JP2020000888A - Game machine - Google Patents

Abstract

To provide a game machine capable of enhancing a player's interest in a game relating to a performance based on button operations.SOLUTION: The game machine includes operation means that a player can operate. When identification information is displayed in a ready-to-win display mode as a combination representing that a symbol row other than one symbol row turns out a specific lottery result, and a symbol to become a combination other than the specific symbol combination is displayed on the one symbol row, the game machine executes a super ready-to-win B performance that can change a symbol displayed on the one symbol row to another symbol on the basis of an operation of the operation means. The game machine includes: discrimination means that, during execution of the super ready-to-win B performance, discriminates a residual period of a period when the identification information is dynamically displayed; and specific performance setup means that, when the residual period discriminated by the discrimination means is a specific period or less, can set up a specific performance that displays the specific symbol to become a specific symbol combination in the residual period.SELECTED DRAWING: Figure 77

Description

  The present invention relates to a gaming machine such as a pachinko machine.

  In a gaming machine such as a pachinko machine, there is a gaming machine that prevents the effect display during a jackpot from being monotonized by diversifying the effect patterns in a round winning of a jackpot (Patent Document 1).

JP 2007-117660 A

  However, the above-described conventional gaming machine has a problem that there is room for improvement in a method of preventing the effect display during the big hit from becoming monotonous.

  SUMMARY An advantage of some aspects of the invention is to provide a gaming machine that can improve a method of preventing the effect display from becoming monotonous during a jackpot.

  In order to achieve this object, the gaming machine according to claim 1 has an effect executing means for executing an effect of a game, a display means for displaying an effect mode executed by the effect executing means, and the effect executing means. A staging mode selecting means for selecting a staging mode to be executed from a plurality of staging modes, wherein the staging mode selected by the staging mode selecting means has an operating means operable by a player. Each time a predetermined condition is satisfied, a route effect mode in which the effect mode is changed by the player selecting one route from a plurality of routes by operating the operating means is set, and the route effect mode is set. Is executed, there is an auxiliary means for assisting in selecting a route other than the route selected in the previously performed route effect mode.

  According to the gaming machine of the first aspect, it is possible to improve the method of preventing the effect display during the big hit from becoming monotonous.

It is a front view of the pachinko machine in 1st Embodiment. It is a front view of the game board of a pachinko machine. It is a rear view of a pachinko machine. FIG. 2 is a block diagram illustrating an electrical configuration of the pachinko machine. It is a front perspective view of an operation unit. It is the exploded front perspective view of the operation unit which looked at the operation unit which disassembled from the front. It is a front view of an operation unit. It is a front view of an operation unit. It is a front view of an operation unit. It is a front exploded perspective view of a game board and a board lower unit. It is a front exploded perspective view of a game board and a board lower unit. It is a rear exploded perspective view of a game board and a board lower unit. It is a front exploded perspective view of a variable winning device. It is a rear exploded perspective view of the variable winning device. (A) is a top view of the variable winning device, (b) is a front view of the variable winning device, and (c) is a side view of the variable winning device as viewed in the direction of the arrow XVc in FIG. 15 (b). is there. 15A is a cross-sectional view of the variable prize winning device taken along the line XVIa-XVIa in FIG. 15B, and FIG. It is sectional drawing. (A) and (b) are partial front views of the game board. 17A is a cross-sectional view of the lower panel unit taken along line XVIIIa-XVIIIa in FIG. 17B, and FIG. 17B is a cross-sectional view of the lower panel unit taken along line XVIIIb-XVIIIb in FIG. FIG. 18C is a cross-sectional view of the lower panel unit in which the arrangement of the light irradiation unit is virtually changed from FIG. It is a front perspective view of a compound operation unit. It is a rear perspective view of a compound operation unit. It is a front exploded perspective view of a compound operation unit. It is a rear exploded perspective view of a compound operation unit. It is a front exploded perspective view of a main body member, a shielding member, and a swing member. FIG. 4 is an exploded rear perspective view of a main body member, a shielding member, and a swing member. (A) is a front view of the first guide arm, (b) is a bottom view of the first guide arm, and (c) is a first guide arm along line XXVc-XXVc in FIG. 25 (a). FIG. 25D is a cross-sectional view of the first guide arm taken along line XXVd-XXVd in FIG. 25A. 26A is a front view of the second guide arm, FIG. 26B is a bottom view of the second guide arm, and FIG. 26C is a second guide arm along line XXVIc-XXVIc in FIG. FIG. 26D is a cross-sectional view of the second guide arm taken along line XXVId-XXVId in FIG. 26A. (A) And (b) is a front view of a 1st guide arm, a 2nd guide arm, and wiring. It is a front view of a compound operation unit. It is a rear view of a compound operation unit. It is a front view of a compound operation unit. It is a rear view of a compound operation unit. It is a front view of a compound operation unit. It is a rear view of a compound operation unit. FIG. 30 is a partial cross-sectional view of the composite operation unit taken along the line XXXIV-XXXIV in FIG. 28. FIG. 33 is a partial cross-sectional view of the composite operation unit taken along the line XXXV-XXXV in FIG. 32. It is a front view of a compound operation unit. FIG. 37 is a partial cross-sectional view of the composite operation unit taken along the line XXXVII-XXXVII in FIG. 36. It is a front perspective view of a swing operation unit. It is a rear perspective view of a swing operation unit. It is a front exploded perspective view of a rocking operation unit. It is a back exploded perspective view of a rocking operation unit. (A) is a front view of the oscillating operation unit, and (b) is a side view of the oscillating operation unit as viewed in the direction of the arrow XXXXIIb in FIG. 42 (a). It is a front view of a swing operation unit. 43A is a cross-sectional view of the drive side arm member, the driven side arm member, and the first bridging member taken along the line XXXXIVa-XXXIVa in FIG. 43, and FIG. It is sectional drawing of a member, a driven side arm member, and a 2nd bridge member. (A) is a partial side view of the swinging operation unit as viewed in the direction of the arrow XXXXVa in FIG. 43, and (b) and (c) show that the driven arm member is bent forward from the state of FIG. FIG. 6 is a partial side view of the swinging operation unit illustrating the state in a time series. FIG. 44 is a cross-sectional view of the drive-side arm member and the driven-side arm member taken along the line XXXXIV-XXXXXIV in FIG. 43. FIG. 44 is a partial cross-sectional view of the swinging operation unit along the line XXXXV-XXXXV in FIG. 43. It is a front view of a drive side arm member and a driven side arm member. It is a front view of a drive side arm member and a driven side arm member. It is a front view of a drive side arm member and a driven side arm member. (A) And (b) is a partial front view of the swing operation unit in 2nd Embodiment. (A) to (c) are front views of the swing operation unit in the third embodiment, and (d) is a cross-sectional view of the swing operation unit along the line Ld-Ld in FIG. 52 (b). It is a front view of a compound operation unit in a 4th embodiment. (A) And (b) is a partial front view of a composite operation unit. It is a rear view of the compound operation unit in a 5th embodiment. (A) to (c) are partial rear views of the composite operation unit. It is a partial front view of a compound operation unit in a 6th embodiment. (A) And (b) is a partial front view of a composite operation unit. (A) And (b) is a partial front view of the swing operation unit in 7th Embodiment. It is a front view of the game board in an 8th embodiment. FIG. 61 is a partial cross-sectional view of the gaming board taken along line LXI-LXI in FIG. 60. (A) is a front view of the first guide arm in the ninth embodiment, (b) is a bottom view of the first guide arm, and (c) is a perspective view of a detachable front locking member. . (A) is a front view of a 2nd guide arm, (b) is a bottom view of a 2nd guide arm, (c) is a 2nd guide arm in the LXIIIc-LXIIIc line of FIG. FIG. (A) and (b) are front views of a first guide arm and a second guide arm of the wiring guide arm, and (c) is a first view of the wiring guide arm along the line LXIVc-LXIVc in FIG. It is sectional drawing of a guide arm and a 2nd guide arm. (A) is a figure which showed typically the area division setting of a display screen, and an effective line setting, and (b) is a figure which illustrated the actual display screen. (A) is a schematic diagram illustrating a screen of the super background notice, and (b) is a schematic diagram illustrating a screen when the screen of (a) is horizontally scroll-displayed in the super background notice. . (A) is a schematic view illustrating a screen on which a special image is displayed in the super background notice, and (b) is a schematic view illustrating a screen suggesting a transition to the door inside background in the super background notice. It is. (A) is a schematic diagram illustrating a screen in which the mode of the stray eyes is displayed in the super reach A, and (b) is a schematic diagram illustrating a mode screen of the double reach in the super reach A. . (A) is a schematic diagram illustrating a screen displayed in Super Reach A, and (b) is a schematic diagram illustrating a screen displayed in Super Reach A. (A) is a schematic diagram illustrating a screen displayed in Super Reach A, and (b) is a schematic diagram illustrating a screen displayed in Super Reach A. It is the schematic diagram which illustrated the screen at the time of a big hit in super reach A. (A) is a schematic diagram illustrating a screen displayed in the big hit effect, and (b) is a schematic diagram illustrating a screen displayed in the big hit effect. (A) is a schematic diagram illustrating a screen displayed in the big hit effect, and (b) is a schematic diagram illustrating a screen displayed in the big hit effect. (A) is a schematic diagram illustrating a screen displayed in the big hit effect, and (b) is a schematic diagram illustrating a screen displayed in the big hit effect. (A) is a schematic diagram illustrating the timing of the effect performed in Super Reach B, and (b) is a schematic diagram illustrating the timing of the effect performed in Super Reach B. (A) is a schematic diagram illustrating the timing of the effect performed in Super Reach B, and (b) is a schematic diagram illustrating the timing of the effect performed in Super Reach B. (A) is a schematic diagram illustrating a screen displayed in super reach B, and (b) is a schematic diagram illustrating a screen displayed in super reach B. (A) is a schematic diagram illustrating a screen displayed in super reach B, and (b) is a schematic diagram illustrating a screen displayed in super reach B. It is a figure showing the outline of various counters. FIG. 3 is a block diagram illustrating an electrical configuration of a RAM in the main control device. (A) is a block diagram showing an electrical configuration of a ROM in the main control device, and (b) schematically shows a correspondence relationship between a first random number counter C1 and a special symbol big hit determination value. (C) is a schematic diagram schematically showing the contents of the first hit type selection table, and (d) is a second random number counter C4 and a normal symbol hit determination value. FIG. 3 is a schematic diagram schematically showing the correspondence relationship of FIG. (A) is a block diagram showing an electrical configuration of a variation pattern selection table provided in a ROM in the main control device, and (b) shows a correspondence between a variation type counter CS1 and a variation type at the time of a big hit. It is a schematic diagram which showed typically, (c) is the schematic diagram which showed typically the correspondence relationship between the fluctuation | variation type counter CS1 and fluctuation | variation type at the time of a deviation (normal), (d) FIG. 9 is a schematic diagram schematically showing a correspondence relationship between a variation type counter CS1 and a variation type in (probable variation). FIG. 2A is a block diagram illustrating an electrical configuration of a ROM in the audio ramp control device, and FIG. 2B is a block diagram illustrating an electrical configuration of a RAM in the audio ramp control device. FIG. 3 is a block diagram illustrating an electrical configuration of the display control device. FIG. 3 is a block diagram illustrating an electrical configuration of a RAM in the display control device. FIG. 4 is a schematic diagram schematically showing the contents of a data table storage area provided in a RAM in the display control device. (A) is a schematic diagram schematically showing the contents of a mass setting table storage area provided in a RAM in a display control device, and (b) is a schematic diagram showing a normal mass setting provided in the mass setting table storage area. It is the schematic diagram which showed typically the content of the table, (c) is the schematic diagram which showed typically the content of the continuous mass setting table provided in the mass setting table storage area. (A) is an explanatory view explaining the back surface A, and (b) is an explanatory diagram explaining the back surface B. It is the schematic diagram which showed an example of the display data table typically. FIG. 4 is a schematic diagram schematically illustrating an example of a transfer data table. It is the schematic diagram which showed an example of the drawing list typically. 5 is a flowchart illustrating a timer interrupt process executed by an MPU in the main control device. It is a flow chart which shows special design change processing performed by MPU in a main control unit. It is a flowchart showing a special symbol change start process executed by the MPU in the main control device. It is a flowchart which shows the start winning process performed by MPU in a main control apparatus. It is a flowchart which shows the normal symbol fluctuation | variation process performed by MPU in a main control apparatus. It is a flowchart which shows the through gate passage process performed by MPU in a main control apparatus. 9 is a flowchart illustrating an NMI interrupt process executed by the MPU in the main control device. 5 is a flowchart illustrating a start-up process performed by an MPU in a main control device. 5 is a flowchart illustrating main processing executed by an MPU in the main control device. It is a flowchart which shows the jackpot control processing performed by MPU in a main control apparatus. 5 is a flowchart illustrating a start-up process performed by an MPU in the audio lamp control device. 5 is a flowchart illustrating a main process executed by an MPU in the audio lamp control device. It is the flowchart which showed the command determination process performed by MPU in a voice lamp control apparatus. 5 is a flowchart illustrating a variable display setting process executed by the MPU in the audio lamp control device. It is the flowchart which showed SW input monitoring and production processing performed by the MPU in the audio lamp control device. It is the flowchart which showed the super background operation process performed by MPU in an audio lamp control device. It is the flowchart which showed the big hit operation process performed by the MPU in the voice lamp control device. It is the flowchart which showed the super reach B time operation process performed by the MPU in the audio lamp control device. 5 is a flowchart illustrating a main process executed by an MPU in the display control device. 9 is a flowchart illustrating a boot process executed by the MPU in the display control device. (A) is a flowchart showing a command interruption process executed by the MPU in the display control device, and (b) is a flowchart showing a V interruption process executed by the MPU in the display control device. is there. 9 is a flowchart illustrating a command determination process executed by the MPU in the display control device. (A) is a flowchart showing a variation pattern command process executed by the MPU in the display control device, and (b) is a flowchart showing a stop type command process executed by the MPU in the display control device. is there. It is the flowchart which showed the super-background effect process performed by MPU in a display control apparatus. 6 is a flowchart illustrating reach-related command processing executed by an MPU in the display control device. It is the flowchart which showed the super reach B process for a display performed by MPU in a display control apparatus. It is the flowchart which showed the big hit related command processing which is executed by the MPU inside the display control device. (A) is a flowchart showing an opening command process executed by the MPU in the display control device, and (b) is a flowchart showing a round number command process executed by the MPU in the display control device. . 9 is a flowchart illustrating a map setting process executed by the MPU in the display control device. 9 is a flowchart showing an ending command process executed by an MPU in the display control device. 9 is a flowchart illustrating a background image change command process executed by the MPU in the display control device. 6 is a flowchart illustrating SW-related command processing executed by the MPU in the display control device. 9 is a flowchart illustrating a super-background SW process executed by the MPU in the display control device. It is a flowchart which showed the big hit SW process performed by MPU in a display control apparatus. 9 is a flowchart illustrating an error command process executed by the MPU in the display control device. 5 is a flowchart illustrating a display setting process executed by the MPU in the display control device. 9 is a flowchart illustrating a warning image setting process executed by the MPU in the display control device. 9 is a flowchart illustrating a pointer update process executed by the MPU in the display control device. (A) is a flowchart showing a transfer setting process executed by the MPU in the display control device, and (b) is a flowchart showing a resident image transfer setting process executed by the MPU in the display control device. is there. 9 is a flowchart illustrating a normal image transfer setting process executed by the MPU in the display control device. (A) is a flowchart showing a drawing process executed by the MPU in the display control device executed by the MPU in the display control device, and (b) is a counter executed by the MPU in the display control device. This is an update process. (A) is a schematic diagram illustrating the timing of the effect performed in the super reach B in the modified example of the first control example, and (b) is performed in the super reach B in the modified example of the first control example. It is the schematic diagram which illustrated the timing of the effect | action. (A) is a schematic diagram illustrating a screen displayed in super reach B in a modified example of the first control example, and (b) is a screen displayed in super reach B in a modified example of the first control example. It is the schematic diagram which illustrated. FIG. 10 is a schematic diagram schematically showing the contents of a data table storage area provided in a RAM in a display control device according to a modification of the first control example. It is a super reach B operation process executed by the MPU in the voice lamp control device in a modified example of the first control example. It is a flowchart which shows the display super reach B process performed by the MPU in the display control apparatus in the modification of a 1st control example. It is the schematic diagram which showed the frame button and the selection switch typically.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, an embodiment in which the present invention is applied to a pachinko gaming machine (hereinafter, simply referred to as “pachinko machine”) 10 will be described as a first embodiment with reference to FIGS. 1 to 50. FIG. 1 is a front view of the pachinko machine 10 according to the first embodiment, FIG. 2 is a front view of the game board 13 of the pachinko machine 10, and FIG. 3 is a rear view of the pachinko machine 10.

  As shown in FIG. 1, the pachinko machine 10 has an outer frame 11 having an outer shell formed by a wooden frame combined in a substantially rectangular shape, and an outer frame 11 formed to have substantially the same outer shape as the outer frame 11. And an inner frame 12 supported to be openable and closable. Metal hinges 18 are attached to the outer frame 11 at two upper and lower positions on the left side in front view (see FIG. 1) to support the inner frame 12, and the side on which the hinges 18 are provided is used as an opening / closing axis. The frame 12 is supported to be openable and closable toward the front side.

  A game board 13 (see FIG. 2) having a large number of nails, winning holes 63, 64, and the like is detachably mounted on the inner frame 12 from the back side. When a ball (game ball) flows down in front of the game board 13, a ball game is performed. The inner frame 12 has a ball launching unit 112a (see FIG. 4) that launches a ball into the front area of the game board 13 and a launch that guides the ball fired from the ball launch unit 112a to the front area of the game board 13. A rail (not shown) and the like are attached.

  On the front side of the inner frame 12, a front frame 14 covering the front upper side and a lower plate unit 15 covering the lower side are provided. In order to support the front frame 14 and the lower plate unit 15, metal hinges 19 are attached to two upper and lower positions on the left side when viewed from the front (see FIG. 1), and the side on which the hinge 19 is provided is used as an opening / closing axis. The lower plate unit 14 and the lower plate unit 15 are supported to be openable and closable toward the front side. The locking of the inner frame 12 and the locking of the front frame 14 are respectively released by inserting a dedicated key into the keyhole 21 of the cylinder lock 20 and performing a predetermined operation.

  The front frame 14 is assembled with decorative resin parts, electric parts, and the like, and is provided with a window portion 14c having an approximately elliptical opening at a substantially central portion thereof. A glass unit 16 having two glass sheets is disposed on the back side of the front frame 14, and the front of the game board 13 is visible on the front side of the pachinko machine 10 via the glass unit 16.

  On the front frame 14, an upper plate 17 for storing a ball is formed in a substantially box shape that protrudes toward the front side and has an open upper surface, and prize balls, loaned balls, and the like are discharged to the upper plate 17. The bottom surface of the upper plate 17 is formed to be inclined downward to the right as viewed from the front (see FIG. 1), and the ball introduced into the upper plate 17 is guided to the ball firing unit 112a (see FIG. 4) by the inclination. A frame button 22 is provided on the upper surface of the upper plate 17. The frame button 22 is operated by the player when, for example, changing the stage of the effect displayed on the third symbol display device 81 (see FIG. 2) or changing the effect of the super reach. You.

  Light emitting means such as various lamps is provided around the front frame 14 (for example, at a corner). These light-emitting means are controlled to change the light-emitting mode by lighting or blinking according to a change in the game state at the time of a big hit or at a predetermined reach, and play a role of enhancing the effect of the effect during the game. At the periphery of the window 14c, there are provided illuminations 29 to 33 in which light-emitting means such as LEDs are incorporated. In the pachinko machine 10, these illumination parts 29 to 33 function as effect lamps such as a jackpot lamp, and at the time of a jackpot or a reach effect, the illumination parts 29 to 33 are turned on by lighting or blinking of a built-in LED. Or, it flashes to notify that a jackpot is in progress or that the player is reaching one step before the jackpot. In addition, at the upper left of the front frame 14 when viewed from the front (see FIG. 1), there is provided a display lamp 34 which has a built-in light emitting means such as an LED and is capable of displaying when a prize ball is being paid out and when an error has occurred.

  Further, a small window 35 is formed below the right illumination unit 32 by attaching a transparent resin from the back side so that the back side of the front frame 14 can be visually recognized, and a sticking space K1 (FIG. 2) can be viewed from the front of the pachinko machine 10. Further, in the pachinko machine 10, a plating member 36 made of chrome-plated ABS resin is attached to a region around the illuminated portions 29 to 33 in order to bring out more gorgeousness.

  A ball lending operation unit 40 is provided below the window 14c. The ball lending operation unit 40 includes a frequency display unit 41, a ball lending button 42, and a return button 43. When the ball lending operation unit 40 is operated in a state in which bills, cards, and the like are inserted into a card unit (ball lending unit) (not shown) arranged on the side of the pachinko machine 10, the ball is slid according to the operation. Lending is done. More specifically, the frequency display unit 41 is an area in which balance information of a card or the like is displayed, and a built-in LED is turned on, and the balance is displayed as a number as balance information. The ball lending button 42 is operated to obtain a lending ball based on information recorded on a card or the like (recording medium), and the lending ball is supplied to the upper plate 17 as long as there is a remaining amount on the card or the like. Is done. The return button 43 is operated when requesting the return of a card or the like inserted in the card unit. In a pachinko machine in which balls are lent directly to the upper plate 17 from a ball lending device or the like without a card unit, a so-called cash machine, the ball-lending operation unit 40 is unnecessary. A decorative seal or the like may be added to the installation portion to make the component configuration common. A pachinko machine using a card unit and a cash machine can be shared.

  In the lower plate unit 15 located below the upper plate 17, a lower plate 50 for storing spheres that could not be completely stored in the upper plate 17 is formed in a substantially box shape with an open upper surface in a central portion thereof. I have. On the right side of the lower plate 50, an operation handle 51 operated by a player to drive a ball into the front of the game board 13 is provided.

  Inside the operation handle 51, a touch sensor 51a for permitting driving of the ball firing unit 112a, a firing stop switch 51b for stopping firing of the ball during a pressing operation, and a rotation of the operation handle 51. A variable resistor (not shown) that detects a dynamic operation amount (rotational position) based on a change in electric resistance is incorporated. When the operation handle 51 is rotated clockwise by the player, the touch sensor 51a is turned on and the resistance value of the variable resistor changes in accordance with the amount of rotation operation, and the resistance value of the variable resistor is changed. The ball is fired at an intensity (firing intensity) corresponding to, and the ball is hit into the front of the game board 13 with a flying amount corresponding to the operation of the player. When the operation handle 51 is not operated by the player, the touch sensor 51a and the firing stop switch 51b are off.

  At the lower front part of the lower plate 50, a ball release lever 52 for operating when discharging the balls stored in the lower plate 50 downward is provided. The ball-pulling lever 52 is constantly urged rightward, and is slid leftward against the urging, so that a bottom opening formed on the bottom surface of the lower plate 50 is opened. The ball naturally drops from the bottom opening and is discharged. The operation of the ball removing lever 52 is usually performed in a state where a box (generally referred to as a “thousand boxes”) for receiving the balls discharged from the lower plate 50 is placed below the lower plate 50. As described above, the operation handle 51 is disposed on the right side of the lower plate 50, and the ashtray 53 is mounted on the left side of the lower plate 50.

  As shown in FIG. 2, the game board 13 includes a base plate 60 cut into a substantially square shape in a front view, a number of nails (not shown) for ball guidance, a windmill (not shown), and a rail 61. , 62, a general winning opening 63, a first winning opening 64, a second winning opening 640, a variable winning device 330, a through gate 67, a variable display device unit 80, and the like. 1)). The base plate 60 is made of a light-transmissive resin material, and is formed so that a player can visually recognize various structures disposed on the back side of the base plate 60 from the front side. The general winning opening 63 and the variable display device unit 80 are provided in through holes formed in the base plate 60 by router processing, and are fixed from the front side of the game board 13 with tapping screws or the like. The first prize port 64, the second prize port 640, and the variable prize apparatus 330 are formed in the lower panel unit 300 which is fitted into a receiving opening 60a of the base plate 60 described later.

  The front central portion of the game board 13 can be visually recognized from the front side of the inner frame 12 through the window 14c (see FIG. 1) of the front frame 14. The configuration of the game board 13 will be described below mainly with reference to FIG.

  An outer rail 62 formed by bending a band-shaped metal plate into a substantially arc shape is planted on the front of the game board 13, and a band-shaped metal plate similar to the outer rail 62 is provided inside the outer rail 62. The arc-shaped inner rail 61 formed by the above is planted. The inner rail 61 and the outer rail 62 surround the outer periphery of the front of the game board 13, and the front and rear of the game board 13 and the glass unit 16 (see FIG. 1) surround the front and back of the game board 13. A game area in which a game is played is formed by the behavior of. The game area is an area defined by two rails 61 and 62 and a resin outer edge member 73 connecting between the rails, which is the front of the game board 13 (a winning opening or the like is provided and fired). The area where the falling ball flows down).

  The two rails 61 and 62 are provided to guide the ball fired from the ball firing unit 112a (see FIG. 4) to the upper part of the game board 13. A return ball preventing member 68 is attached to a tip portion (upper left portion of FIG. 2) of the inner rail 61 to prevent a ball once guided to the upper portion of the game board 13 from returning to the ball guide passage again. Is done. A return rubber 69 is attached to the tip of the outer rail 62 (upper right portion in FIG. 2) at a position corresponding to the maximum flight portion of the ball, and the ball fired at a predetermined momentum hits the return rubber 69 and momentum. Is rebounded toward the center while being attenuated.

  First symbol display devices 37A and 37B each including a plurality of LEDs as light emitting means and a 7-segment display are provided at a lower left portion (a lower left portion in FIG. 2) of the game area when viewed from the front. The first symbol display devices 37A and 37B are for performing display according to each control performed by the main control device 110 (see FIG. 4), and mainly display the game state of the pachinko machine 10. In the present embodiment, the first symbol display devices 37A and 37B are configured to be properly used depending on whether the ball has won the first winning opening 64 or the second winning opening 640. Specifically, when the ball wins the first winning opening 64, the first symbol display device 37A operates, while when the ball wins the second winning opening 640, the first symbol display device 37A operates. The symbol display device 37B is configured to operate.

  In addition, the first symbol display devices 37A and 37B use LEDs to indicate whether the pachinko machine 10 is in the process of probable change, during working hours, or during normal operation, or to indicate whether or not the pachinko machine 10 is fluctuating. Whether the stop symbol is a symbol corresponding to a probable jackpot or a symbol corresponding to an ordinary jackpot is indicated by an illuminated state, the number of retained balls is indicated by an illuminated state, and the round during the jackpot is displayed by a 7-segment display device. Display numbers and errors. In addition, the plurality of LEDs are configured such that the emission colors (for example, red, green, and blue) of each LED are different, and the combination of the emission colors may indicate various game states of the pachinko machine 10 with a small number of LEDs. it can.

  In the pachinko machine 10, the lottery is performed when the first winning port 64 and the second winning port 640 have a winning. In the lottery, the pachinko machine 10 determines whether or not it is a big hit (big hit lottery), and when it is determined to be a big hit, also determines the big hit type. As the jackpot type determined here, a 15R certain-variable jackpot, a 4R certain-variable jackpot, and a 15R regular large jackpot are prepared. The first symbol display devices 37A and 37B not only indicate whether or not the result of the lottery is a jackpot as a stop symbol after the end of the change, but if the jackpot is a jackpot, a symbol corresponding to the jackpot type is displayed. .

  Here, “15R probability variable jackpot” is a probability variable jackpot in which the maximum number of rounds shifts to a high probability state after 15 rounds of jackpot, and “4R probability variable jackpot” means a maximum round number of four rounds. Is a probable jackpot that transitions to a high probability state after. The “15R normal jackpot” is a jackpot in which the maximum number of rounds shifts to the low probability state after the jackpot of 15 rounds and the time saving state is reached during a predetermined number of changes (for example, 100 changes). is there.

  The “high-probability state” refers to a state in which the subsequent jackpot probability is increased as an added value after the end of the jackpot, that is, when the probability is changing (probable change), in other words, a game that is easily shifted to the special game state. State. The high probability state (probable change) in the present embodiment includes a state of a game in which the winning probability of a second symbol described later increases and a ball can easily enter the second winning opening 640. The “low-probability state” refers to a state where the probability of change is not being changed, and a state in which the jackpot probability is normal, that is, a state in which the probability of jackpot is lower than that in the case of probability change. The time saving state (medium time saving) of the “low probability state” is a state in which the jackpot probability is a normal state, and the jackpot probability of the second symbol is increased while the jackpot probability remains unchanged. This refers to a game state in which a ball is likely to win. On the other hand, the state where the pachinko machine 10 is in the normal state is a state of the game in which the probability is not changed or the time is not reduced (a state in which neither the big hit probability nor the second symbol hit probability is increased).

  During probable change or during working hours, not only the probability of hitting the second symbol increases, but also the time during which the electric accessory 640a attached to the second winning opening 640 is opened is changed. Is set. When the electric accessory 640a is in an open state (open state), a ball is awarded to the second winning opening 640 as compared to when the electric accessory 640a is in a closed state (closed state). It will be in an easy state. Therefore, during a probability change or during a shortened working hours, a ball can easily enter the second winning opening 640, and the number of jackpot lotteries can be increased.

  In addition, during the probability change or during the working hours, instead of changing the opening time of the motorized accessory 640a attached to the second winning opening 640, or in addition to changing the opening time, the power A change may be made to increase the number of times that the accessory 640a is released from the normal number. In addition, during the probability change or during working hours, the winning probability of the second symbol is not changed, and the electric accessory 640a associated with the second winning opening 640 is opened and the electric accessory 640a is opened once. At least one of the number of times may be changed. In addition, during probable change or during working hours, the time during which the electric accessory 640a associated with the second winning opening 640 is opened or the number of times the electric accessory 640a is opened per hit is not determined. Only the probability may be changed so as to increase as compared with the normal state.

  In the game area, a plurality of general winning openings 63 are provided in which five to fifteen balls are paid out as winning balls when the balls win. Further, a variable display device unit 80 is provided in a central portion of the game area. The variable display device unit 80 uses the winning (starting winning) in the first winning opening 64 and the second winning opening 640 as a trigger, and synchronizes with the variable display on the first symbol display devices 37A and 37B, and outputs the third symbol. A third symbol display device 81 composed of a liquid crystal display (hereinafter simply abbreviated as "display device") for performing a variable display, and an LED for varying display of a second symbol when the ball of the through gate 67 passes is used as a trigger. A second symbol display device (not shown) is provided. Further, a center frame 86 is provided in the variable display device unit 80 so as to surround the outer periphery of the third symbol display device 81.

  The third symbol display device 81 is composed of a large-sized 9-inch liquid crystal display. The display content is controlled by the display control device 114 (see FIG. 4), so that, for example, the upper, middle and lower 3 Two symbol columns are displayed. Each symbol row is composed of a plurality of symbols (third symbols), and these third symbols are horizontally scrolled for each symbol row, and the third symbol is variably displayed on the display screen of the third symbol display device 81. It has become. In the third symbol display device 81 of the present embodiment, the display of the gaming state accompanying the control of the main control device 110 (see FIG. 4) is performed by the first symbol display devices 37A and 37B, whereas the first symbol display device 37A displays the game state. The decorative display corresponding to the display of the symbol display devices 37A and 37B is performed. Note that the third symbol display device 81 may be configured using, for example, a reel or the like instead of the display device.

  The second symbol display device alternately lights a symbol “O” and a symbol “X” as display symbols (second symbols (not shown)) for a predetermined time each time a ball passes through the through gate 67. The variable display is performed. In the pachinko machine 10, when it is detected that the ball has passed through the through gate 67, a winning lottery is performed. If the winning lottery results in a winning, the symbol "O" is stopped and displayed on the second symbol display device after the variation of the second symbol is displayed. If the result of the winning lottery is off, the symbol “x” is stopped and displayed on the second symbol display device after the variation display of the third symbol.

  In the case of the pachinko machine 10, when the variable display on the second symbol display device is stopped at a predetermined symbol (in this embodiment, a symbol of “○”), the electric accessory 640a attached to the second winning opening 640 is moved for a predetermined time. Only in the operating state (open).

  The time required for the fluctuation display of the second symbol is set to be shorter during the probable change or during the time reduction than in the normal game state. Thus, during the probable change and during the time reduction, the fluctuation display of the second symbol is performed in a short time, so that the winning lottery can be performed more than during the normal. Therefore, the chance of winning in the winning lottery increases, so that the player can be given many opportunities to open the electric accessory 640a of the second winning opening 640. Therefore, the ball can easily enter the second winning opening 640 during the probability change and during the working hours.

  In addition, during the probability change or during the working hours, the probability of winning is increased, and the opening time and the number of times of opening the electric accessory 640a per hit are increased. When the ball is in a state where it is easy to win, the time required for the variable display of the second symbol may be constant regardless of the gaming state. On the other hand, when the time required for the fluctuation display of the second symbol is set to be shorter than the normal time during the probability change or during the time saving, the hit probability may be constant regardless of the game state, or one hit may be performed. The opening time and the number of times of opening of the electric accessory 640a with respect to may be constant regardless of the gaming state.

  The through gate 67 is assembled to the game board 13 in the left and right regions of the variable display device unit 80, and is configured to allow a part of the ball fired on the game board 13 to pass through. When the ball passes through the through gate 67, a winning lottery of the second symbol is performed. After the winning lottery, the variable display is performed on the second symbol display device. If the result of the winning lottery is a hit, a symbol of "○" is displayed as a stop symbol of the variable display, and the result of the winning lottery is out of order. For example, a symbol "x" is displayed as a stop symbol of the variable display.

  The number of times the ball has passed through the through gate 67 is held up to a total of four times, and the number of held balls is displayed by the above-mentioned first symbol display devices 37A and 37B, and at the second symbol holding lamp (not shown). Is also lit. Four second symbol holding lamps are provided for the maximum number of holdings, and are disposed symmetrically below the third symbol display device 81.

  The variable display of the second symbol is performed by switching on and off of a plurality of lamps in the second symbol display device as in the present embodiment, as well as the first symbol display devices 37A and 37B and the third symbol display. This may be performed using a part of the symbol display device 81. Similarly, the lighting of the second symbol holding lamp may be performed by a part of the third symbol display device 81. Further, the maximum number of reserved balls for passing the ball through the through gate 67 is not limited to four, and may be set to three or less, or five or more (for example, eight). The number of through gates 67 is not limited to two, and may be one, for example. Further, the mounting position of the through gate 67 is not limited to the left and right of the variable display device unit 80, but may be, for example, below the variable display device unit 80. Further, since the number of reserved balls is indicated by the first symbol display devices 37A and 37B, the second symbol retaining lamp may not be turned on.

  Below the variable display unit 80, a first winning port 64 in which a ball can win is provided. When a ball wins in the first winning opening 64, a first winning opening switch (not shown) provided on the back side of the game board 13 is turned on, and the main control unit 110 is turned on by turning on the first winning opening switch. A jackpot lottery is performed in (see FIG. 4), and a display corresponding to the lottery result is shown on the first symbol display device 37A.

  On the other hand, below the first winning opening 64 in front view, a second winning opening 640 where a ball can win is arranged. When a ball wins in the second winning opening 640, a second winning opening switch (not shown) provided on the back side of the game board 13 is turned on, and the main control device 110 is turned on by turning on the second winning opening switch. A jackpot lottery is performed at (see FIG. 4), and a display corresponding to the lottery result is shown on the first symbol display device 37B.

  Each of the first winning port 64 and the second winning port 640 is also one of winning ports in which five balls are paid out as winning balls when the ball wins. In the present embodiment, the number of award balls to be paid out when a ball wins in the first winning opening 64 and the number of award balls to be paid out when a ball wins to the second winning opening 640 are the same. The number of award balls to be paid out when a ball wins in the first winning opening 64 is different from the number of award balls to be paid out when a ball wins to the second winning opening 640, for example, the number of balls to the first winning opening 64. May be configured such that the number of award balls paid out when the player wins is three, and the number of award balls paid out when a ball wins in the second winning opening 640.

  The second winning opening 640 is provided with an electric accessory 640a. The electric accessory 640a is configured to be openable and closable. Normally, the electric accessory 640a is in a closed state (reduced state), so that the ball does not easily enter the second winning opening 640. On the other hand, when the symbol “O” is displayed on the second symbol display device as a result of the second symbol change display performed when the ball passes through the through gate 67, the electric accessory 640 a is in the open state (enlarged). State), and the ball is in a state where it is easy to win the second winning opening 640.

  As described above, the probability of hitting the second symbol is higher during the probable change and during the working hours, and the time required to display the variation of the second symbol is shorter than that during the normal period. Are easily displayed, and the number of times the electric accessory 640a is opened (increased) increases. Further, during probable change and during working hours, the time during which the electric accessory 640a is opened is longer than during normal times. Therefore, a state in which a ball can easily win the second winning opening 640 can be created during the probability change and during the working hours, as compared with the normal time.

  Here, the probability of a big hit in the case where the ball has won in the first winning opening 64 and the case where the ball has won in the second winning opening 640 is the same in the low probability state and the high probability state. However, the probability of a 15R probability variable jackpot being selected as a jackpot type selected in the event of a jackpot is higher when a ball wins the second winning opening 640 than when a ball wins the first winning opening 64. Is set. On the other hand, the first winning opening 64 does not have the motorized accessory as in the second winning opening 640, and the ball is always in a state where it can win.

  Therefore, during normal times, the electric winning accessory attached to the second winning opening 640 is often in a closed state, and it is difficult to win the second winning opening 640. Then, the ball is fired so that the ball passes to the left of the variable display device unit 80 (so-called “left-handed”), and by winning the first winning opening 64, a lot of chances of a jackpot lottery are obtained, and the jackpot is won. It is more advantageous for the player to aim for that.

  On the other hand, when the ball is passed through the through gate 67 during the probable change or during working hours, the electric accessory 640a attached to the second winning opening 640 is likely to be opened and the second winning opening 640 is easily won. Therefore, the ball is fired toward the second winning opening 640 so that the ball passes to the right of the variable display device 80 (so-called “right-handed”), and passes through the through gate 67 to open the electric accessory. At the same time, it is more advantageous for the player to aim for a 15R probability change jackpot by winning the second winning opening 640.

  In the pachinko machine 10 according to the present embodiment, since the configuration of the game board 13 is symmetrical, the pachinko machine 10 can aim at the first winning opening 64 by “right-handing” or the second winning opening 640 by “left-handing”. You can also aim. For this reason, the pachinko machine 10 of the present embodiment provides the player with a method of shooting a ball in accordance with the playing state of the pachinko machine 10 (whether the game is being changed, is being reduced in time, or is usually being made). Need to be changed to “left-handed” and “right-handed”. Therefore, the trouble of changing the way of hitting the ball can be eliminated.

  A variable winning device 330 (see FIG. 11) is provided below the first winning opening 64, and a specific winning opening 65a is provided at a substantially central portion thereof. In the pachinko machine 10, when the jackpot lottery performed due to the winning in the first winning port 64 or the second winning port 640 becomes a jackpot, after a predetermined time (variable time) elapses, the jackpot stop symbol is displayed. Thus, the first symbol display device 37A or the first symbol display device 37B is turned on, and a stop symbol corresponding to the jackpot is displayed on the third symbol display device 81 to indicate the occurrence of the jackpot. After that, the game state transitions to a special game state (big hit) where the ball is easy to win. In this special game state, the specific winning opening 65a which is normally closed is opened for a predetermined time (for example, until 30 seconds elapse or until 10 balls are won).

  The specific winning opening 65a is closed after a predetermined time has elapsed, and after the closing, the specific winning opening 65a is opened again for a predetermined time. The opening / closing operation of the specific winning opening 65a can be repeated up to, for example, 15 times (15 rounds). The state in which the opening / closing operation is being performed is one form of a special game state that is advantageous to the player, and the player is paid out a larger amount of prize balls than usual in order to give a game value (game value). Is performed. The details of the variable winning device 330 (see FIG. 11) that opens and closes the specific winning opening 65a will be described later. However, in brief, the moving upper cover member 332 of the variable winning device 330 slides, and the specific winning opening 65a is opened. It is opened and closed.

  The special game state is not limited to the above-described embodiment. A large opening that is opened and closed separately from the specific winning opening 65a is provided in the game area, and when the LED corresponding to the big hit is lit on the first symbol display devices 37A and 37B, the specific winning opening 65a is opened for a predetermined time. During the opening of the specific winning opening 65a, a game state in which a large opening provided separately from the specific winning opening 65a is opened for a predetermined time and a predetermined number of times when a ball wins inside the specific winning opening 65a is a special game. It may be formed as a state. The number of the specific winning opening 65a is not limited to one, and one or two or more (for example, three) may be arranged. The present invention is not limited to the lower left side of the winning opening 64, but may be, for example, the left side of the variable display unit 80.

  At the lower right corner of the game board 13, there is provided a sticking space K 1 for sticking a stamp or an identification label, etc. The stamp or the like stuck to the sticking space K 1 is a small window of the front frame 14. 35 (see FIG. 1).

  The game board 13 is provided with an out port 314. A ball that flows down the game area and does not win any of the winning ports 63, 64, 65a, and 640 is guided to a ball discharge path (not shown) through the out port 314. The out opening 314 is provided in a pair on the left and right of the specific winning opening 65a.

  In the game board 13, a large number of nails are planted for appropriately dispersing and adjusting the falling direction of the ball, and various members (accessories) such as a windmill are provided.

  As shown in FIG. 3, on the back side of the pachinko machine 10, control board units 90 and 91 and a back pack unit 94 are mainly provided. The control board unit 90 includes a main board (main control device 110), an audio lamp control board (audio lamp control device 113), and a display control board (display control device 114). The control board unit 91 is provided with a payout control board (payout control device 111), a launch control board (fire launch control device 112), a power supply board (power supply device 115), and a card unit connection board 116.

  In the back pack unit 94, a back pack 92 and a payout unit 93 forming a protective cover unit are unitized. In addition, each control board includes an MPU as a one-chip microcomputer for controlling each control, a port for communicating with various devices, a random number generator used for various lotteries, and a time counting and synchronization. A clock pulse generating circuit and the like are mounted as needed.

  The main control device 110, the sound lamp control device 113 and the display control device 114, the payout control device 111 and the firing control device 112, the power supply device 115, and the card unit connection board 116 are housed in the board boxes 100 to 104, respectively. . Each of the board boxes 100 to 104 includes a box base and a box cover that covers an opening of the box base. The box base and the box cover are connected to each other, and each control device and each board are stored.

  Further, the substrate box 100 (main control device 110) and the substrate box 102 (dispensing control device 111 and firing control device 112) non-openably connect the box base and the box cover by a sealing unit (not shown) (the caulking structure). Consolidation). In addition, a seal (not shown) is attached to the connection between the box base and the box cover over the box base and the box cover. This sealing seal is made of a brittle material. If the sealing seal is to be peeled off to open the substrate boxes 100 and 102, or if the substrate boxes 100 and 102 are forcibly opened, the box base side and the box cover are closed. Cut to the side and. Therefore, by checking the sealing unit or the sealing seal, it is possible to know whether or not the substrate boxes 100 and 102 have been opened.

  The dispensing unit 93 includes a tank 130 located at the top of the back pack unit 94 and opening upward, a tank rail 131 connected below the tank 130 and gently inclined toward the downstream side, and a downstream side of the tank rail 131. A case rail 132 vertically connected to the side, and a payout device 133 provided at the most downstream portion of the case rail 132 and paying out balls by a predetermined electrical configuration of a payout motor 216 (see FIG. 4). ing. The balls supplied from the island facilities of the game hall are sequentially supplied to the tank 130, and the payout device 133 pays out a required number of balls as needed. A vibrator 134 for applying vibration to the tank rail 131 is attached to the tank rail 131.

  The dispensing control device 111 is provided with a state return switch 120, the firing control device 112 is provided with an operation knob 121 for a variable resistor, and the power supply device 115 is provided with a RAM erasure switch 122. The state return switch 120 is operated to clear the clogged ball (return to a normal state) when a payout error occurs, such as a clogged ball in the payout motor 216 (see FIG. 4). The operation knob 121 is operated to adjust the firing force of the firing solenoid. The RAM erase switch 122 is operated when the power is turned on to return the pachinko machine 10 to the initial state.

  Next, an electrical configuration of the pachinko machine 10 will be described with reference to FIG. FIG. 4 is a block diagram showing an electrical configuration of the pachinko machine 10. As shown in FIG.

  The main control device 110 is equipped with an MPU 201 as a one-chip microcomputer which is an arithmetic device. The MPU 201 includes a ROM 202 storing various control programs and fixed value data executed by the MPU 201, and a memory for temporarily storing various data and the like when executing the control programs stored in the ROM 202. A certain RAM 203 and other various circuits such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit are built in. In the main control device 110, the main processing of the pachinko machine 10 such as the jackpot lottery, the setting of the display on the first symbol display device 37A, 37B and the third symbol display device 81, and the lottery of the display result on the second symbol display device are performed by the MPU 201. Execute

  Various commands are transmitted from the main control device 110 to the sub-control device by the data transmission / reception circuit in order to instruct the sub-control devices such as the payout control device 111 and the sound lamp control device 113 to operate. Such a command is transmitted from the main control device 110 to the sub control device only in one direction.

  The RAM 203 includes, in addition to various areas, counters, and flags, a stack area in which the contents of internal registers of the MPU 201 and a return address of a control program executed by the MPU 201 are stored. A work area (work area) in which values are stored. The RAM 203 has a configuration in which a backup voltage is supplied from the power supply 115 to retain data (backup) even after the power of the pachinko machine 10 is cut off, and all data stored in the RAM 203 is backed up. .

  When the power is shut down due to the occurrence of a power failure or the like, the stack pointer and the value of each register at the time of the power shutdown (including when a power failure occurs; the same applies hereinafter) are stored in the RAM 203. On the other hand, when the power is turned on (including turning on the power by turning off the power, the same applies hereinafter), the state of the pachinko machine 10 is returned to the state before the power was turned off based on the information stored in the RAM 203. Writing to the RAM 203 is executed when the power is turned off by a main process (not shown), and restoration of each value written to the RAM 203 is executed in a startup process (not shown) when the power is turned on. It should be noted that the power failure signal SG1 from the power failure monitoring circuit 252 is input to the NMI terminal (non-maskable interrupt terminal) of the MPU 201 when the power is cut off due to the occurrence of a power failure or the like. , An NMI interrupt process (not shown) as a power failure process is immediately executed.

  An input / output port 205 is connected to the MPU 201 of the main controller 110 via a bus line 204 composed of an address bus and a data bus. The input / output port 205 has a payout control device 111, a sound lamp control device 113, a first symbol display device 37A, 37B, a second symbol display device, a second symbol hold lamp, and a lower side of an opening / closing plate of the specific winning opening 65a. A solenoid 209 including a large opening solenoid for opening and closing the front side and a solenoid for driving an electric accessory is connected, and the MPU 201 sends various commands and control signals to these via an input / output port 205. Send

  The input / output port 205 includes various switches 208 including a switch group (not shown) and a sensor group including a slide position detection sensor S and a rotation position detection sensor R, and a RAM erasure switch circuit 253 described later provided in the power supply device 115. Is connected, and the MPU 201 executes various processes based on signals output from the various switches 208 and the RAM erase signal SG2 output from the RAM erase switch circuit 253.

  The payout control device 111 drives the payout motor 216 to control the payout of prize balls and loaned balls. The MPU 211 as an arithmetic unit has a ROM 212 storing a control program executed by the MPU 211, fixed value data, and the like, and a RAM 213 used as a work memory or the like.

  Like the RAM 203 of the main control device 110, the RAM 213 of the payout control device 111 has a stack area in which the contents of the internal registers of the MPU 211 and the return address of the control program executed by the MPU 211 are stored, and various flags and counters. , I / O and the like are stored. The RAM 213 has a configuration in which a backup voltage is supplied from the power supply device 115 so that data can be retained (backed up) even after the power of the pachinko machine 10 is cut off, and all data stored in the RAM 213 is backed up. Note that, similarly to the MPU 201 of the main control device 110, the NMI terminal of the MPU 211 is configured to receive the power failure signal SG1 from the power failure monitoring circuit 252 when the power is shut off due to the occurrence of a power failure or the like. When input to the MPU 211, an NMI interrupt process (not shown) as a process at the time of a power failure is immediately executed.

  An input / output port 215 is connected to the MPU 211 of the payout control device 111 via a bus line 214 composed of an address bus and a data bus. The input / output port 215 is connected to the main control device 110, the payout motor 216, the firing control device 112, and the like. Although not shown, the payout control device 111 is connected to a prize ball detection switch for detecting the paid prize ball. The prize ball detection switch is connected to the payout control device 111, but is not connected to the main control device 110.

  The launch control device 112 controls the ball launch unit 112a so as to have a launching strength of the ball according to the amount of rotation of the operation handle 51 when the main control device 110 gives an instruction to launch the ball. . The ball firing unit 112a includes a firing solenoid and an electromagnet (not shown), and the firing solenoid and the electromagnet are permitted to be driven when predetermined conditions are satisfied. Specifically, the touch sensor 51a detects that the player is touching the operation handle 51, and the operation is performed on condition that the firing stop switch 51b for stopping firing of the ball is turned off (not operated). The firing solenoid is excited in accordance with the amount of turning operation (rotating position) of the handle 51, and the ball is fired with a strength corresponding to the amount of operation of the operating handle 51.

  The sound lamp control device 113 outputs sound from a sound output device (such as a speaker (not shown)) 226, turns on and off lights from a lamp display device (lighting units 29 to 33, display lamps 34, etc.) 227, and produces a fluctuation effect (fluctuation). It controls the setting of the display mode of the third symbol display device 81, which is performed by the display control device 114, such as display) and a notice effect. The MPU 221 as an arithmetic unit has a ROM 222 storing a control program executed by the MPU 221 and fixed value data, and the like, and a RAM 223 used as a work memory or the like.

  The input / output port 225 is connected to the MPU 221 of the audio ramp control device 113 via a bus line 224 composed of an address bus and a data bus. The input / output port 225 includes a main controller 110, a display controller 114, an audio output device 226, a lamp display device 227, other devices 228, a frame button 22, a selection switch 270 (an upper switch 270a, a right switch 270b, a lower switch 270c). , Left switch 270d), decision switch 270e, and the like. Other devices 228 include drive motors 433, 462, 551 and solenoid 474.

  The sound lamp control device 113 determines the display mode of the third symbol display device 81 based on various commands (variation pattern command, stop type command, etc.) received from the main control device 110, and commands the determined display mode to a command. (Display variation pattern command, display stop type command, etc.). Further, the sound lamp control device 113 monitors an input from the frame button 22 and, when the player operates the frame button 22, changes the stage displayed on the third symbol display device 81 or performs super reach. The display control device 114 is instructed to change the effect content at the time. When the stage is changed, a back image change command including information on the changed stage is transmitted to the display control device 114 so that the third image display device 81 displays a rear image corresponding to the changed stage. . Here, the back image is an image displayed on the back side of the third symbol, which is a main image displayed on the third symbol display device 81. The display control device 114 displays various images on the third symbol display device 81 according to the command transmitted from the audio lamp control device 113.

  Further, the sound lamp control device 113 receives a command (display command) representing the display content of the third symbol display device 81 from the display control device 114. Based on the display command received from the display control device 114, the sound lamp control device 113 outputs a sound corresponding to the display content from the sound output device 226 in accordance with the display content of the third symbol display device 81. Lighting and extinguishing of the lamp display device 227 are controlled in accordance with the display contents.

  The display control device 114 is connected to the audio lamp control device 113 and the third symbol display device 81 and, based on a command received from the audio lamp control device 113, performs a variation effect of the third symbol in the third symbol display device 81. It controls display. In addition, the display control device 114 appropriately transmits a display command for notifying the display content of the third symbol display device 81 to the audio lamp control device 113. The sound lamp control device 113 outputs the sound from the sound output device 226 in accordance with the display content indicated by the display command, so that the display of the third symbol display device 81 and the sound output from the sound output device 226 are matched. be able to.

  The power supply unit 115 includes a power supply unit 251 for supplying power to each unit of the pachinko machine 10, a power failure monitoring circuit 252 for monitoring power interruption due to a power failure or the like, and a RAM provided with a RAM erase switch 122 (see FIG. 3). And an erase switch circuit 253. The power supply unit 251 is a device that supplies a required operating voltage to each of the control devices 110 to 114 and the like via a power supply path (not shown). As an outline, the power supply unit 251 takes in a voltage of AC 24 volts supplied from the outside, and outputs a voltage of 12 volts for driving various switches such as various switches 208, a solenoid such as the solenoid 209, a motor, and the like. A voltage of 5 volts for logic, a backup voltage for RAM backup, and the like are generated, and these 12 volts, 5 volts and backup voltage are supplied to necessary voltages to the control devices 110 to 114 and the like.

  The power failure monitoring circuit 252 is a circuit for outputting a power failure signal SG1 to each NMI terminal of the MPU 201 of the main control device 110 and the MPU 211 of the payout control device 111 when the power is cut off due to the occurrence of a power failure or the like. The power failure monitoring circuit 252 monitors a DC stable voltage of 24 volts, which is the maximum voltage output from the power supply unit 251, and determines that a power failure (power interruption, power interruption) has occurred if this voltage falls below 22 volts. Then, the power outage signal SG1 is output to the main control device 110 and the payout control device 111. Based on the output of the power failure signal SG1, the main control device 110 and the payout control device 111 recognize the occurrence of the power failure and execute the NMI interrupt processing. Note that, even after the DC stable voltage of 24 volts becomes less than 22 volts, the power supply unit 251 outputs the voltage of 5 volts, which is the drive voltage of the control system, for a time sufficient for executing the NMI interrupt processing. Is maintained at a normal value. Therefore, main controller 110 and payout controller 111 can normally execute and complete the NMI interrupt process (not shown).

  The RAM erasure switch circuit 253 is a circuit for outputting a RAM erasure signal SG2 for clearing the backup data to the main controller 110 when the RAM erasure switch 122 (see FIG. 3) is pressed. The main controller 110 clears the backup data when the RAM erasing signal SG2 is input when the power of the pachinko machine 10 is turned on, and also controls the payout control device 111 to execute a payout initialization command for clearing the backup data. Transmit to the device 111.

  Next, the game board 13 and the operation unit 200 will be described with reference to FIGS. First, with reference to FIGS. 5 and 6, a description will be given of a structure in which the units 400 and 500 are housed in the rear case 210. FIG.

  FIG. 5 is a front perspective view of the operation unit 200, and FIG. 6 is an exploded front perspective view of the operation unit 200 when the disassembled operation unit 200 is viewed from the front.

  As shown in FIGS. 5 and 6, the operation unit 200 is opened on one side (front side in FIG. 6) from the bottom wall 211 and the outer wall 212 erected from the outer edge of the bottom wall 211. And a rear case 210 formed in a box shape. The rear case 210 is formed in a rectangular frame shape in a front view by forming a rectangular opening 211a at the center of the bottom wall portion 211. The opening 211a is formed in a size corresponding to the outer shape of the third symbol display device 81 (see FIG. 2) (that is, in which the third symbol display device 81 can be disposed).

  The left, right, and upper outer wall portions 212 include an intermediate wall portion 212a formed in the middle in the front-rear direction and parallel to the bottom wall portion 211, and a fastening portion 212b capable of fastening a member to the intermediate wall portion 212a. On the front side of the intermediate wall portion 212a, the outer wall portion 212 extends from the end opposite to the opening 211a of the intermediate wall portion 212a, and on the back side of the intermediate wall portion 212a, the outer wall portion 212 is It extends from the end of the side 212a adjacent to the opening 211a.

  The holding and fixing portion 446 and the fixing plate 461 are fastened and fixed to the fastening portion 212b formed on the left and right intermediate wall portions 212a, and the guide plate 424 is fixed to the fastening portion 212b formed on the upper middle wall portion 212a. Are fastened and fixed.

  Here, the fixing plate 461 is a member that supports a drive motor 462 that generates a driving force for driving the composite operation unit 400, and the holding and fixing portion 446 is a member that fixes one end of the biasing spring 445, and the guide plate 424. Is a member for guiding the movement of the connecting member 423 (see FIG. 20) of the composite operation unit 400. In other words, none of these is a production part directly visible to the player, but a part having an auxiliary role of production for generating a driving force for the operation of the combined operation unit 400 or guiding the operation. .

  By disposing the fixing plate 461, the holding and fixing portion 446, and the guide plate 424 having such a role near the front side of the rear case 210, a space near the rear side of the rear case 210 can be opened. By using the vacant space on the rear side as a space for retreating a portion that is actually visually recognized by the player, such as the shielding member 420, the constituent members of the composite operation unit 400 can be stacked back and forth, and the opening 211a The width required for retracting the composite operation unit 400 to the outside can be reduced. Therefore, the formation width of the bottom plate portion 211 can be reduced. Thereby, the opening 211a can be enlarged, and the formation range of the third symbol display device 81 can be enlarged.

  In the operation unit 200, the composite operation unit 400 and the swing operation unit 500 are respectively housed in the internal space of the rear case 210, and are configured as one unit.

  Specifically, the composite operation unit 400 is disposed on the left, right, and upper portions of the area formed by the inner surface of the outer wall 212 of the rear case 210, and the swing operation unit 500 is disposed inside the outer wall 212 of the rear case 210. It is disposed below the area formed by the side surface (see FIG. 5).

  Next, with reference to FIGS. 7 to 9, an outline of operation modes of the composite operation unit 400 and the swing operation unit 500 will be described. In the description of FIGS. 7 to 9, FIGS. 5 and 6 will be referred to as appropriate.

  7 to 9 are front views of the operation unit 200. FIG. Note that FIG. 7 shows a state where the main body member 410 of the composite operation unit 400 is located at the overhang position, FIG. 8 shows a state where the moving member 540 of the swing operation unit 500 is located at the overhang position, and FIG. The state in which the main body member 410 of the composite operation unit 400 and the moving member 540 of the swing operation unit 500 are arranged at the extended position is illustrated.

  As shown in FIG. 7, the composite operation unit 400 operates the main body member 410 between the retracted position shown in FIG. 5 and the extended position shown in FIG. That is, at the retracted position shown in FIG. 5, the main body member 410 is retracted above the opening 211a of the rear case 210 (see FIG. 2). On the other hand, in the extended position shown in FIG. 7, the main body member 410 is lowered, and the main body member 410 is disposed at the center of the opening 211a of the rear case 210 (that is, in front of the third symbol display device 81, see FIG. 2). . The composite operation unit 400 is a unit that performs two kinds of operations (sliding operation and swinging operation) in which the shielding member 420 moves in a different manner by sliding the main body member 410 as described later.

  As shown in FIG. 8, the swing operation unit 500 operates the moving member 540 between the retracted position shown in FIG. 5 and the extended position shown in FIG. In the retracted position shown in FIG. 5, the moving member 540 is retracted below the opening 211a of the rear case 210 (see FIG. 2). On the other hand, in the overhang position shown in FIG. 8, the moving member 540 is raised, and the moving member 540 is disposed at the center of the opening 211a of the rear case 210 (that is, in front of the third symbol display device 81, see FIG. 2). . The moving members 540 are formed as a pair of left and right, and at the projecting position shown in FIG.

  As shown in FIG. 9, both the composite operation unit 400 and the swing operation unit 500 can be arranged at the extended position. In this case, the composite operation unit 400 and the swing operation unit 500 can be visually recognized as an integrated decorative member (partially overlapped in a front view), and a decorative member having a width equal to or larger than the width outside the opening 211a is formed. be able to. Thereby, the effect of the combined operation unit 400 and the swing operation unit 500 can be improved. In addition, since the composite operation unit 400 and the swing operation unit 500 project toward the center of the opening 211a in different directions (downward and upward), for example, compared with a case where all the movable members extend in the same direction, The distance that each member moves from the retracted position to the extended position can be reduced. Accordingly, when the moving speeds of the combined operation unit 400 and the swing operation unit 500 are the same, the period of moving from the retreat position to the overhang position can be reduced.

  Next, with reference to FIG. 10 to FIG. 18, the board lower unit 300 disposed below the game board 13 will be described. 10 and 11 are front exploded perspective views of the game board 13 and the board lower unit 300, and FIG. 12 is a rear exploded perspective view of the game board 13 and the board lower unit 300. Note that FIG. 10 shows a state in which only the front plate member 320 is disassembled from the game plate 13, and FIGS. 11 and 12 show that the front unit 310 and the variable winning device 330 of the lower panel unit 300 are further divided from FIG. It is disassembled from the board 13. In order to facilitate understanding, the game board 13 is illustrated in a simplified manner.

  As shown in FIG. 10, a specific winning opening 65a is formed along the lower edge of the inner rail 61. Since the lower edge of the inner rail 61 is formed in a downwardly convex curved shape, the arrangement position of the specific winning opening 65a is smaller than that in the case where the lower side of the specific winning opening 65a is formed by a straight line along the left-right direction. Can be lowered downward. The outer edge of the specific winning opening 65a has an upper side formed by the movable upper lid member 332, a lower side formed by the lower edge of the inner rail 61, and left and right sides formed by left and right walls of the opening upper portion 313. .

  As described below, the specific winning opening 65a is switched between the closed state and the open state by sliding the movable upper cover member 332 back and forth, and the opening and closing operation of the specific winning opening 65a is, for example, up to 15 times. Times (15 rounds) can be repeated.

  As shown in FIG. 11, the lower panel unit 300 is a unit that forms an out port 314 from which a ball is discharged and a specific winning port 65 a, and is a receiving unit that is formed in the lower part of the game panel 13 in the front-rear direction. The front unit 310 is fitted into the opening 60a from the front side and fastened and fixed, the front plate member 320 is fastened and fixed to the front unit 310 from the front side and has a ball path formed on the back side, and the receiving opening 60a. And a variable winning device 330 having a movable upper lid member 332 that is fitted and fastened and fixed from the back side and changes the flowing direction of the ball.

  The front side unit 310 includes a plate-shaped main body plate portion 311 formed so that a ball can flow down the front side, and an electric accessory 640a in which a pair of members is opened and closed right and left at the front center of the main body plate portion 311. A plate-shaped inclined plate portion 312 protruding forward from the left and right upper portions of the main body plate portion 311; an upper opening portion 313 recessed upward from a lower bottom portion of the main body plate portion 311; And a pair of out ports 314 that are drilled in the front-rear direction on both left and right sides of the part 313 and that discharge the ball out of the game area.

  The main body plate portion 311 is formed in a front-rear direction at a position surrounded by a first winning opening lower side 311a formed above the electric accessory 640a and forming a lower side of the first winning opening 64 and a pair of members of the electric accessory 640a. A second winning opening 640 provided, a light irradiating device 311b arranged below the second winning opening 640 to illuminate the front side of the second winning opening 640, and a rib-like front outside the out opening 314. And a ball-flowing rib 311c that is protruded.

  The light irradiation device 311b is accommodated in the accommodating recess 323a (see FIG. 12) of the front plate member 320, and is directed upward (to the second winning opening 640 side) due to the ball winning the second winning opening 640. The LED member is irradiated with light.

  The ball flowing rib 311c adjusts the flowing direction of the ball rolling along the inner rail 61, and will be described later in detail with reference to FIG.

  The inclined plate portion 312 is formed so that a ball can roll on the upper side surface, is disposed on the left and right of the electric accessory 640a, and is inclined downward as it approaches the electric accessory 640a. Thus, when the electric accessory 640a is in the open state in which the electric accessory 640a is tilted left and right, the ball that is rolled down by rolling the inclined plate portion 312 can be made to win the second winning opening 640 with a high probability. On the other hand, when the electric accessory 640a is in the closed state in which it stands up, the sphere that rolls down the inclined plate portion 312 can drop with high probability to the front side of the upper opening portion 313.

  The upper opening portion 313 is formed to be inclined upward toward the left and right center. Here, by setting the vertical width of the central portion in the left-right direction of the specific winning opening 65a to be equal to or larger than the diameter of the sphere, the vertical width of the left and right walls of the upper opening portion 313 (corresponding to the left and right walls of the specific winning opening 65a). ) Can be set to a length less than or equal to the diameter of the sphere (see FIG. 17). In this case, it is difficult to make the ball win from the left and right ends of the specific winning opening 65a, but the ball flows down to the center of the game board 13 along the inner rail 61, and the center of the specific winning opening 65a in the left and right direction. , The game can be continued.

  Here, when the upper and lower side surfaces of the specific winning opening 65a are parallel planes (a plane extending in the left-right direction), until the straight line intersecting with the inner rail 61 becomes the same as the length of the lower surface of the specific winning opening 65a. It is necessary to arrange the specific winning opening 65a so as to rise from the lower edge of the inner rail 61. Therefore, the position of the specific winning opening 65a becomes higher.

  On the other hand, in the present embodiment, since the lower side surface of the specific winning opening 65a is formed to be curved similarly to the lower surface of the inner rail 61, it is not necessary to arrange the specific winning opening 65a upward, and the specific winning opening 65a is positioned at a low position. Can be arranged.

  Further, since the upper side surface of the specific winning opening 65a is inclined downward as it approaches the left and right ends, the ball is moved to the specific winning opening 65a as compared with a case where the upper side surface is formed by a plane extending in the left and right direction. Can be lowered downward. Thereby, the lower edge of the third symbol display device 81 can be lowered.

  The out opening 314 is formed as a pair on the left and right sides of the upper opening portion 313, and the lower side of the out opening 314 is disposed below and the upper side of the out opening 314 is disposed above the left and right ends of the upper opening portion 313. You. That is, the upper opening portion 313 is formed below the out opening 314. Thereby, the arrangement of the variable winning device 330 described later can be lowered, and the lower edge of the third symbol display device 81 can be lowered. Note that, even with such an arrangement, in the present embodiment, the sphere flows down the upper surface of the movable upper lid member 332 which has an upper side surface substantially the same as the shape of the upper opening portion 313 and is slid in the front-rear direction. Is discharged to the out port 314 (see FIG. 17), so that the game can be continued.

  The front plate member 320 is a plate-shaped member formed of a light-transmissive resin material, is disposed on the front side of the front unit 310, and is formed so that a sphere can flow between itself and the main body plate portion 311. Plate portion 321, a first winning opening front portion 322 arranged at the upper end of the main body plate portion 321 for guiding the ball to the lower side 311 a of the first winning opening, and disposed below the electric accessory 640 a. The lower part 323 of the electric accessory which is provided, the lower plate 324 of the outer opening disposed along the lower surface of the outlet 314, and the rear side protruding from the main body plate 321 along the lower edge of the inner rail 61. And a ball feeder 325.

  The main body plate portion 321 includes a spherical flow rib 321a protruding in a rib shape on the back side outside the lower opening plate 324. The ball running rib 321a adjusts the flowing direction of the ball rolling along the inner rail 61, and the details will be described later with reference to FIG.

  The electric accessory lower support portion 323 includes a housing recess 323a that is a horizontally long recess, and the light irradiation device 311b is housed in the housing recess 323a.

  The outer mouth lower plate 324 is provided with thin ribs extending in the front-rear direction on the upper side surface in the left-right direction. Further, the out-opening lower plate 324 includes a step portion 324a projecting upward at left and right inner end portions. Due to the unevenness formed on the upper side surface of the out mouth lower plate 324, the flowing ball can be decelerated. The ribs formed on the lower plate 324 are formed to be inclined downward toward the rear side. Thus, the speed at which the flowing ball is discharged to the out port 314 can be improved.

  Since the above-mentioned inclined plate portion 312 is formed directly above the lower plate 324 (see FIG. 17), the ball falling after rolling the inclined plate portion 312 is directed toward the lower plate 324. Falling is suppressed. In other words, the ball that falls after rolling on the inclined plate portion 312 falls inside the left-right direction of the pair of out-opening lower plates 324 (the position where the movable upper lid member 332 is disposed), or Either it falls to the outer end (near the ball-flowing rib 321a and at the boundary between the rib formation range and the rail on which the ball flows). These are both out of the rib formation range. Thus, it is possible to suppress the ball from falling from a high place on the lower plate 324 of the outer opening, and to improve the durability of the lower plate 324 of the outer opening.

  The step portion 324a is a step formed between the out opening 314 and the specific winning opening 65a, and a ball flowing down in the left-right direction and flowing down the upper side surface of the out opening lower plate 324 exceeds the step portion 324a. Thus, it is prevented from flowing down to the center in the left-right direction (see FIG. 17). That is, the ball that flows down from the left and right direction and flows down the upper side surface of the out-port lower plate 324 is guided exclusively to the out-port 314.

  The ball feeder 325 mainly includes a back side surface 325a formed on the back side, and left and right side surfaces 325b connected to the back side surface 325a and formed on the left and right sides.

  The rear side surface 325a is inclined downward toward the rear side, and the left and right side surface 325b is inclined toward the center toward the rear side. Thereby, the falling direction of the sphere that has reached the sphere feeding unit 325 can be directed to the back side. Therefore, it is possible to suppress the ball from staying in front of the specific winning opening 65a, and to prevent a so-called over winning.

  Next, the variable winning device 330 will be described with reference to FIGS. FIG. 13 is an exploded front perspective view of the variable winning device 330, FIG. 14 is an exploded rear perspective view of the variable winning device 330, and FIG. 15 (a) is a top view of the variable winning device 330. 15 (b) is a front view of the variable winning device 330, and FIG. 15 (c) is a side view of the variable winning device 330 as viewed in the direction of the arrow XVc in FIG. 15 (b).

  As shown in FIGS. 13 and 14, the variable winning device 330 includes a main body member 331 that forms a skeleton, a movable upper lid member 332 that is inserted through the main body member 331 from the front, and that is formed to be slidable in the front-rear direction. A rear lid member 334 accommodating a solenoid 333 for generating a driving force for slidingly moving the movable upper lid member 332 and a lever member 334b pivoted by the solenoid 333, and being fastened and fixed to the rear side of the main body member 331. And mainly comprising.

  The main body member 331 is provided with a deformed through hole 331a through which the movable upper lid member 332 is inserted, a lower passage 331b through which a ball won at the specific winning opening 65a flows down, and is disposed below the lower passage 331b and directed upward. A light irradiating device 331c for irradiating light, and a back side housing portion 331d which is a recess formed to be recessed toward the front side on the back side and houses the solenoid 333, the lever member 334b, and the like. .

  As shown in FIGS. 15A and 15B, the deformed through hole 331a is a through hole formed along the shape of the movable upper lid member 332, and is a front side for receiving the front side plate portion 332a. It mainly has an opening 331a1 and a rear opening 331a2 for accommodating the rear plate 332b.

  The front opening 331a1 is a pentagon-shaped dent having a lower side extending horizontally in a front view, and being inclined upward as the upper side goes toward the center, and having left and right sides extending vertically.

  The rear opening 331a2 is an opening formed by cutting off the left and right portions of the front opening 331a1 from the central part on the rear side of the front opening 331a1. That is, the outer shape of the lower side and the upper side of the rear opening 331a2 and the outer shape of the lower side and the upper side of the front opening 331a are not formed in the front-rear direction, but are formed at surface positions. Thereby, the movable upper lid member 332 can be smoothly guided.

  The lower passage 331b is formed as a pair of right and left so as to allow a ball to pass therethrough (see FIG. 18A), and is formed so as to protrude below the lower edge of the inner rail 61. Is provided (see FIG. 15B).

  The light irradiating device 331c is a device that illuminates the lower passage 331b, the plate-shaped portion 332a1, and the like with light, and is disposed below the inner rail 61 (below the receiving opening 60a). Thus, since the devices and the like required for the light irradiation device 331c can be disposed below the inner rail 61, a space on the back side of the game board 13 can be secured, and the third symbol display device 81 (FIG. 2) can be lowered downward.

  The light irradiation device 331c includes a light irradiation unit 331c1 that irradiates light. The light irradiation part 331c1 is formed as a pair of right and left directly below the lower passage 331b, and irradiates light upward.

  The back side housing portion 331d communicates with the front opening portion 331a1 with the rear opening portion 331a2 interposed therebetween.

  The moving upper lid member 332 is a long member formed of a light-transmissive resin material, and includes a front plate portion 332a housed in the front opening 331a1, a rear plate portion 332b housed in the rear opening 331a2. A central rib 332c protruding downward along the central axis of the front plate portion 332a and the rear plate portion 332b, and a connection hole 332d formed vertically in a rear end portion of the rear plate portion 332b. Prepare mainly.

  The front side plate portion 332a is formed in a plate-like portion 332a1 formed in such a manner as to rise and incline toward the center in the left-right direction along the shape of the upper side of the front opening portion 331a1, and is formed in the vertical direction of the plate-like portion 332a1. And a guide rib 332a3 that protrudes downward at the left-right end of the plate-shaped portion 332a1 and extends in the front-rear direction.

  The plate-shaped portion 332a1 includes a front inclined side surface 332a1f that is formed to be inclined downward toward the rear side as it goes downward (see FIG. 16) and that is recessed toward the rear side toward the center in the left-right direction. Since the front inclined side surface 332a1f is formed so as to be concave toward the rear side toward the center in the left-right direction, the ball can flow toward the center side when the ball is sandwiched between the front plate member 320 and the front inclined side surface 332a1f. In addition, it is possible to prevent the sliding operation of the movable upper lid member 332 from being hindered by the ball.

  Since the front inclined side surface 332a1f is formed as a part for reflecting light as described later, a metal film is formed on the front inclined side surface 332a1f or mirror-finished to reflect light effectively. You may. In this embodiment, a tape that reflects light is attached.

  The guide rib 332a3 is formed along the left and right side surfaces of the front opening 331a1 in the assembled state (see FIG. 15), and is in contact with the lower side surface of the front opening 331a1. Thereby, it is possible to suppress the displacement in the left-right direction at the time of sliding movement of the movable upper cover member 332.

  The center rib 332c is formed at a bent portion of the front plate portion 332a formed by bending a plate shape. Thereby, the rigidity of the front side plate part 332a can be improved. Further, when the movable upper lid member 332 is slid forward (when the movable upper lid member 332 of the variable winning device 330 is in the retracted state), the movable upper lid member 332 is fixed to the back side of the upper opening portion 313. Accordingly, it is possible to prevent the movable upper lid member 332 from malfunctioning due to the collision between the center rib 332c and the ball.

  The connection hole 332d is a through hole through which the connection portion 334b4 of the lever member 334b is inserted and the displacement due to the swing of the lever member 334b is transmitted to the movable upper cover member 332 (see FIG. 16).

  The solenoid 333 mainly includes a main body 333a serving as a driving source, and a hook-shaped hook-shaped member 333b disposed below the main body 333a and vertically moved below the lever member 334b.

  The rear cover member 334 mainly includes a plate-shaped main body portion 334a, and a lever member 334b pivotally supported by the main body portion 334a and having a front end formed to be movable in the front-rear direction.

  The lever member 334b includes a main body 334b1 extending vertically and a pair of shafts 334b2 protruding in the left and right directions at the lower end of the main body 334b1 in a columnar shape and supported by the main body 334a. A lower claw portion 334b3 that extends below the main body portion 334b1 at a substantially intermediate position between the pair of shaft portions 334b2 and is formed so as to be able to receive the hook-shaped member 333b between the main body portion 334b1 and the upper end portion of the main body portion 334b1. And a connecting portion 334b4 formed to bulge in a columnar shape.

  Next, the sliding movement of the movable upper cover member 332 will be described with reference to FIG. FIG. 16A is a cross-sectional view of the variable winning device 330 taken along the line XVIa-XVIa in FIG. 15B, and FIG. 16B is a diagram showing the movable upper cover member 332 sliding from the state of FIG. 16A. It is sectional drawing of the variable winning device 330 after it is made to perform. FIG. 16A illustrates a retracted state in which the movable upper lid member 332 is disposed rearward, and FIG. 16B illustrates a protruding state in which the movable upper lid member 332 is disposed forward, and FIG. In order to facilitate understanding of the path E1, the central rib 332c is partially omitted. In FIGS. 16A and 16B, the inner rail 61 and the front plate member 320 in the assembled state (see FIG. 2) are virtually illustrated by imaginary lines.

  As shown in FIG. 16A, when the movable upper lid member 332 is in the retracted state, the hook-shaped member 333b is disposed upward, and the lever member 334b is tilted backward. In this state, the ball can flow down in front of the variable winning device 330, that is, the ball can win (open state) at the specific winning opening 65a (see FIGS. 10 and 17).

  On the other hand, as shown in FIG. 16 (b), when the movable upper cover member 332 is in the overhanging state, the hook member 333b is pressed downward, so that the lever member 334b is tilted forward about the shaft portion 334b2, and The movable upper lid member 332 is slid to the front side while being in contact with the side surface of the side housing portion 331b. In this state, the ball cannot be won (closed state) at the specific winning opening 65a (see FIGS. 10 and 17).

  In this case, the back side surface of the lower end of the hook-shaped member 333b abuts on the end of the lower claw portion 334b3 of the lever member 334b in the front-rear direction, whereby the swing of the lever member 334b is mechanically restricted. (The hook-shaped member 333b is arranged in the moving direction of the lower claw portion 334b3, and the moving direction of the lower claw portion 334b3 is orthogonal to the moving direction of the hook-shaped member 333b). Therefore, the driving force of the solenoid 333 can be suppressed as compared with the case where the swing of the lever member 334b is stopped by the driving force of the solenoid 333.

  Here, the path of the light emitted from the light irradiation device 331c will be described with reference to FIG.

  As shown in FIG. 16A, when the movable upper cover member 332 is in the retracted state, the light emitted upward from the light irradiation unit 331c1 reaches the front inclined side surface 332a1f of the plate-shaped portion 332a1 along the path E1. I do. At this time, since the front inclined side surface 332a1f is formed so as to be inclined rearward as it goes downward, the light emitted from below and reaching the front inclined side surface 332a1f is reflected toward the front (player side). In this case, the player can visually recognize as if the front inclined side surface 332a1f of the movable upper lid member 332 is emitting light. Further, since the light reflected by the front inclined side surface 332a1f is projected on the light projection range E0 of the front plate member 320, the front plate member 320 can be noticed. Thereby, the performance ability of the movable upper lid member 332 and the front plate member 320 can be improved.

  Here, when an LED or the like is arranged on the movable upper cover member 332 to cause the movable upper cover member 332 to emit light, the movable upper cover member 332 may be enlarged. On the other hand, in the present embodiment, since the LED is not provided on the movable upper lid member 332, it is possible to improve the performance of the movable upper lid member 332 as an effect portion while suppressing the movable upper lid member 332 from being enlarged. Can be.

  As shown in FIG. 16B, when the movable upper cover member 332 is in the extended state, the light is emitted upward along the path E2 from the light irradiation unit 331 c 1, and the light traveling toward the front inclined side surface 332 a 1 f is transmitted to the inner rail 61. Does not reach the front inclined side surface 332a1f of the plate portion 332a1. In this case, the light irradiated from the light irradiation unit 331c1 along the path E1 reaches the intermediate position of the plate-shaped portion 332a1 of the front plate portion 332a and only passes through as it is, so the front inclined side surface 332a1f and the front plate member 320 Is visually recognized by the player as dark.

  That is, depending on whether the movable upper lid member 332 is in the retracted state or the extended state, whether or not the light irradiated from the light irradiation unit 331c1 reaches the front inclined side surface 332a1f changes. Whether or not the light projection range E0 of the member 320 is visually recognized changes. Therefore, by checking the state of the brightness of the light projecting range E0 of the front inclined side surface 332a1f and the front plate member 320, it can be confirmed whether or not a ball can be won in the specific winning opening 65a.

  Accordingly, even when the movable upper lid member 332 slides back and forth as in the present embodiment, it is difficult to grasp the change in the state of the movable upper lid member 332 in a front view (FIGS. 17A and 17B). )), It is possible to easily confirm whether or not a ball can be won in the specific winning opening 65a by a change in the brightness of the light projection range E0.

  Here, the movable upper lid member 332 operates to form a closed state that prevents the ball from passing to the specific winning opening 65a and an open state that allows the ball to pass to the specific winning opening 65a ( Only the forward / backward slide movement) changes the brightness state of the projection range E0. In other words, since the state of the light projecting range E0 is changed only by the operation required for the movable upper lid member 332 to continue the game, no additional mechanism is required. In other words, the movable upper lid member 332 can be used for both the purpose of switching whether or not the ball passes through the specific winning opening 65a and the purpose of producing an effect using the light emitted from the light irradiation unit 331c1.

  When the sphere passes through the lower passage 331b and crosses the path E1, the light emitted from the light irradiating unit 331c may be reflected by the sphere to produce an effect. In this case, the vicinity of the inner rail 61 (below the light projection range E0 in FIGS. 16A and 17B) can be brightly illuminated in a front view.

  With reference to FIG. 17, a description will be given of the flow of the ball when the movable upper lid member 332 forms the extended state and when the movable upper lid member 332 forms the retracted state. FIG. 17A and FIG. 17B are partial front views of the game board 13. FIG. 17A illustrates a case where the movable upper lid member 332 forms an overhanging state (see FIG. 16B), and FIG. 17B illustrates a case where the movable upper lid member 332 is in the retracted state (FIG. 16B). 17 (a) is shown. In FIGS. 17 (a) and 17 (b), the main body plate portion 321 of the front plate member 320 is shown in imaginary lines. 17 (a) and 17 (b), whether or not the movable upper lid member 332 is overhanging is shown by the presence or absence of hatching. That is, in FIG. 17 (a) and FIG. 17 (b), the shaded portion is in contact with the front plate member 320 or the front plate is so large that it blocks the passage of a ball between the front plate member 320. This is a portion close to the member 320.

  In the state shown in FIG. 17A, the sphere that falls on the route C2 flows down along the upper side surface of the movable upper lid member 332 and is discharged to the out port 314. In this case, the movable upper lid member 332 may fall down due to the weight of the ball, and when the left and right ends of the movable upper lid member 332 are moved below the step portion 324a, the ball is discharged to the out port 314. You will not be able to play games.

  On the other hand, in the present embodiment, the movable upper lid member 332 has a length several times (about four times as long as that shown in FIG. 16 (b)) the length protruding to the front side of the modified through hole 331a. It is housed in the modified through hole 331a and is formed so as to be able to contact the side surface of the modified through hole 331a in the vertical direction over the front and rear direction of the variable winning device 330. Therefore, by reducing the clearance between the movable upper lid member 332 and the deformed through hole 331a, it is possible to prevent the movable upper lid member 332 from falling down due to the weight of the ball colliding with the movable upper lid member 332. Accordingly, the left and right ends of the movable upper cover member 332 can be formed at the same level as the step 324a, and the nail to the specific winning opening 65a can be lowered. The rim can be lowered.

  As shown in FIG. 17B, when the movable upper lid member 332 is in the retracted state, the ball can flow down to the specific winning opening 65a. At this time, the ball rolling on the route C1 from the left and right along the inner rail 61 collides with the step portion 324a and is discharged to the out opening 314, and the ball falling on the route C2 from above toward the specific winning opening 65a. Rolls on the inner rail 61 and reaches the specific winning opening 65a.

  Here, in the present embodiment, the vertical width of the left and right ends of the specific winning opening 65a is formed to be equal to or less than the diameter of the sphere. That is, the vertical distance from the inner rail 61 at the left and right ends of the movable upper lid member 332 is formed to be equal to or less than the diameter of the sphere. Therefore, the height of the step portion 324a from the inner rail 61 can be reduced, and the arrangement of the out port 314 to which the ball falling from the step portion 324a reaches can also be lowered.

  In this case, it is difficult for the ball to enter from the left and right ends of the specific winning opening 65a (in addition, in the present embodiment, the ball is blocked by the base plate 60). However, since the lower side of the specific winning opening 65a is formed along the inner rail 61, the ball that has flowed to the front side of the left and right ends of the specific winning opening 65a rolls toward the center of the game area along the inner rail 61 by gravity. Is moved, and the ball enters the specific winning opening 65a from there. In addition, since the lower edge of the inner rail 61 is formed to be inclined rearward (see FIG. 16), the ball can smoothly enter the specific winning opening 65a (see FIG. 17).

  Thereby, the movable upper lid member 332 forming the upper side of the specific winning opening 65a is separated upward from the inner rail 61 at least in the vicinity of the center of the game area (near where the inner rail 61 is disposed at the lowest position) or more than the diameter of the ball. It is sufficient to lower the position of the movable upper lid member 332 downward. Therefore, the arrangement position of the variable winning device 330 can be lowered in comparison with the case where it is necessary to be separated upward from the inner rail 61 more than the diameter of the sphere at a position other than the vicinity of the center of the inner rail 61. Thereby, the space on the back side of the game board 13 can be secured, and the lower edge of the third symbol display device 81 (see FIG. 2) can be lowered.

  Next, with reference to FIG. 18, a description will be given of the function of the spherical flow ribs 311c and 321a and the spherical feed portion 325 and the fact that light is collected by the front inclined side surface 332a1f. 18A is a cross-sectional view of the lower panel unit 300 taken along line XVIIIa-XVIIIa in FIG. 17B, and FIG. 18B is a lower panel unit 300 taken along line XVIIIb-XVIIIb in FIG. 17A. 18C is a cross-sectional view of the lower panel unit 300 in which the arrangement of the light irradiation unit 331c1 is virtually changed from FIG. 18B.

  In FIG. 18A, the rolling path of the ball is described by paths C1a, C1b, and C2a, and the movable upper lid member 332 in the retracted state is illustrated by imaginary lines. The moving upper lid member 332 is located on the near side (upper side in FIG. 17B) with respect to the cross section of FIG. 18A, and is not actually visible. FIG. 18 (a) is shown by an imaginary line in a state where the positions (when viewed in the vertical direction) match. 18B and FIG. 18C, three spheres flowing down the lower passage 331b are virtually illustrated.

  The path of a ball that is rolled from the left and right along the inner rail 61 (see FIG. 11) and discharged to the out port 314 will be described. As shown in FIG. 18 (a), the sphere rolling from the left / right direction toward the center of FIG. 18 (a) abuts on at least one of the sphere running rib 311c or the sphere running rib 321a. That is, the sphere rolling while abutting on the main body plate portion 311 of the front unit 310 abuts against the ball-flowing rib 311c, and the sphere rolling while abutting on the main body plate portion 321 of the front plate member 320 is a ball-flowing rib. 321a.

  Here, when the sphere flows and abuts against the rib 311c, the velocity direction of the sphere is directed in the direction along the path C1a, and then abuts on the sphere flowing rib 321a. Therefore, regardless of whether the ball rolls while abutting on the main body plate portion 311 of the front unit 310 or rolls while abutting on the main body plate portion 321 of the front plate member 320, the rolling ball has a longer ball length. It can contact the rib 321a.

  By causing the ball rolling along the inner rail 61 (see FIG. 11) to flow into contact with the rib 321a, the velocity direction of the ball can be directed in the direction along the path C1b. In this case, the velocity of the ball can be directed to the rear side (upward in FIG. 18A) before the ball is arranged on the front side of the out port 314. Therefore, the period from when the ball is arranged on the front side of the out port 314 to when the ball is discharged from the game area can be shortened, and it is possible to suppress the ball from staying on the front side of the out port 314. At the same time, the opening width of the out port 314 can be suppressed. Thereby, when the specific winning opening 65a (see FIG. 10) and the out opening 314 are arranged side by side, the arrangement of the specific winning opening 65a can be lowered below the game area.

  A case where the ball falls between the stepped portions 324a arranged in a pair on the left and right will be described. In this case, the ball that has fallen between the steps 324a rolls toward the center in the left-right direction, and the ball abuts on the left and right side surfaces 325b of the ball feeder 325, so that the velocity direction of the ball is along the path C2a. Change. Thus, the ball can be prevented from staying in front of the specific winning opening 65a (see FIG. 10), so that an over winning can be suppressed.

  When the sphere flows down along the lower passage 331b and crosses the light irradiated from the light irradiation unit 331c1, the sphere blocks the light, so that the light does not reach the front inclined side surface 332a1f. Therefore, it is possible to confirm whether or not the ball has won the specific winning opening 65a (see FIG. 17) based on whether the light projecting range E0 of the front inclined side surface 332a1f or the front plate member 320 is viewed bright or dark. it can.

  Thereby, as in the present embodiment, the front plate member 320 formed of a light-transmitting resin material is disposed in front of the specific winning opening 65a, and the inside of the specific winning opening 65a is difficult to visually recognize. Also, it can be confirmed that the ball has entered the specific winning opening 65a by the change in the brightness of the light projecting range E0. Therefore, it is not necessary to remove the specific winning opening 65a obliquely from above in order to confirm that the ball enters the specific winning opening 65a, and the burden on the player can be reduced.

  In the present embodiment, the irradiation direction of the light irradiated from the light irradiation unit 331c1 and the flow direction of the sphere flowing down the lower passage 331b intersect at an angle close to a right angle (see FIG. 18B). Therefore, compared to the case where the ball flows down in the light traveling direction (see FIG. 18C) or the case where the ball flows down in the light irradiation direction, the ball enters the specific winning opening 65a. The period in which the sphere flowing down the lower passage 331b blocks light can be shortened. In other words, it is possible to lengthen the period in which the light projecting range E0 of the front inclined side surface 332a1f and the front plate member 320 is viewed brightly, and it is possible to secure the performance of the front inclined side surface 332a1f and the front plate member 320.

  As shown in FIG. 18B, when the light path E1 and the flowing direction of the sphere flowing down the lower passage 331b intersect (cross) at an angle close to a right angle, the light path E1 is blocked by the sphere. Thereafter, around the time when the sphere passes through the front end of the lower passage 331b (the right side in FIG. 18B), the light is no longer blocked by the sphere (light reaches the front inclined side surface 332a1f).

  In this case, even if the balls continue to flow down the lower passage 331b, the path E1 is shielded for each ball, so that the change in the brightness of the light projecting range E0 of the front inclined side surface 332a1f and the front plate member 320 is reduced. By confirming, it is possible to confirm the number of balls that have entered the specific winning opening 65a.

  On the other hand, as shown in FIG. 18C, when the light path E3 and the flowing direction of the sphere flowing down the lower passage 331b are close to parallel, after the light path E3 is blocked by the sphere, When the sphere reaches the rear end of the lower passage 331b (left side in FIG. 18C, near the sensor S) and falls downward, light is no longer blocked by the sphere (so that the light reaches the front inclined side surface 332a1f). Become). That is, until then, the light path E3 remains blocked by the sphere.

  In this case, when the balls continue to flow down the lower passage 331b, the light path E3 is blocked by the first sphere (the left sphere in FIG. 18C) as long as the sphere is arranged in the lower passage 331b. Further, after the first ball falls downward from the rear end of the lower passage 331b (left side in FIG. 18 (c)), the light path is changed to the second ball (right side ball in FIG. 18 (c)). E3 is blocked. In addition, when the second ball (the third ball) enters the lower passage 331b when the second ball falls from the rear end of the lower passage 331b, a light path is applied to the lower ball 331b. E3 is blocked. As described above, the sphere continues to block the light path E3, and the sphere is always visually recognized as dark while flowing down the lower passage 331b. That is, the number of times that light is visually recognized or darkly changed does not always match the number of balls entering the specific winning opening 65a, and the number of balls entering the specific winning opening 65a does not always match. Confirmation becomes difficult. On the other hand, the present embodiment has the advantages described above.

  As shown in FIG. 18A, the front inclined side surface 332a1f is formed so as to be depressed toward the rear side toward the center in the left-right direction, so that the light emitted from the pair of left and right light irradiation units 331c1 is irradiated by the front inclined side surface 332a1f. By being reflected, the light is condensed along the path E1 to the center of the front plate member 320, and reaches the light projection range E0 (see FIG. 17B).

  Here, in the present embodiment, since the front plate member 320 is disposed on the front side of the movable upper cover member 332, the specific winning opening 65a can be hidden, while the front inclined side surface 332a1f is visually recognized through the front plate member 320. Therefore, it may be difficult to grasp a change in brightness of the front inclined side surface 332a1f. In that case, it is necessary to increase the intensity of light of a light emitting element such as an LED used for the light irradiation unit 331c1, and there is a problem that light emitting elements that can be used for the light irradiation unit 331c1 are limited.

  On the other hand, the front inclined side surfaces 332a1f converge the light irradiated from the light irradiation unit 331c1 to the center of the front plate member 320, so that the light irradiated from the pair of light irradiation units 331c1 is overlapped, The intensity of light visually recognized in the light projection range E0 can be improved. Therefore, the degree of freedom in selecting a light-emitting element that can be used for the light irradiation section 331c1 can be improved (a light-emitting element with low light intensity can be selected).

  In addition, since the light emitted from the pair of light irradiation units 331c1 is partially overlapped and visible when viewed from the front (see FIG. 17B), the colors of the light are different from each other so that the pair of light irradiation Light of a total of three colors, that is, the color of the light emitted from the unit 331c1 and the color obtained by combining the colors, can be visually recognized in the projection range E0 (see FIG. 17B).

  Here, since the light emitted from each of the pair of light irradiation units 331c1 is shielded by the sphere rolling along the path C2a independently (see FIG. 18), at the timing when the sphere shields the light, The color of light visually recognized in the light projection range E0 can be variously switched.

  For example, in FIG. 18, a case is considered in which “blue” light is emitted from the right light irradiation unit 331c1 and “red” light is emitted from the left light irradiation unit 331c1. In this case, when the movable upper cover member 332 is in the retracted state, the light is emitted from the right side in the order of “blue”, “purple (overlapping portion)”, and “red” in the light emitting range E0 (see FIG. 17B). Is visually recognized.

  In this case, if the sphere rolls on the path C2a on the right side of FIG. 18 to block the light emitted from the light irradiation unit 331c1, the light of “blue” will be blocked. Only the red light is visible.

  On the other hand, when the sphere rolls on the path C2a on the left side of FIG. 18 and blocks the light emitted from the light irradiation unit 331c1, the light of the “red” color is blocked. Only "blue" light is visible.

  As described above, the mode of the light visually recognized in the light projection range E0 can be changed depending on which path the ball rolls and which light from the light irradiation unit 331c1 is blocked. Since the change in the light mode is caused by a ball flowing down the game area along a random path while colliding with a nail or the like, the change in the light mode can be generated at random timing. That is, as compared with a case where the change of the mode of the light irradiated from the light irradiation unit 331c1 is caused by the electronic control, it is possible to perform the effect with more randomness, and it is possible to improve the effect of the effect.

  In the present embodiment, the front inclined side surface 332a1f is formed in a U-shape as viewed from above, but may be formed in a parabolic shape as viewed from above from the viewpoint of condensing light.

  Next, the composite operation unit 400 will be described with reference to FIGS.

  FIG. 19 is a front perspective view of the composite operation unit 400, and FIG. 20 is a rear perspective view of the composite operation unit 400. 19 and 20 illustrate a state in which the main body member 410 of the combined operation unit 400 is disposed at the retracted position, and the drive motor 462 and the fixed plate 461 are not illustrated. In the composite operation unit 400, the guide member 450 and the rear upper plate 470 are fastened and fixed to the bottom wall 211 (see FIG. 6) of the rear case 210.

  FIG. 21 is an exploded front perspective view of the composite operation unit 400, and FIG. 22 is an exploded rear perspective view of the composite operation unit 400. As shown in FIGS. 21 and 22, the composite operation unit 400 has a horizontally-long rectangular main body member 410 which can be slid in the vertical direction, and one end portion of which can be guided at both left and right ends of the main body member 410. A pair of members connected to each other, the other end portions of which are pivotally supported with each other; a swing member 430 disposed so as to be swingable on the center front side of the main body member 410; A pair of leg members 440 which are fastened and fixed at both ends and extend in the vertical direction, a guide member 450 in which a guide hole 452 for guiding the leg member 440 is formed, and a driving force required for moving the leg member 440. A driving device 460 to be generated, a rear upper plate 470 fastened and fixed above the opening 211a of the rear case 210, and a wiring connecting the rear upper plate 470 and the main body member 410 to accommodate wiring therein. Composed mainly comprises a guide arm 480, a.

  FIG. 23 is an exploded front perspective view of the main body member 410, the shielding member 420 and the swing member 430, and FIG. 24 is an exploded rear perspective view of the main body member 410, the shielding member 420 and the swing member 430.

  As shown in FIGS. 23 and 24, the main body member 410 has a plate-like base member 411 formed to be long in the left-right direction, and is provided in both left and right ends of the base member 411 in the front-rear direction, and A long hole-shaped leg insertion hole 412 that is extended, and a direction that is arranged inside the leg insertion hole 412 of the base member 411 in the left-right direction and is drilled in the front-rear direction and rises and leans toward the left-right center axis of the base member 411. And a columnar member extending from the upper end of the base member 411 to the front side, and one end of the wiring guide arm 480 is pivotally supported. An arm shaft support portion 414, a holding portion 415 extending upward from the center in the left-right direction of the base member 411 and having a hook-like tip, and a swing member 430 provided as a pair at a lower end portion of the base member 411. Shaft support hole 431a A supporting portion 416 to be supported, a photosensor 417 disposed in front of the base member 411 to detect the sensor passage portion 435d of the swing member 430, a decorative plate portion 418 formed in a substantially semicircular shape in a front view, Mainly equipped.

  The base member 411 has a shape in which a central portion in the left-right direction hangs downward from both left and right end portions. Thereby, a space can be formed above the center in the left-right direction, and the wiring guide arm 480 can be disposed in the space (see FIG. 29).

  The leg insertion hole 412 is formed in a long hole shape, and the rotation of the leg member 440 with respect to the base member 411 is suppressed by inserting the connection fixing portion 442 (see FIG. 21) of the leg member 440. You. Thereby, the posture of the leg member 440 and the main body member 410 can be stabilized.

  The guide hole 413 is an elongated hole through which the insertion shaft portion 421c of the shielding member 420 is inserted and slid, and has a width slightly larger than the diameter of the insertion shaft portion 421c. Above the guide hole 413, a front cover 413a is provided, which covers the front side of the leg insertion hole 412 and has a side surface facing the guide hole 413 formed along the upper side of the guide hole 413. On the side, a support plate 413b, which is a plate-shaped portion protruding from the front side of the base member 411 and is inclined upward along the guide hole 413, is provided.

  The support plate 413b has an end on the front side in contact with the back surface of the swing base member 421. Thus, the swinging movement of the swing base member 421 is suppressed by the support plate 413b, so that the posture during the movement of the shielding member 420 can be stabilized.

  The arm shaft support portion 414 is disposed on the left side in front view of the center portion of the base member 411. More specifically, the arm shaft support portion 414 is disposed at an intermediate portion between a portion where the upper end portion of the base member 411 starts to drop and a central portion in the left-right direction. Is done. Note that the end (lower end) of the third guide arm 483 (see FIG. 21) of the wiring guide arm 480 is supported by the arm shaft support 414, and a collar member is provided at the tip of the arm shaft support 414. Fastened and fixed.

  The holding portion 415 is a portion that is hooked on a slide lever 473 (see FIG. 21) disposed on the rear upper plate 470. That is, in a state where the main body member 410 is located at the retracted position (see FIG. 29), the upper end of the slide lever 473 and the lower end of the hook-shaped portion of the holding portion 415 are in contact with each other, The downward movement of the main body member 410 is restricted. Note that an inclined surface 415a is formed on the upper surface of the tip portion formed in a hook shape. The inclined surface 415a does not hinder the movement of the main body member 410 even when the main body member 410 is moved to the retracted position with the slide lever 473 extended.

  The decorative plate portion 418 is a decorative portion that is visually recognized in a front view together with the shielding member 420 when the main body member 410 is disposed at the extended position, and in a state where the main body member 410 is disposed at the retracted position (FIG. 29), which is in contact with the lower surface of the contact plate 421d.

  The shielding member 420 includes a swing base member 421 formed in such a manner that ends of a pair of plate members are pivotally supported, and a decorative member whose upper end is fastened and fixed to the front side of the swing base member 421. 422, a pair of connecting members 423 whose one ends are pivotally supported coaxially with the pivot position of the swing base member 421, and a guide on which the other end of the connecting member 423 is pivoted. A guide plate 424 formed with a hole 424b and fastened and fixed to the upper end on the front side of the rear case 210.

  The swing base member 421 is formed of a pair of plate-like members 421 a formed in a substantially arc shape, and is a swing shaft that is coaxially supported by a shaft support hole 423 d formed at one end of the connection member 423. It mainly includes a hole 421b, a pair of left and right insertion shaft portions 421c that are inserted and guided in the guide holes 413 of the main body member 410, and a contact plate 421d that protrudes from the rear side and contacts the upper surface of the main body member 410. .

  The swing shaft hole 421b is a portion that serves as a swing shaft of the pair of plate members 421a, while a shaft support rod 423c inserted through one end of the connection member 423 is penetrated and supported by the connection member 423. It is.

  Since the insertion shaft portion 421c is inserted into the guide hole 413 of the main body member 410, the left and right ends of the shielding member 420 are moved as the main body member 410 is moved downward from the intermediate position (see FIG. 30). It is moved close to the center in the left-right direction.

  The contact plate 421d is a curved surface projecting rearward from the plate-shaped member 421a, and is formed along the shape of the upper surface of the decorative plate portion 418. As a result, the upper surface of the main body member 410 and the lower surface of the contact plate 421d are brought into contact at the retracted position.

  The decorative member 422 includes a pair of thick portions 422 a disposed on the front side of the swing base member 421, and a portion formed below the swing base member 421 in a front view, and a lower end portion. And a hanging portion 422b formed to be curved backward from the swing base member 421.

  The hanging portion 422b is arranged closer to the main body member 410 than the swing base member 421.

  The connecting member 423 is formed of a pair of rod members 423a bent in a U-shape at the bending portion 423b, and includes a pivot rod 423c. One end of the rod member 423a has a pivot rod 423c. A shaft support hole 423d through which is inserted is formed, and a slide shaft portion 423e that is inserted into and guided by the guide hole 424b of the guide plate 424 is formed at the other end of the rod member 423a.

  The bent portion 423b is bent above a straight line connecting the shaft support hole 423d and the slide shaft portion 423e. That is, the bent portion 423b is disposed farther from the swing base member 421 than the straight line connecting the shaft support hole 423d and the slide shaft portion 423e. Therefore, a large space can be secured between the swing base member 421 and the connecting member 423, and the degree of freedom in designing the swing base member 421 can be improved.

  The slide shaft portion 423e is formed from a cylindrical portion inserted into the guide hole 424b, and a disk-shaped collar member fastened and fixed to the tip of the cylindrical portion.

  The guide plate 424 includes a base plate 424a that is fastened and fixed to the rear case 210, and a pair of guide holes 424b that are formed in left and right end portions of the base plate 424a in the front-rear direction and extend in the left-right direction. , Mainly comprising. A pair of guide holes 424b are formed at the same height.

  The guide hole 424b is formed in the left-right direction, that is, the direction along the upper outer edge of the opening 211a of the rear case 210. Therefore, the width required for the guide plate 424 to guide the connecting member 423 can be suppressed. In this case, since the guide plate 424 can be disposed at a position farther from the third symbol display device 81, the shielding member 420 can be formed larger accordingly.

  The oscillating member 430 is a member pivotally supported by the shaft supporting portion 416, and includes a main body member 431 that is oscillated and a base that is provided to protrude toward the front side of the center of the base member 411. A member 432, a drive motor 433 fastened and fixed to the base member 432 to generate a drive force for driving the main body member 431, a drive gear 434 supported by the drive motor 433, and meshed with the drive gear 434. A transmission gear 435 pivotally supported above the base member 432 with respect to the drive gear 434, and a connection member 436 connecting the connection shaft 435c of the transmission gear 435 and the connection shaft 431b of the main body member 431. Prepare for.

  The main body member 431 is a member in which a hemispherical decorative part is formed on the front side. And a connection shaft 431b that is disposed at the center on the side and that is supported at one end of the connection member 436.

  The connection shaft 431b is disposed on the rear side of the main body member 431 at a position closer to the shaft support hole 431a than the end on the opposite side (upper side) of the shaft support hole 431a. Accordingly, the moving width of the upper end of the main body member 431 can be made larger than the moving width in which the connecting member 436 is actually moved back and forth.

  The transmission gear 435 is supported by the base member 432 and extends substantially half way around the main body 435a where a gear meshing with the drive gear 434 is formed, and extends to the opposite side of the gear formed on the main body 435a. Overhang 435b, a cylindrical connecting shaft 435c projecting rightward from the front end of the overhang 435b, and formed along the left front side of the overhang 435b. And a sensor passage portion 435d (see FIG. 34), which is formed in a fan shape when viewed in the left-right direction and whose peripheral portion passes through the photosensor 417.

  The connection member 436 is a rod-shaped member having holes parallel to each other at both ends. The connection member 436 includes a one-side connection hole 436a that is formed at one end and is supported by the connection shaft 431b of the main body member 431. And a second connection hole 436b which is bored at the other end and is supported by the connection shaft 435c of the transmission gear 435.

  Returning to FIG. 21 and FIG. The arm member 440 is formed of a long plate-shaped main body 441 having a pair extending in the vertical direction, and a long hole having a cross section protruding from the upper end of the main body 441 to the front side being long in the vertical direction. A coupling fixing portion 442, a pair of insertion shaft portions 443 protruding rearward from upper and lower ends of the main body 441 and inserted through the guide holes 452 of the guide member 450, and a front side from the lower end of the main body 441. A locking portion 444 that protrudes from the rear case 210 and a locking portion 444 where one end of the biasing spring 445 is locked, and the other end of the biasing spring 445 whose one end is locked to the locking portion 444. And a holding and fixing portion 446 fastened and fixed to the front side.

  The main body portion 441 has a rack gear 441a engraved on a side surface facing the main body member 410, and the rack gear 441a is meshed with the drive gear 463 of the drive device 460. The force is transmitted to the leg member 440.

  The insertion shaft portion 443 is formed in a vertically long hole shape and is inserted into the guide hole 452 of the guide member 450 extending vertically, so that the posture of the leg member 440 with respect to the guide member 450 is stabilized. Can be. Further, since the insertion shaft portion 443 is formed as a pair of upper and lower portions, the posture of the leg member 440 with respect to the guide member 450 can be stabilized.

  The urging spring 445 generates an urging force for moving the leg member 440 toward the retracted position (see FIG. 19). At this time, the other end of the biasing spring 445 functions as a fixed-side end locked by the holding and fixing portion 446, and one end functions as a moving-side end locked by the locking portion 444.

  The guide member 450 includes a main body member 451 which is a vertically long plate member arranged in a pair of left and right, and a long hole formed in the main body member 451 in a pair of upper and lower sides in the front and rear direction and extending in the vertical direction. , A pair of fixing portions 453 for fixing the driving device 460 at the center in the vertical direction of the main body member 451, and the leg member 440 disposed at the front side of the upper end portion of the main body member 451 and the retracted position ( (See FIG. 19) and a cover member 454 disposed on the front side of the leg member 440.

  The driving device 460 has a shape in which the side close to the main body member 410 is lowered one step backward, the side close to the main body member 410 is fixed to the fixing portion 453 of the guide member 450, and the opposite side is the fastening portion 212b ( Mainly includes a fixing plate 461 fixed to the fixing plate 461, a driving motor 462 fastened and fixed to the fixing plate 461, and a driving gear 463 supported by the driving motor 462.

  Since the fixing plate 461 has a shape in which the side away from the main body member 410 is raised by one step toward the front side, a gap surrounded by the rear case 210 and the fixing plate 461 may be formed on the side away from the main body member 410. it can. Here, when the urging springs 445 are arranged on the left and right sides of the leg member 440, the width of the leg members 440 including the urging springs 4454 in the left and right direction is increased, whereby the left and right width of the opening 211a is reduced. I was In the present embodiment, the biasing spring 445 can be provided in a gap (formed on the front side of the leg member 440) surrounded by the rear case 210 and the fixing plate 461, and the left and right sides of the leg member 440 are correspondingly arranged. Space in the direction can be suppressed.

  The rear upper plate 470 is a member fastened and fixed to a bottom wall portion 211 (see FIG. 6) formed above the opening 211a of the rear case 210, and includes a plate-shaped main body portion 471 and the main body portion 471. A column-shaped shaft support portion 472 protruding from the upper left end in front view to the front side, a slide lever 473 elongated in the left-right direction provided in the center of the main body portion 471, and the slide lever 473 is arranged in the left-right direction. And a front cover 475 fastened and fixed to the main body 471 so as to cover the front side of the slide lever 473.

  The shaft support portion 472 is a portion on which the one-side cylindrical portion 481b (see FIG. 25) of the wiring guide arm 480 is supported, and a collar member C is fastened and fixed to the tip. The wiring to be introduced into the main body member 410 is disposed so as to pass through the vicinity of the shaft support 472.

  The slide lever 473 is a member that is in contact with the lower surface of the holding portion 415 of the main body member 410 in a state where the main body member 410 is located at the retracted position (see FIG. 29), and prevents the main body member 410 from moving downward. is there. An inclined surface 473a is formed on the lower surface of the tip of the slide lever 473. The contact between the inclined surface 473a and the inclined surface 415a of the main body member 410 makes it possible to suppress the resistance generated between the contact surfaces.

  The overhang of the slide lever 473 is changed depending on whether or not electricity is conducted to the solenoid 474. For example, when the electricity is conducted, the slide lever 473 projects leftward when viewed from the front. If the electricity is conducted, the slide lever 473 is brought into contact with the lower surface of the holding portion 415, and the body member 410 Is prevented from moving downward (see FIG. 29). On the other hand, when the electricity is not conducted, the slide lever 473 does not contact the holding portion 415, and the main body member 410 can be moved downward.

  Here, it is conceivable that the solenoid 474 is driven as the main body member 410 is disposed at the retracted position, and the slide lever 473 comes into contact with the holding portion 415. However, in this case, the driving force from the driving device 460 cannot be released until the solenoid 474 moves the slide lever 473 after the main body member 410 is disposed at the retracted position. Therefore, when changing the operation of the driving device 460 by detecting the arrangement of the main body member 410, it is necessary to control the driving device 460 in consideration of the time for the solenoid 474 to move the slide lever 473, which is difficult to control. It becomes.

  On the other hand, in the present embodiment, the inclined surface 415a of the holding portion 415 is arranged to face the inclined surface 473a of the slide lever 473 by moving the main body member 410 upward with the slide lever 473 extended (FIG. 31). ), And the slide lever 473 is pushed back. When the main body member 410 is located at the retracted position and the contact between the holding portion 415 and the slide lever 473 in the longitudinal direction of the slide lever 473 is released, the slide lever 473 projects again and the lower surface of the holding portion 415 and the slide lever The upper surface of the 473 is in contact with the upper surface (see FIG. 29). Accordingly, regardless of the arrangement of the main body member 410, by keeping the slide lever in the extended state, the downward movement after the main body member 410 is moved to the retracted position can be prevented. Therefore, control of the driving device 460 becomes easy.

  The front cover 475 is a member in which a slide groove 475a, which is a concave groove for guiding the slide lever 473, is formed along the left and right direction on the back surface. The slide lever 473 is slid by the slide groove 475a of the front cover 475. The displacement in the vertical direction during the movement is suppressed.

  The wiring guide arm 480 is a movable mechanism that is formed of a resin material and guides the wiring W from the rear upper plate 470 fastened and fixed to the rear case 210 to the main body member 410. A first guide arm 481 in which one side cylindrical portion 481b to be formed is pivotally supported by the shaft support portion 472, and a second guide arm 482 in which the other end of the first guide arm 481 is pivotally supported at one end. And a third guide arm 483 that pivotally supports the other end of the second guide arm 482 at one end and the other end is pivotally supported by the arm shaft support 414.

  Here, the wiring W is an electric wiring (for example, a flat harness) formed in a belt shape (widely formed in the direction perpendicular to the paper surface of FIG. 27). The length of the second guide arm 482 in the longitudinal direction is shorter than the diameter of the collar member C than the first guide arm 481, and the length of the third guide arm 483 is longer than that of the second guide arm 482. Is shorter than the diameter of the collar member C.

  The wiring guide arm 480 is configured to be able to accommodate the wiring W therein, and is a member that prevents the wiring W from being broken and disconnected. Accordingly, it is not necessary to arrange the wiring W introduced into the main body member 410 through the leg members 440, and it is possible to suppress a space for disposing the leg members 440. Therefore, the opening 211a can be enlarged in the left-right direction.

  Next, the first guide arm 481 and the second guide arm 482 will be described with reference to FIGS. Note that the third guide arm 483 is configured as a technical idea including the ones described for the first guide arm 481 and the second guide arm 482, and thus the description thereof is omitted here.

  FIG. 25 (a) is a front view of the first guide arm 481, FIG. 25 (b) is a bottom view of the first guide arm 481, and FIG. 25 (c) is XXVc of FIG. 25 (a). It is sectional drawing of the 1st guide arm 481 in the -XXVc line, and FIG.25 (d) is sectional drawing of the 1st guide arm 481 in the XXVd-XXVd line of FIG.25 (a).

  As shown in FIGS. 25A to 25D, the first guide arm 481 includes a plate-shaped arm portion 481a formed in a long plate shape, and a left end of the plate-shaped arm portion 481a when viewed from the front. The axis is disposed on the vertical line of the lower bottom surface (the lower side surface in FIG. 25A) of the plate-shaped arm portion 481a, and the one-side cylindrical portion 481b extending in the front-rear direction, and the plate-shaped arm portion At the end opposite to the one-side tubular portion 481b among the ends of the one-side tubular portion 481a, an axis is arranged on a vertical line on the lower bottom surface of the plate-shaped arm portion 481a and the other-side tubular portion extending in the front-rear direction. 481c, an attachment portion 481d formed in a plate shape at a predetermined interval above the plate-shaped arm portion 481a, a bottom portion 481e connecting the plate-shaped arm portion 481a and the attachment portion 481d on the back side, and an attachment portion 481d. Front locking portion 481 extending from the front side surface to plate-shaped arm portion 481a And, mainly includes the.

  The wiring W is inserted through the inside of the concave cross-section formed by the plate-shaped arm portion 481a, the attachment portion 481d, and the bottom portion 481e (see FIG. 27). Accordingly, it is possible to suppress the wiring W from being rubbed with other members or being sandwiched by other members.

  The plate-shaped arm portion 481a has a cutout portion 481a1 formed at a portion facing the front locking portion 481f, and the plate-shaped arm portion 481a has a reduced thickness at the portion where the cutout portion 481a1 is formed. .

  The cutout portion 481a1 is a recess formed in the plate-shaped arm portion 481a in a shape slightly larger than the front locking portion 481f in a front view, and is formed across the width of the plate-shaped arm portion 481a. Note that the formation of the bottom portion 481e is omitted in the portion where the notch portion 481a1 is formed (the bottom portion 481e is formed to penetrate).

  By configuring the notch portion 481a1 as described above, the first guide arm 481 can be easily manufactured by die molding (by one-way die cutting). Further, by inserting the wiring W from the notch 481a1, the wiring W can be easily accommodated in the first guide arm 481.

  The portion of the plate-like arm portion 481a other than the portion where the notch portion 481a1 is formed has a shorter interval with the attachment portion 481d than the overhang width of the front locking portion 481f. Therefore, in a state where the wiring W is accommodated in the first guide arm 481 and is extended in the longitudinal direction (see FIG. 27A), it is possible to prevent the wiring W from dropping to the front side (FIG. 27A). Can be prevented.

  The plate-shaped arm portion 481a includes a rib portion N formed in a rib shape in the width direction on a side surface facing the attachment portion 481d. The rib portion N is formed in the vicinity of the other cylindrical portion 481c that is pivotally supported by the second guide arm 482, and a rib protruding from the second guide arm 482 at an intermediate portion of the plate-like arm portion 481a. The portions N are formed alternately.

  The other-side cylindrical portion 481c includes an enlarged-diameter portion 481c1 whose inner diameter is partially increased. In order to form an overlap margin with the second guide arm, the rear-side end surface is closer to the front than the bottom portion 481e. It is formed (see FIG. 25B).

  The enlarged diameter portion 481c1 is formed over a half circumference (upper half circumference in FIG. 25 (a)) on the inner peripheral side of the other cylindrical portion 481c, and is formed from the other bottom portion 481e2 of the other cylindrical portion 481c. The depression is formed to a length that is approximately half the length of the cylinder of the side cylindrical portion 481c (see FIG. 25C).

  The attachment portion 481d includes an arc-shaped attachment portion 481d1 formed as an arc coaxial with the other-side tubular portion 481c around the other-side tubular portion 481c, and is extended forward from the plate-shaped arm portion 481a. . Thereby, even when the flat locking portion 481f is formed, a gap for inserting the wiring from the front side can be secured.

  The attachment portion 481d includes a rib portion N formed in a rib shape in the width direction on a side surface facing the plate-shaped arm portion 481a. The rib portion N is formed at an intermediate position between the rib portions N projecting from the plate-shaped arm portion 481a at an intermediate portion of the attachment portion 481d.

  The arcuate attachment portion 481d1 is formed with a radius larger than the radius of the substantially arcuate shape formed when the wiring W is bent outward (upper right in FIG. 27B) of the other cylindrical portion 481c. You.

  Further, since the wiring guide arm 480 is formed at the upper end inside the rear case 210 (see FIG. 7), when replacing or performing maintenance of the wiring W, the wiring is attached along a route not blocked by the rear case 210. Need to be removed. In the present embodiment, the attachment portion 481d close to the upper wall surface of the rear case 210 is formed so as to protrude forward from the plate-shaped arm portion 481a separated from the upper wall surface of the rear case 210. Therefore, for example, when removing the wiring W, the wiring W may be pulled out to the front side and pulled out in the direction from the attachment portion 481d toward the plate-shaped arm portion 481a. It will not be. The wiring may be inserted in the opposite direction. Therefore, the maintainability of the replacement of the wiring W can be improved.

  The bottom portion 481e is disposed above the one-side cylindrical portion 481b and formed in a fan shape around the axis of the one-side cylindrical portion, and is disposed above the other-side cylindrical portion 481c. And a bottom portion 481e2 formed in a fan shape centered on an axis spaced apart from the axis of the side cylindrical portion 481c by a predetermined distance. Note that the end of the arcuate attachment portion 481d1 is formed to the left in front view than the end of the other-side bottom portion 481e2.

  The planar locking portion 481f is a claw-shaped member that prevents the wiring W from falling off from the front side. That is, the wiring W is formed with a width shorter than the length from the bottom portion 481e to the front locking portion 481f.

  26 (a) is a front view of the second guide arm 482, FIG. 26 (b) is a bottom view of the second guide arm 482, and FIG. 26 (c) is XXVIc of FIG. 26 (a). FIG. 26D is a cross-sectional view of the second guide arm 482 taken along line XXVIc, and FIG. 26D is a cross-sectional view of the second guide arm 482 taken along line XXVId-XXVId in FIG.

  As shown in FIGS. 26 (a) to 26 (d), the second guide arm 482 has a plurality of configurations having the same technical concept as the first guide arm 481, and the description of the configuration is omitted. I do. That is, the plate-like arm portion 481a is on the plate-like arm portion 482a, the other-side tubular portion 481c is on the other-side tubular portion 482c, the attachment portion 481d is on the attachment portion 482d, the bottom portion 481e is on the bottom portion 482e, and the front locking portion. 481f respectively correspond to the front locking portions 482f.

  The plate-shaped arm portion 482a includes a cutout portion 482a2 at a portion facing the front locking portion 482f. The technical idea of the notch 482a2 is the same as the technical idea of the notch 481a1, and a description thereof will be omitted.

  The plate-shaped arm portion 482a and the attachment portion 482d include a rib portion N on the side surface facing each other. A rib portion N is formed in the attachment portion 482d in the vicinity of one side pivot portion 482b that is pivotally supported by the first guide arm 481. In the middle portion of the second guide arm 482, the rib portion N is formed by the plate-shaped arm portion 482a. And the attachment portion 482d.

  The second guide arm 482 has a one-side support 482b, which is formed in a columnar shape from the upper right portion of the bottom portion 482e to the front side and has a fastening portion formed at the end thereof, and the one-side support 482b as an axis. One bottom 482e1 formed in a substantially circular arc shape and extending on the same plane from the bottom 482e, and the right end of the plate-like arm 482a protruding from the vicinity of the outer periphery of the one bottom 482e1 to the front side. And an arc-shaped plate portion 482a1 connected to the main body.

  The arc-shaped plate portion 482a1 is formed with a radius larger than the radius of the substantially arc-shaped shape formed when the wiring W is bent outward (upper right in FIG. 27B) of the other cylindrical portion 481c. You.

  The one-side shaft support portion 482b is a portion where the reduced diameter portion 482b1 is formed and the other side cylindrical portion 481c of the first guide arm 481 is inserted, and the front side surface of the one side bottom portion 482e1 is the other side cylindrical portion. It is formed so as to be able to contact the rear side surface of the shape portion 481c. Therefore, in the assembled state (see FIG. 27), the bottom portions 481e and 482e are formed on the same plane, and the bottom portions 481e and 482e can contact each other in the respective rotation directions of the first guide arm 481 and the second guide arm 482. It is formed. Therefore, excessive rotation of the first guide arm 481 and the second guide arm 482 can be prevented, and the wiring W can be prevented from being excessively bent (see FIG. 27).

  The reduced-diameter portion 482b1 is formed over a half circumference (a lower half circumference in FIG. 26A) on the outer peripheral side of the one-side shaft support portion 482b, and the one-side shaft support portion 482b has one side shaft from the one bottom portion 482e1 side. The depression is formed to a length approximately half the length of the support portion 482b (see FIG. 26C).

  Next, the swing of the second guide arm 482 with respect to the first guide arm 481 will be described with reference to FIG. FIGS. 27A and 27B are front views of the first guide arm 481, the second guide arm 482, and the wiring W. FIG. 27A illustrates a state in which the second guide arm 482 is folded with respect to the first guide arm 481 (corresponding to the state in FIG. 29), and FIG. The state where the second guide arm 482 is swung counterclockwise from the state of a) to the end of the movable range in which the second guide arm 482 can swing with respect to the first guide arm 481 (corresponding to the state of FIG. 33). Illustrated. In FIG. 27 (b), one side bottom portion 482e1 of the second guide arm 482 and the other side bottom portion 481e2 of the first guide arm 481 are in contact with each other, thereby preventing the second guide arm 482 from further swinging. Is done.

  As shown in FIG. 27 (a), the wiring W is formed by a concave portion (FIG. 25 (d) and FIG. 26 (d) formed by the plate-shaped arm portions 481a and 482a, the attachment portions 481d and 482d, and the bottom portions 481e and 482e. ) See). Therefore, due to the rigidity of the first guide arm 481 or the second guide arm 482, it is possible to prevent the wiring W from being bent to such a degree that the wiring W is disconnected during the movement of the main body member 410.

  In addition, at the pivotal support positions of the first guide arm 481 and the second guide arm 482 (the right end in FIG. 27A), the wiring W is disposed so as to wrap around the other-side cylindrical portion 481c. Therefore, at the pivotal support positions of the first guide arm 481 and the second guide arm 482, the wiring W is suppressed from being bent with a radius of curvature equal to or smaller than the diameter of the other cylindrical portion 481c. Therefore, it is possible to prevent the wiring W from being bent, and it is possible to suppress disconnection of the wiring W.

  The state of FIG. 27A corresponds to the state illustrated in FIG. 29, that is, the state where the main body member 410 is located at the retracted position. As for the speed at which the main body member 410 is moved from the retreat position to the overhang position, the higher the speed, the easier it is to improve the effect. When starting the main body member 410 from a state where the main body member 410 is stopped at the retracted position, it is necessary that the driving device 460 generate a driving force that exceeds the inertial force of the main body member 410 and the inertial force of the wiring guide arm 480. Therefore, in the state of FIG. 27A, it is desirable that the rotation resistance of the first guide arm 481 and the second guide arm 482 constituting the wiring guide arm 480 at the pivotal support position be small.

  In the present embodiment, as shown in FIG. 27A, in a state where the second guide arm 482 is folded with respect to the first guide arm 481, the enlarged diameter portion 481c1 and the enlarged diameter portion 481c1 around the axis of the one cylindrical portion 481b. The reduced diameter portion 482b1 surrounds. The enlarged diameter portion 481c1 and the reduced diameter portion 482b1 are portions that are depressed in a direction away from a counterpart member forming a pivotal relationship, and have an effect of suppressing rotational friction during rotation of the shaft. In a state in which the second guide arm 482 is folded with respect to the first guide arm 481, the enlarged diameter portion 481c1 and the reduced diameter portion 482b1 are formed around the entire circumference of the one cylindrical portion 481b. Therefore, resistance when rotating the second guide arm 482 with respect to the first guide arm 481 is suppressed.

  On the other hand, in the state of FIG. 27B, the range in which the enlarged-diameter portion 481c1 and the reduced-diameter portion 482b1 are arranged around the axis of the one-side cylindrical portion 481b is substantially half a circumference (FIG. 27B: upper half circumference). ). As shown in FIG. 27B, the large-diameter portion 481c1 and the small-diameter portion 482b1 mostly overlap. In this case, the rotational resistance of the first guide arm 481 and the second guide arm 482 can be increased as compared with the state shown in FIG.

  From the state in which the second guide arm 482 is folded with respect to the first guide arm 481, the larger the diameter-increasing portion 481c1 and the diameter-reducing portion 482b1 overlap as the second guide arm 482 is rotated with respect to the first guide arm 481. And the rotational resistance of the first guide arm 481 and the second guide arm 482 increases. That is, as the second guide arm 482 is rotated with respect to the first guide arm 481, the speed of the second guide arm 482 can be reduced.

  Therefore, the speed at which the other side bottom portion 481e2 and one side bottom portion 482e1 come into contact with each other can be reduced, and the first guide arm 481 and the second guide arm 482 make the other side bottom portion 481e2 and the one side bottom portion 482e1 come into contact with each other. The load received by contact can be suppressed. As a result, the durability of the first guide arm 481 and the second guide arm 482 can be improved, and the first guide arm 481 and the second guide arm 482 are urged to the opposite sides (the second guide arm 482 is It can be prevented from bending toward the side further rotated counterclockwise from the state (b).

  In the present embodiment, since the wiring guide arm 480 is formed by three members being pivotally supported, the moving speed of the wiring guide arm 480 is variable even when the moving speed of the main body member 410 is constant. can do.

  For example, in a state where the main body member 410 is disposed at the extended position (see FIG. 33), the posture of the wiring guide arm 480 is not limited to one way, and the third guide arm 483 can rotate upward (posture). Changeable) is changeable. Therefore, the movement speed of the first guide arm 481 can be adjusted by changing the posture of the third guide arm 483 even while the main body member 410 is moving. Therefore, even if the moving speed of the wiring guide arm 480 is changed during the movement of the main body member 410, it is not necessary to change the moving speed of the main body member 410 accordingly.

  As shown in FIG. 27B, when the other-side bottom portion 481e2 and the one-side bottom portion 482e1 come into contact with each other, a gap is formed between the arc-shaped attachment portion 481d1 and the arc-shaped plate portion 482a1. Even if the wiring W is bent to the outside of the other cylindrical portion 481c (upper right in FIG. 27B) due to this gap, the wiring W is sandwiched between the arc-shaped attachment portion 481d1 and the arc-shaped plate portion 482a1. Can be prevented, and disconnection of the wiring W can be prevented.

  As shown in FIG. 27B, when the wiring guide arm 480 is in the open state, the wiring W largely moves to the outside of the other cylindrical portion 481c, and particularly, the first guide arm 481 and the second guide The wiring W is likely to be displaced near the end of the arm 482 (supporting position). When the wiring W is repeatedly displaced with respect to the first guide arm 481 and the second guide arm 482, the wiring W rubs against the inner surfaces of the first guide arm 481 and the second guide arm 482, and the durability of the wiring W is increased. There is a possibility that the property is reduced.

  On the other hand, in the present embodiment, the wiring W and the first guide arm 481 and the rib W formed on the inner surface of the first guide arm 481 and the second guide arm 482 are hooked on the wiring W. The resistance with the second guide arm 482 can be improved, and the displacement of the wiring W can be suppressed.

  In the vicinity of the pivotal support positions of the first guide arm 481 and the second guide arm 482, the wiring W is effective by forming the rib portion N on the side surface opposite to the direction in which the wiring W separates from the other cylindrical portion 481c. Can be supported. That is, for example, the portion of the wiring W extending from the connecting position of the arc-shaped attachment portions 481d1 to the attachment portion 481d is pressed against the plate-shaped arm portion 481a along the shape of the arc-shaped attachment portion 481d1. . Therefore, by forming the rib portion N at the pressed portion, the resistance between the wiring W and the plate-shaped arm portion 481a can be increased.

  In addition, the side surface of the portion near the pivotal support position of the plate-shaped arm portion 481a against which the wiring W is pressed is curved and depressed to the opposite side of the attachment portion 481d, so that the wiring W is fitted into the depression. The displacement between W and the plate-shaped arm portion 481a can be suppressed. In this case, since the surface of the curved dent and the wiring W come into surface contact with each other, the local wear of the wiring W is suppressed as compared with the case where the wiring W receives resistance at the point contact from the rib portion N. Can be.

  Further, the distance between the plate-shaped arm portion 481a and the attachment portion 481d may be increased near the pivotal support position. For example, the attachment portion 481d may be inclined in such a manner as to move away from the plate-shaped arm portion 481a as the front engagement portion 481f on the right side in FIG. 27B approaches the other cylindrical portion 481c. In this case, the slack of the wiring W in the vicinity of the support portion is obtained by bending the wiring W by a portion where the distance between the attachment portion 481d and the plate-shaped arm portion 481a is widened (a portion near the other cylindrical portion 481c). The wiring W can be absorbed, and the displacement of the wiring W at the intermediate portion of the first guide arm 481 (the portion sandwiched between the front locking portions 481f) can be suppressed (the wiring W cancels the slack near the supporting portion). Therefore, displacement of the first guide arm 481 in the longitudinal direction can be suppressed). Therefore, it is possible to prevent the wiring W from rubbing against the inner side surface of the first guide arm 481 and to be worn, thereby improving the durability of the wiring W.

  In an intermediate portion between the first guide arm 481 and the second guide arm 482, the rib portions N are alternately formed on the inner side surfaces opposed to each other. Therefore, compared to the case where the rib portion N is formed only on one of the inner surfaces facing each other, the wiring W can be more easily hooked on more rib portions N. Thereby, the resistance between the wiring W and the first guide arm 481 and the second guide arm 482 can be increased, and the displacement between the wiring W and the first guide arm 481 and the second guide arm 482 is suppressed. can do.

  In FIG. 27, a disk-shaped collar member C fastened and fixed to the front side of the wiring guide arm 480 is illustrated by imaginary lines. The collar member C is fastened and fixed to, for example, the tip of the one-side shaft support 482b or the tip of the shaft support 472 (see FIG. 21) inserted into the one-side cylindrical portion 481b, and the front of each of the cylindrical portions 481b, 481c. It is a member that prevents movement to the side.

  In this embodiment, the collar member C extends to a position where at least a part thereof overlaps with the adjacent attachment portions 481d and 482d in a front view, or does not overlap with the attachment members 481d and 482d in a front view. 482d to a position where the wiring W does not fall off. For example, at the left end of FIG. 27B, a gap is formed between the collar member C and the attachment portion 481d, but the wiring W is separated from the one-side tubular portion 481b (the portion where the wiring W is deformed outward). Therefore, there is little possibility that the wiring W falls off from the gap. That is, since the collar member C is extended so as to overlap with the wiring W when viewed from the front (FIG. 27), it has a diameter sufficient to prevent the wiring W from falling off. This prevents the wiring W from dropping from the wiring guide arm 480.

  Here, assuming that the first guide arm 481 and the second guide arm 482 are formed to have the same length, the collar member C abuts when the first guide arm 481 and the second guide arm 482 are folded, It cannot be folded. On the other hand, in the present embodiment, the first guide arm 481 and the second guide arm 482 have different longitudinal lengths. That is, in a state where the first guide arm 481 and the second guide arm 482 are folded until their extending directions are parallel to each other (see FIG. 27A), the first guide arm 481 and the second guide arm 482 are arranged on the front side of the one-side cylindrical portion 481b. The collar member C provided is different from the collar member C provided on the front side of the other cylindrical portion 482c to such an extent that the collar member C does not interfere with the other.

  Thus, by disposing the collar member C, it is possible to suppress the wiring W from falling off from the wiring guide arm 480, and to suppress the arrangement space by folding the wiring guide arm 480. It is desirable that the lengths of the first guide arm 481 and the second guide arm 482 in the longitudinal direction (the length up to the axis of the collar member C) be different from the diameter of the collar member C or more.

  Next, the operation of the composite operation unit 400 will be described. First, with reference to FIGS. 28 to 33, a change in the posture of the shielding member 420 with respect to the sliding movement of the main body member 410 will be described.

  28 is a front view of the combined operation unit 400, FIG. 29 is a rear view of the combined operation unit 400, FIG. 30 is a front view of the combined operation unit 400, and FIG. 32 is a front view of the composite operation unit 400, and FIG. 33 is a rear view of the composite operation unit 400.

  28 and 29 illustrate a state in which the main body member 410 is disposed at the retracted position. In FIGS. 30 and 31, the posture of the swing base member 421 with respect to the main body member 410 from the state illustrated in FIGS. 28 and 29. The state where the main body member 410 is arranged at an intermediate position where the slide shaft portion 423e of the connecting member 423 is arranged at the inner end of the guide hole 424b with the state shown in FIG. The state where the member 410 is arranged at the overhang position is illustrated.

  Also, in FIG. 28, the main body member 431 of the swing member 430 is illustrated by an imaginary line, and in FIGS. 28, 30 and 32, a part of the main body member 410 is illustrated by a hidden line, and the overlapping portion P is indicated by an imaginary line. 29, 31 and 33, the rear upper plate 470 is shown by imaginary lines.

  Further, in FIG. 30, the vicinity of the connection member 423 is enlarged and the state in which the connection member 423 has moved by a predetermined amount from the center-side ends of the pair of guide holes 424b in the enlarged view is illustrated by imaginary lines. Is done. In FIG. 31, the vicinity of the guide hole 413 is enlarged and the state in which the insertion shaft 421c is moved by a predetermined amount from the lower end of the guide hole 413 in the enlarged view is illustrated by imaginary lines.

  When the drive gear 463 is rotated, the main body member 410 is vertically moved along the guide hole 452 with the movement of the leg member 440 meshed with the drive gear 463.

  As shown in FIGS. 28 and 29, the contact plate 421 d of the swing base member 421 of the shielding member 420 is supported by the decorative plate portion 418 of the base member 411 when the main body member 410 is located at the retracted position. Thus, the central portion in the left-right direction of the swing base member 421 is supported. In this state, the slide shaft portion 423e of the connecting member 423 is disposed at a laterally outer end of the guide hole 424b of the guide plate 424, and the insertion shaft portion 421c of the shielding member 420 is located at the lower end of the guide hole 413 of the main body member 410. And the wiring guide arm 480 is folded so that the extending directions of the respective guide arms are parallel to each other. Further, since the upper side surface of the slide lever 473 and the lower side surface of the holding portion 415 are in contact with each other, the downward movement of the main body member 410 is prevented.

  As shown in FIG. 28, at least a part of the mechanical portion such as the transmission gear 435 of the swinging member 430 is provided with a gap formed between the pair of decorative members 422 of the shielding member 420 (formed at the center in the left-right direction and downward). It is arranged in a gap that becomes wider as it goes (see FIGS. 28 and 34). Thus, in a state where the main body member 410 is disposed at the retracted position, the swing member 430 can be arranged vertically in the shielding member 420, and the width of the shielding member 420 and the swing member 430 in the vertical direction can be reduced. Can be suppressed. In this case, the area in front view formed by the main body member 410, the shielding member 420, and the swing member 430 can be reduced, so that the opening 211a (see FIG. 6) can be made larger.

  Here, for example, a mechanical part such as the transmission gear 435 of the swing member 430 may be provided on the front side of the main body member 410 in some cases. In this case, in order to increase the area of the overlapped portion P between the main body member 410 and the decoration member 422 (to move the main body member 410 and the decoration member 422 in the moving direction of the main body member 410), the decoration member 422 is moved by the mechanical part. It is conceivable to arrange them on the front side. On the other hand, in this case, since it is necessary to move the swing member 430 that accommodates the decorative member 422 to the front side (the direction away from the main body member 410), the space on the front side of the swing member 430 is suppressed, and It is difficult to form the swing member 430 three-dimensionally on the front side.

  On the other hand, according to the present embodiment, it is possible to accommodate at least a part (mechanical part such as the transmission gear 435) of the swing member 430 in a space generated by the pair of decorative members 422 being separated from each other. it can. Accordingly, for example, it is not necessary to move the decoration member 422 to the front side of the mechanical part of the oscillating member 430 in order to increase the area of the overlapping portion P between the main body member 410 and the decoration member 422. 430 can be located proximate to body member 410. Thus, the swing member 430 can be formed three-dimensionally on the front side.

  In FIG. 28, since the swing member 430 takes a posture in which the main body member 431 is tilted (see FIG. 34), the vertical width in a front view is suppressed as compared with the standing posture (see FIGS. 32 and 35). You. Therefore, even when the swing member 430 is viewed alone, the area of the swing member 430 formed in a front view can be suppressed.

  As shown in FIGS. 30 and 31, the contact plate 421 d of the swing base member 421 of the shielding member 420 is supported by the decorative plate portion 418 of the base member 411 in a state where the main body member 410 is disposed at the intermediate position. Thus, the central portion in the left-right direction of the swing base member 421 is supported (that is, the shielding member 420 has the same posture as the posture in FIGS. 28 and 29). In this state, the slide shaft 423e of the connecting member 423 is disposed at the left and right inner end of the guide hole 424b of the guide plate 424, and the insertion shaft 421c of the shielding member 420 is located at the lower end of the guide hole 413 of the main body member 410. Placed in The wiring guide arm 480 has a third guide arm 483 mounted on the upper side surface of the main body member 410, and the first guide arm 481 and the second guide arm 482 each take a posture inclined with respect to the left-right direction.

  Since the third guide arm 483 is formed shorter than the other guide arms 481 and 482, the state in which the third guide arm 483 is stably mounted on the upper side surface of the main body member 410 is referred to as the main body member. It can be maintained longer during the movement of 410. This makes it possible to further stabilize the wiring W provided inside the wiring guide arm 480 and prevent the wiring W from being disconnected.

  Here, when the main body member 410 is moved downward at a high speed and is located at the intermediate position, the slide shaft portion 423e of the connecting member 423 rebounds at the inner end of the guide hole 424b, and the swing base of the shielding member 420. The pivot position (the pivot rod 423c, see FIG. 23) of the member 421 and the connecting member 423 may jump upward, and the posture of the shielding member 420 may not be stabilized. On the other hand, in the present embodiment, the guide hole 413 for guiding the insertion shaft portion 421c of the swing base member 421 is formed to be inclined upward and inward in the left-right direction, and the guide for guiding the slide shaft portion 423e. A hole 424b is formed in the left-right direction.

  In other words, when the slide shaft part 423e reaches the inner end of the guide hole 424b, the insertion shaft part 421c is a component perpendicular to the direction in which the pivotal support position of the swing base member 421 and the connecting member 423 rebounds. Is guided so as to be movable in the direction having

  Therefore, a resistance F is applied downward from the upper side surface of the guide hole 413 to the insertion shaft portion 421c that is moved upward with the upward movement of the swing base member 421, and the upper portion of the insertion shaft portion 421c. Movement to is suppressed. In this case, the swing base member 421 is prevented from jumping upward, and the slide shaft portion 423e of the connecting member 423 is prevented from jumping back at the inner end of the guide hole 424b. In addition, even if the swing base member 421 jumps upward and the connecting member 423 jumps upward, the movement of the connecting member is suppressed because the slide shaft portion 423e is in contact with the upper and lower side surfaces of the guide hole 424b. Is done.

  Further, in the present embodiment, even if the bent portion 423b is formed in the connecting member 423, and the slide shaft portion 423e of the connecting member 423 rebounds at the inner end of the guide hole 424b, the bent portion 423b is still in the swing base member 421. (The bent portion 213b moves a distance X toward the center in the left-right direction). Therefore, when the slide shaft portion 423e of the connecting member 423 rebounds at the inner end in the left-right direction of the guide hole 424b, a sufficient interval can be formed between the connecting member 423 and the swing base member 421, and Collision with the swing base member 421 can be prevented. Thus, the degree of freedom in designing the swing base member 421 can be improved.

  In a state where the main body member 410 is disposed at the intermediate position, the connecting member 423 connected to the swing base member 421 suppresses the movement of the swing base member 421 in the left-right direction. That is, for example, when the swing base member 421 starts to move leftward in front view due to disturbance, the connecting member 423 inserted into the guide hole 424b on the right side in front view is located at the center in the left-right direction of the pair of guide holes 424b. The movement is stopped by the end, and the movement of the swing base member 421 in the left-right direction is suppressed. Therefore, the arrangement of the swing base member 421 can be stabilized.

  As shown in FIGS. 32 and 33, the swing base member 421 of the shielding member 420 is suspended and supported by the connecting member 423 in a state where the main body member 410 is disposed at the extended position. In this state, the slide shaft portion 423 e of the connecting member 423 is disposed at the left and right inner end of the guide hole 424 b of the guide plate 424, and the insertion shaft portion 421 c of the shielding member 420 is located at the upper end of the guide hole 413 of the main body member 410. Placed in In addition, the wiring guide arm 480 is in a posture in which the other bottom portion 481e2 of the first guide arm 481 (see FIG. 25) and the one bottom portion 482e1 of the second guide arm 482 (see FIG. 26) abut in the swing direction. Take.

  Here, when the main body member 410 moves from the intermediate position to the overhang position, the pair of left and right insertion shaft portions 421 c move upward along the guide holes 413 in the left and right directions along with the movement. That is, the forces applied to the pair of swing base members 421 from the pair of left and right guide holes 413 of the main body member 410 are directed in opposite directions to the left and right, and cancel each other. Therefore, the displacement of the pivot shaft hole 421b (see FIG. 33) formed on the central axis of the pair of pivot base members 421 in the left-right direction is suppressed, and the displacement of the shielding member 420 in the left-right direction is suppressed. Is suppressed.

  As shown in FIG. 33, in a state where the main body member 410 is located at the extended position, the pair of swing base members 421 and the pair of decorative members 422 of the shielding member 420 are in contact with each other. Thereby, for example, even if one of the swing base members 421 moves faster than the other swing base member 421 and the pair of swing base members 421 are displaced from each other (vertical displacement), the other swing base member 421 is shifted. The contact with the swing base member 421 can suppress the displacement. Thereby, the posture of the shielding member 420 at the extended position can be stabilized.

  The change in the area of the overlapping portion P will be described. The overlapping portion P means a portion where the main body member 410 and the shielding member 420 overlap in a front view. As shown in FIGS. 28 and 30, most of the main body member 410 corresponds to the overlapping portion P from the state where the main body member 410 is arranged at the retracted position to the state where the main body member 410 is arranged at the intermediate position. On the other hand, as shown in FIG. 32, in a state where the main body member 410 is disposed at the overhang position, the shielding member 420 is moved above the main body member 410, particularly in the central portion in the left-right direction, and the area of the overlapping portion P is increased. Is reduced. That is, the main body member 410 and the shielding member 420 are separately visible.

  Thereby, compared with the case where the main body member 410 is arranged at the retracted position, the area in the front view of the main body member 410 and the shielding member 420 is larger when the main body member 410 is arranged at the extended position. In particular, the width in the vertical direction at the center in the horizontal direction is increased. In this case, in the central portion of the third symbol display device 81 (see FIG. 2) that easily attracts the player's attention, the area change in the front view of the area formed by the main body member 410 and the shielding member 420 can be increased. The effect can be improved.

  In the present embodiment, the above-described change in the area of the overlapping portion P occurs after the main body member 410 and the shielding member 420 start to protrude to the front of the third symbol display device 81 (see FIG. 2). Thus, the effect can be performed as if the main body member 410 and the shielding member 420 expand, and the effect of the effect can be improved.

  Next, the operation of the swing member 430 of the combined operation unit 400 will be described with reference to FIGS. FIG. 34 is a partial cross-sectional view of the composite operation unit 400 along the line XXXIV-XXXIV in FIG. 28, and FIG. 35 is a partial cross-sectional view of the composite operation unit 400 along the line XXXV-XXXV in FIG. In FIG. 34, the state in which the main body member 431 of the swing member 430 is tilted is illustrated by a solid line, and the hanging portion 422b of the decorative member 422 is accommodated between the main body member 431 and the main body member 410 of the swing member 430. The illustrated state is shown. In FIG. 35, the state in which the main body member 431 of the swing member 430 is upright is illustrated by a solid line, and the state in which the swing member 430 is tilted is illustrated by an imaginary line for reference, and is arranged in an extended state. The moving member 540 of the swing operation unit 500 is shown in phantom lines.

  As shown in FIGS. 34 and 35, the drive gear 434 is rotated by the drive motor 433 (see FIG. 23), and the transmission gear 435 is rotated accordingly. When the connecting member 436 pivotally supported by the shaft 435c moves in the front-rear direction, the main body member 431 pivotally supported by the coupling member 436 swings about the shaft supporting portion 416 (see FIG. 23). In this case, the main body member 431 is moved in a direction approaching and separating from the decoration member 422b. The swing member 430 can be switched between an inclined state shown in FIG. 34 and an upright state shown in FIG. 35 at an arbitrary position, and can change its posture as long as it does not interfere with the shielding member 420.

  Since the shaft support 416 (see FIG. 23) is connected to the lower end of the oscillating member 430, when the oscillating member 430 is in a tilted state (see FIG. 34), the upper end side that is disposed to face the shielding member 420. The distance D between the main body member 410 and the main body member 410 can be made large. On the other hand, the movement width of the lower end portion of the oscillating member 430 on the opposite side of the shielding member 420 can be reduced, and the oscillating member 430 can slide compared to the case where the oscillating member 430 slides back and forth. The space required for arranging can be reduced.

  In other words, when securing the space for accommodating the shielding member 420 by sliding in the front-rear direction, the lower end of the oscillating member 430 on the opposite side of the shielding member 420 also moves by the distance D similarly to the upper end. Accordingly, a space for disposing the swing member 430 increases. On the other hand, in the present embodiment, since the swing member 430 is swung, the shielding member 420 is smoothly accommodated between the main body member 410 and the swing member 430, and the arrangement area of the swing member 430 is reduced. It is possible to achieve both suppression.

  In the present embodiment, the change width d of the outer shape of the lower portion on the front side of the main body member 431 is particularly small during the tilting operation of the swing member 430. Therefore, even if the main body member 431 is tilted in a state in which another member approaches or abuts below the main body member 431 (see FIG. 9), it is possible to suppress a load from being applied between the members.

  In the present embodiment, in the state of FIG. 9, the upper surface of the moving member 540 (see FIG. 40) arranged to face the main body member 431 has a downwardly curved surface, and the main body member 431 approaches the curved surface. The main body member 431 can be tilted at a position (a position where the main body member 431 and the moving member 540 partially overlap in a front view). Accordingly, the posture of the main body member 431 can be changed with a large width at the upper part of the main body member 431 while ensuring the effect of bringing the main body member 431 and the moving member 540 closer to each other at the lower part of the main body member 431 and visually confirming them integrally. it can.

  As shown in FIGS. 34 and 35, the decorative member 422 of the shielding member 420 is inclined downward (toward the shaft support 416 (see FIG. 23)) or rearward (toward the main body member 410). It is formed to be curved in a direction away from the swing member 430. In this case, when the decoration member 422 starts to be accommodated between the swing member 430 and the main body member 410, a distance between the decoration member 422 and the swing member 430 can be ensured, and the decoration member 422 and the neck can be secured. Collision with the swing member 430 can be avoided.

  In addition, the lower end of the decorative member 422 can be stored deeply (downward) in the gap formed between the main body member 410 and the swing member 430 while the upper end of the decorative member 422 extends toward the front. . Since no other member is disposed on the front side of the swing member 430, the degree of freedom in designing the shape of the front portion of the swing member 430 can be improved.

  As illustrated in FIG. 35, in a state where the swing member 430 is upright, the decorative member 422 is separated upward from between the swing member 430 and the main body member 410, and the body member 431 of the swing member 430 is moved upward. The upper end and the main body member 410 are arranged close to each other. Accordingly, a dead space in a case where the decoration member 422 is not accommodated between the main body member 410 and the swing member 430 can be filled. In addition, by making it possible to form a posture in which the main body member 431 of the swing member 430 is disposed close to the main body member 410, the movement width of the swing member 430 in the front-rear direction in the pachinko machine 10 in which the front-rear width is defined is increased. As a result, the effect of the swinging motion of the swing member 430 can be improved.

  Here, FIG. 34 illustrates a state where the swing member 430 is disposed above the third symbol display device 81 and the swing member 430 is tilted. In this case, the direction A1 of the effect surface on the front side of the swing member 430 is a direction inclined obliquely downward toward the front. On the other hand, in FIG. 35, the swing member 430 is arranged on the front side of the third symbol display device 81 (see FIG. 2), and the state in which the swing member 430 is erected is shown by a solid line. In this case, the direction A2 of the effect surface on the front side of the swing member 430 is directed to the front. That is, by adjusting the degree of swing of the swinging member 430, the directions A1 and A2 on the front side of the swinging member 430 are directed toward the eyes of the player (the center front side of the third symbol display device 81). Can be adjusted. Therefore, the attention power of the swing member 430 can be improved, and the effect can be improved.

  Further, a new rotating shaft is not provided to improve the attention power of the swing member 430, but the shaft supporting portion 416 (see FIG. 23) is used. That is, the shaft support 416 is used to secure the distance between the decoration member 422 and the swing member 430 when the decoration member 422 starts being housed between the swing member 430 and the main body member 410, This is also used for the purpose of adjusting the directions A1 and A2 on the front side of the member 430 to the direction toward the eyes of the player (the center front side of the third symbol display device 81).

  The degree of swing of the swing member 430 can be determined based on whether or not the sensor passage portion 435d passes through the photo sensor 417. That is, in the state shown in FIG. 34, the sensor passing portion 435d has not passed through the photosensor 417. On the other hand, in the state shown in FIG. 35, the sensor passage section 435 has passed through the photosensor 417. Therefore, in the present embodiment, a gap between the swing member 430 and the main body member 410 is ensured in a state where the sensor passage portion 435 does not pass through the photosensor 417.

  Therefore, by moving up the main body member 410 in a state where the sensor passage portion 435 does not pass through the photosensor 417, the shielding member 420 and the main body member 410 can be moved without interfering with the swing member 430 and the shielding member 420. It can be accommodated between the swinging member 430.

  Here, with reference to FIGS. 36 and 37, a description will be given of how the shape of the hanging portion 422b suppresses a malfunction of the combined operation unit 400. FIG. 36 is a front view of the combined operation unit 400, and FIG. 37 is a partial cross-sectional view of the combined operation unit 400 taken along the line XXXVII-XXXVII in FIG. FIGS. 36 and 37 show a state in which the main body member 431 of the swing member 430 is tilted by a predetermined angle from the standing state (see FIG. 35), and the back side of the main body member 431 is in contact with the hanging portion 422b. .

  As shown in FIGS. 36 and 37, the main body member 410 is moved up and down in a state where the main body member 431 of the swing member 430 is in the middle position between the upright state (see FIG. 35) and the inclined state (see FIG. 34). In some cases. This control is performed, for example, when the composite operation unit 400 is immediately changed from the state of FIG. 34 to the state of FIG.

  Here, the drive motor 462 (see FIG. 21) that drives the main body member 410 after confirming that the main body member 431 of the swing member 430 is tilted (see the broken line in FIG. 35) from the standing state shown in FIG. Is rotated, a state in which the back side of the main body member 431 contacts the hanging portion 422b cannot occur (see FIG. 34).

  However, in this case, the drive motor 462 (see FIG. 21) is rotated after the operation of the swing member 430 is completed. Therefore, as compared with the case where the drive motor 433 (see FIG. 23) for tilting the swing member 430 and the drive motor 462 for driving the main body member 410 are simultaneously rotated, the composite operation unit 400 is moved from the state of FIG. The period for changing to the state becomes longer. In other words, it is necessary to drive the drive motor 433 and the drive motor 462 simultaneously in order to immediately change the composite operation unit 400 from the state of FIG. 34 to the state of FIG. In this case, the main body member 410 is moved up and down while the main body member 431 of the swing member 430 moves from the upright state (see FIG. 35) to the inclined state (see FIG. 34). In this case, the main body portion 431 of the swing member 430 may come into contact with the hanging portion 422b, and the composite operation unit 400 may malfunction.

  On the other hand, in the present embodiment, the hanging portion 422b is formed to be curved (see FIG. 37). Therefore, as shown in FIG. 37, the contact of the swing member 430 with the back side (formed in a plane) of the main body member 431 is not a contact with a surface but with a point (line). And the frictional resistance at the contact position can be suppressed. Therefore, it is possible to prevent the composite operation unit 400 from malfunctioning due to the contact between the main body member 431 of the swing member 430 and the hanging portion 422b.

  For example, when the state of FIGS. 36 and 37 is a state in which the main body member 410 is moving upward from FIG. 35, the frictional resistance at the contact position between the main body member 431 of the swinging member 430 and the hanging portion 422b is reduced. If it is large, it causes a reduction in the moving speed of the main body member 410. On the other hand, in the present embodiment, since the frictional resistance at the contact position between the main body member 431 of the swing member 430 and the hanging portion 422b is suppressed, the moving speed of the main body member 410 can be increased. In addition, as the main body member 410 moves upward, the main body member 431 of the swing member 430 becomes inclined due to the curved shape of the hanging portion 422b, so that the hanging portion 422b applies a driving force to the main body member 431 of the swing member 430. Giving relationships arise. Thus, the burden of the drive motor 433 causing the swinging member 430 to tilt can be reduced.

  Further, for example, when the state of FIGS. 36 and 37 is a state where the main body member 410 is moving downward from FIG. 34, the friction at the contact position between the main body member 431 of the swinging member 430 and the hanging part 422b is determined. If the resistance is large, it causes a reduction in the moving speed of the main body member 410. On the other hand, in the present embodiment, since the frictional resistance at the contact position between the main body member 431 of the swing member 430 and the hanging portion 422b is suppressed, the moving speed of the main body member 410 can be increased. Further, since the hanging portion 422b is formed to be inclined downward and inclining backward and the back side of the main body member 431 is formed in a flat shape, even if the main body member 410 moves downward while making contact with each other, the hanging portion 422b is formed. The 422b and the main body member 431 do not catch on each other.

  Accordingly, it is possible to prevent the composite operation unit 400 from malfunctioning by moving the main body member 410 while the main body member 431 of the swing member 430 is tilted. Therefore, by moving the main body member 410 while the main body member 431 of the swing member 430 is tilted, the state of the composite operation unit 400 can be changed immediately.

  Next, the swing operation unit 500 will be described with reference to FIGS. FIG. 38 is a front perspective view of the swing operation unit 500, and FIG. 39 is a rear perspective view of the swing operation unit 500. FIGS. 38 and 39 show a state in which the moving member 540 is disposed at the retracted position.

  Although the swing operation unit 500 is constituted by a pair of left and right operation units (see FIG. 5), since their technical structures are common, in FIGS. 38 to 50, the left operation of the pair of left and right operation units is performed. The unit will be described as a swing operation unit 500.

  FIG. 40 is an exploded front perspective view of the swing operation unit 500, and FIG. 41 is an exploded rear perspective view of the swing operation unit 500. In FIG. 40, the fastening holes 527 are partially enlarged and in FIG. 41, the bridging members 528 are partially enlarged.

  As shown in FIGS. 40 and 41, the swing operation unit 500 includes a base member 510 having a rectangular plate shape, and shaft support holes 522 and 526 formed at both ends. The distance between the drive-side arm member 520 in the form of a long plate, which is pivotally supported so as to be able to swing, and the center axes of the shaft support holes 532, 533 formed at both ends is the shaft support hole 522 of the drive-side arm member 520. , 526 has a length equal to the distance between the central axes thereof, and one side end of one side shaft support hole 532 is pivotally supported by the base member 510 so as to be swingable. A horizontally long block-shaped moving member 540 which is swingably supported by the other side shaft support hole 526 of the drive side arm member 520 and the other side shaft support hole 533 of the driven side arm member 530, and a drive side arm member 520. Drive force to swing the A driving device 550 for generating the light, and a front plate member 560 disposed on the front side of the base member 510 with the driving arm member 520 and the driven arm member 530 interposed therebetween and to which the driving motor 551 is fastened and fixed. Prepare.

  The base member 510 includes a plate-shaped main body portion 511, a plurality of shaft support portions 512 projecting from the right side of the main body portion 511 in a front view to the front side, and a lowermost first of the shaft support portions 512. A drive gear receiving hole 513 formed on the left side of the triaxial portion 512c when viewed from the front, a photo sensor 514 disposed on the right side of the shaft support portion 512, and a rectangular shape from the left side of the main body portion 511 when viewed from the front to the front side. And a lower support 515 projecting from the shape.

  The main body portion 511 is formed such that the height of the upper end portion is different between the left side of the first shaft portion 512a when viewed from the front and the right side when viewed from the front. That is, a step-down portion 511a having an upper side surface lowered by one step is provided on the left side of the first shaft portion 512a in a front view.

  The step-down portion 511a has an effect of expanding the display area of the third symbol display device 81 in a state where the moving member 540 of the swing operation unit 500 is disposed at the extended position (see FIG. 8). Further, in a state where the moving member 540 is disposed at the retracted position, for example, when the driven arm member 530 falls backward, the area where the driven arm member 530 may come into contact with the main body 511 in the front-rear direction is reduced. It can be reduced (see FIG. 39). Accordingly, when the moving member 540 moves from the retracted position to the extended position, or when the moving member 540 moves from the extended position to the retracted position, the driven arm member 530 and the main body 511 are connected. The area that may be rubbed can be reduced, and the moving member 540 can be moved smoothly.

  The shaft support portion 512 is formed of three bar members that are arranged vertically apart from each other and whose axes are parallel to each other, and a first end on which one end of the driven arm member is supported in order from the top. A shaft portion 512a, a second shaft portion 512b on which one end of the drive side arm member is supported, and a third shaft portion 512c on which a transmission gear 553 meshed with the drive gear 552 is supported. Prepare mainly.

  The drive gear receiving hole 513 is a through-hole in which a stepped portion that projects to the rear side of the drive gear 552 is fitted.

  The lower support portion 515 is in contact with the lower side of the lower surface of the other end of the drive-side arm member 520 when the drive-side arm member 520 is located at the retracted position, and the other end of the drive-side arm member 520. The part is prevented from swinging further downward.

  The drive-side arm member 520 is a member formed of a resin material, and has a main body plate portion 521 formed in a long plate shape and one end of the main body plate portion 521 (the right end in front view). ), A one-side shaft support hole 522 formed in the front-rear direction and through which the second shaft portion 512b is inserted, and a semicircle centered on the one-side shaft support hole 522 formed below the one-side shaft support hole 522. A gear portion 523 in which gear teeth are engraved on the outer periphery of the sensor portion, a sensor passage plate 524 fastened and fixed to a raised portion 521a raised near the outer periphery of the gear portion 523 to the front side, and a one-side shaft support hole 522. A collar member 525 having a coaxially disposed through hole and fastened and fixed to the rear side of the main body plate portion 521, and a collar member 525 formed in the other end portion (the left end portion in front view) of the main body plate portion 521 in the front-rear direction. The second shaft portion 542b of the moving member 540 is pivotally supported via a collar. A pair of fastening holes 527 including a pair of fastening holes 527a1 and 527b1 that are arranged near the other end of the main body plate portion 521 and are drilled in the front-rear direction. And a bridging member 528 through which the insertion portions 528a2 and 528b2 are inserted and fastened and fixed.

  The main body plate portion 521 includes, at one end (the right end in FIG. 40), a raised portion 521a that is inserted into the guide hole 563 and fastens and fixed to the sensor passage plate 524 at the tip.

  The gear portion 523 is a portion that meshes with the second gear portion 553b of the transmission gear 553 of the driving device 550 (see FIG. 48), and includes an umbrella portion 523a that is covered on the front side.

  In the present embodiment, the umbrella portion 523a is formed so as to cover the entire gear teeth 523 (see FIG. 48). However, the umbrella portion 523a does not necessarily need to cover the entire gear teeth 523, and is formed so as to cover at least the gear teeth of the second gear portion 553b of the transmission gear 553. 553b can be contacted, and wobble of the drive side arm member 520 can be prevented.

  The sensor passage plate 524 is a member disposed on the front side of the front plate member 560 in an assembled state (see FIG. 42), and is a fastening portion which is raised and fastened to one end of the main body plate portion 521. 524a and a sensor passing plate portion 524b extending radially from the fastening portion 524a around the one-side shaft support hole 522 in the assembled state.

  The sensor passage plate portion 524b is a member that is disposed to face the front side surface of the front plate member 560 and that passes through the inside of the photosensor 514. Here, the sensor passage plate portion 524b can be brought into contact with the front side surface of the front plate member 560, and the sensor passage plate portion 524b is brought into contact with the front plate member 560. Shaft tilting with respect to the two shaft portions 512b is suppressed. On the other hand, the sensor passing plate portion 524b is a member that can detect that the driving side arm member 520 has been set to the retracted position by passing through the inside of the photo sensor 514. That is, the sensor passage plate portion 524b can be used for both increasing the resistance to the deformation (shaft tilting) of the driving arm member 520 and detecting the posture of the driving arm member 520.

  The collar member 525 is a plate-shaped member whose outer shape is formed in a substantially rhombic shape with rounded corners, and has a main body portion 525a having a circular outer shape whose diameter is the end in the short direction of the outer shape. An outer fitting hole 525b formed at the center of the portion 525a, and a pair of fastening portions 525c disposed on the left and right sides of the main body portion 525a and formed with a tapered tip and fastened and fixed to the main body plate portion 521; Mainly equipped.

  The pair of fastening holes 527 includes a first fastening hole 527a to which the first bridging member 528a is fixed, and a second fastening hole 527b to which the second bridging member 528b is fixed.

  As shown in FIG. 40, since the pair of fastening holes 527 are formed on the other shaft support portion 526 side (the side on which the moving member 540 is provided) of the driving arm member 520, the fastening holes 527 and one side shaft are formed. A long distance from the support hole 522 can be ensured. Therefore, as described later, even when the driven arm member 530 contacts the bridging member 528 and there is a possibility that the driving arm member 520 may be torsionally deformed, the deformation is determined by the fastening hole 527 and the one-side shaft support hole 522. And a long distance can be used at the portion between them (the torsion angle per a predetermined length in the longitudinal direction can be reduced). In this case, it is possible to suppress a load (a load in a direction in which the second shaft portion 512b is folded and folded) from the one shaft support hole 522 to the second shaft portion 512b, and improve the durability of the second shaft portion 512b. be able to.

  The first fastening hole portion 527a is provided with a first fastening hole 527a1 to which the first bridging member 528a is fastened and fixed, and is formed adjacent to the first fastening hole 527a1 and the auxiliary protrusion 528a3 is inserted therethrough. And a first pinning hole 527a2 to which the first bridge member 528a is non-rotatably fixed.

  The first fastening holes 527a1 and the first pin fastening holes 527a2 are arranged along a line forming a predetermined angle θ1 (θ1 <90 degrees) with respect to the short direction of the drive side arm member 520 (see FIG. 43). .

  The second fastening hole 527b is provided with a second fastening hole 527b1 to which the second bridging member 528b is fastened and fixed, and is formed adjacent to the second fastening hole 527b1 and the auxiliary projection 528b3 is inserted therethrough. A second pinning hole 527b2 to which the second bridging member 528b is non-rotatably fixed, and a base 527b3 formed in such a manner that the outer edges of the second fastening hole 527b1 and the second pinning hole 527b2 are raised to the front side. , Is provided.

  The second fastening holes 527b1 and the second pin fastening holes 527b2 are arranged along a line that forms a predetermined angle θ2 (θ2 <90 degrees) with respect to the short direction of the driving arm member 520 (see FIG. 43). . That is, when the second bridging member 528b is bent and deformed toward the near side in FIG. 43, the load applied to the driving arm member 520 is determined by the twist direction (the direction of rotation about the longitudinal direction of the driving arm member 520). It can be divided in the bending direction (the direction in which the drive side arm member 520 bends to the front side). Thus, when the second bridge member 528b receives a load from the driven side arm member 530 and bends and deforms, it is possible to suppress the drive side arm member 520 from being twisted and deformed around the longitudinal direction.

  The bridging member 528 is provided on a first bridging member 528a disposed on a side closer to the other-side shaft support portion 526, and on a side opposite to the other-side shaft support portion 526 across the first bridge member 528a. And a second bridging member 528b formed larger (longer and wider in the lateral direction) than the first bridging member 528a.

  The first bridging member 528a has a main body 528a1 formed in a long plate shape, an insertion portion 528a2 inserted into the first fastening hole 527a1 and fastened and fixed, and a projecting portion adjacent to the insertion portion 528a2. An auxiliary protruding portion 528a3, a rib portion 528a4 formed along a side edge of the main body portion 581a1 close to the other shaft support hole 526, and protruding toward the rear side, and an end portion of the rib portion 528a4. And an inclined portion 528a5 inclined with respect to the projecting direction.

  The main body 528a1 has a length that covers the driven arm member 530 in a front view in an assembled state (see FIG. 48).

  The auxiliary projection 528a3 is a portion that is inserted into a first pin hole 527a2 formed adjacent to the first fastening hole 527a1 of the main body plate portion 521, so that the bridging member 528 is connected to the main body plate portion 521. Are supported at two points. Therefore, the bridging member 528 can be fixed to the main body plate portion 521 so as not to rotate relatively.

  Since the rib 528a4 is not formed up to the tip of the main body 528a1, the rib 528a4 prevents contact with the driven arm member 530 at the retracted position (see FIG. 48), and the driven arm at the extended position (see FIG. 50). It is formed in such a manner that it can easily come into contact with the member 530. The details will be described later.

  The second bridging member 528b is formed in a long plate shape, an insertion portion 528b2 inserted into the second fastening hole 527b1 and fastened and fixed, and protrudes adjacent to the insertion portion 528b2. An auxiliary protruding portion 528b3, a rib portion 528b4 formed along a side edge of the main body portion 581b1 close to the other shaft support hole 526, and protruding toward the rear side, and an end portion of the rib portion 528b4. And an inclined portion 528b5 inclined with respect to the projecting direction.

  The main body portion 528b1 is formed to have a length that covers the driven arm member 530 in a front view in an assembled state (see FIG. 48).

  The auxiliary projecting portion 528b3 is a portion that is inserted into a second pin fastening hole 527b2 formed adjacent to the second fastening hole 527b1 of the main body plate portion 521, whereby the bridging member 528 is connected to the main body plate portion 521. Are supported at two points. Therefore, the bridging member 528 can be fixed to the main body plate portion 521 so as not to rotate relatively.

  Since the rib portion 528b4 is not formed up to the tip of the main body portion 528b1, the contact with the driven arm member 530 is suppressed at the retracted position (see FIG. 48), and the driven arm is set at the extended position (see FIG. 50). It is formed in such a manner that it can easily come into contact with the member 530. The details will be described later.

  As shown in FIG. 43, the second bridge member 528b has a width of a portion overlapping with the driven arm member 530, rather than a width of a portion of the main body 528b1 (see FIG. 41) fastened to the drive arm member 520. It is formed narrower. Accordingly, when the driven arm member 530 abuts on the second bridging member 528b, it is possible to suppress the second bridging member 528b from being twisted about the longitudinal direction (flexing along the longitudinal direction). Can be easier).

  Therefore, the contact between the driven arm member 530 and the second bridging member 528b can prevent the second bridging member 528b from being twisted and deformed, and the mode of deformation can be limited. In this case, the arrangement position of the portion (the second pin hole 527b2) for preventing the second bridging member 528b from being turned up can be limited, so that the configuration of the second bridging member 528b can be simplified. . That is, it is not necessary to form the auxiliary projection 528b3 (see FIG. 41) in the short direction of the second bridge member 528b with respect to the insertion portion 528b2 (see FIG. 41).

  The driven arm member 530 is a member formed of a resin material, and includes a main body plate portion 531 formed in a long plate shape and one end of the main body plate portion 531 (the right end portion in front view). ), One side shaft support hole 532 in which the first shaft portion 512a is inserted in the front-rear direction, and the other end (the left end in front view) of the main body plate portion 531 is formed in the front-rear direction. And a second shaft support hole 533 in which the first shaft portion 542a of the moving member 540 is supported via a collar.

  The front side surface of the main body plate portion 531 is formed on the same plane as the front side surface of the drive arm member 520.

  The moving member 540 includes a main body 541 that is formed in a block shape that is long in the left and right direction and that has an upper surface formed by a curved surface that is convex downward, and a cylindrical shape that projects rearward on the right side of the main body 541 when viewed from the rear. It mainly includes a pair of shaft support portions 542 provided and an alignment portion 543 protruding from the right side surface of the main body portion 451.

  In the present embodiment, the moving member 540 is formed so as to be thicker toward the side where the pair of moving members 540 abut (the right side in FIG. 42A). The member 540 is formed on the side where it contacts, and is formed at a position separated from the driven arm member 530 toward the front side (see FIG. 42).

  The shaft support portion 542 is formed with the same inter-axis distance as the inter-axis distance between the first shaft portion 512a and the second shaft portion 512b, and the relative arrangement of a pair of shafts in the state shown in FIG. The shaft portion 512a and the second shaft portion 512b are formed from a pair of shafts formed in the same manner as the arrangement of the shafts, and mainly include a first shaft portion 542a and a second shaft portion 542b in order from the top.

  The first shaft portion 542a is a portion inserted into the other shaft support hole 533 of the driven arm member 530, and the second shaft portion 542b is inserted through the other shaft support hole 526 of the drive arm member 520. Part.

  Here, as described above, the axial distance between the shaft support holes 522 and 526 at both ends of the drive side arm member 520 and the axial distance between the shaft support holes 532 and 533 at both ends of the driven arm member 530 are different. It is the same. Further, the relative positions of the first shaft portion 512a and the second shaft portion 512b provided on the base member 510 and the first shaft portion 542a and the second shaft portion 542b provided on the moving member 540 are different. The relationship (the direction and distance of a straight line connecting the axes) is the same. Therefore, a parallel link is formed by the driving side arm member 520 and the driven side arm member 530, and the posture of the moving member 540 is not changed during the swing of the driving side arm member 520 (FIGS. 48 to 50).

  The positioning part 543 is a part for adjusting the relative positional relationship between the pair of moving members 540 when the moving member 540 is arranged at the overhang position. Note that a recess is formed in the moving member 540 on the right side (see FIG. 8) in front view so as to be able to receive the alignment portion 543 of the left moving member 540.

  The drive device 550 includes a drive motor 551 fastened and fixed to the front side of the front plate member 560 with the drive shaft facing the rear side, a drive gear 552 supported by the drive motor 551, and one drive gear 552. The transmission gear 553 mainly meshes with the first gear portion 553a of the second stage and the second gear portion 553b of the second stage meshes with the gear portion 523 of the driving arm member 520.

  The transmission gear 553 is a member in which two-stage gear teeth having different diameters are formed coaxially. The transmission gear 553 includes a first gear portion 553a formed of a large-diameter gear disposed to face the base member 510, and a first gear portion 553a. A second gear portion 553b formed from a gear smaller in diameter than the first gear portion 553a disposed on the front side of the gear portion 551a, and a hole is formed at the center of the first gear portion 553a and the second gear portion 553b. And a shaft support hole 553c supported by the third shaft portion 512c of the base member 510.

  The front plate member 560 includes a main body portion 561 formed in a horizontally long plate shape, a holding portion 562 recessed in the same arrangement as that of the shaft support portion 512 of the base member 510, and a fastening portion 524a of the sensor passage plate 524. And a guide hole 563 that is formed in an arc shape along the movement locus.

  The holding portion 562 is recessed with a diameter equal to the diameter of each column of the shaft support 512, and the tip of each shaft of the shaft support 512 is fitted and fixed therein. Thus, the shaft support 512 can be supported at both ends, so that the shaft can be stabilized. Accordingly, the operations of the driving arm member 520, the driven arm member 530, and the transmission gear 553 can be stabilized.

  The guide hole 563 is an arc-shaped long hole through which a raised portion 521a protruding from the drive-side arm member 520 toward the sensor passage plate 524 is inserted, and extends in the front-rear direction at a lower end. And a stopper wall portion 563a. Thus, even if the drive side arm member 520 is displaced in the radial direction with respect to the second shaft portion 512b, the raised portion 521a of the drive side arm member 520 comes into contact with the guide hole 563 to restrict the movement. Thus, the position of the drive-side arm member 520 can be stabilized.

  The stopper wall portion 563a is a wall portion for preventing the movable member 540 from swinging beyond its movable range when the movable member 540 is moved toward the extended position (see FIG. 43). is there. When moving member 540 moves to the right from the state shown in FIG. 43, stopper wall portion 563a and sensor passage plate 524 and raised portion 521a to which sensor passage plate 524 is fastened and fixed (see FIG. 40) come into contact. You. The stopper wall 563a extends not only on the front side but also on the back side. Thus, the contact area between one end of the drive-side arm member 520 and the stopper wall 563a can be increased, and the sensor passage plate 524 and the raised portion 521a to which the sensor passage plate 524 is fastened and fixed at the time of contact. Can be reduced.

  With reference to FIG. 42 and FIG. 43, the end of the movable range of the swing operation unit 500 will be described. 42 (a) and 43 are front views of the swing operation unit 500, and FIG. 42 (b) is a side view of the swing operation unit 500 as viewed in the direction of the arrow XXXXIIb in FIG. 42 (a). FIG. 42 illustrates a state in which the moving member 540 is disposed at the retracted position, and FIG. 43 illustrates a state in which the moving member 540 is disposed at the extended position.

  As shown in FIGS. 42 and 43, when the moving member 540 swings from the retracted position to the extended position, the posture of the moving member 540 is not changed. Therefore, when the pair of left and right moving members 540 (see FIG. 6) are close to each other (both are rocked to the overhang position), the opposed side surfaces (the right side surface in FIG. 43) remain parallel. Since they are brought close to each other, it is possible to easily combine the pair of moving members 540 by fitting the positioning portions 543 together.

  In a state where the moving member 540 is located at the overhang position, the bridging member 528 is put on the front side surface of the driven arm member 530. Further, since the distance between the drive side arm member 520 and the driven side arm member 530 is reduced, the drive side arm member 520 and the driven side arm member 530 can be brought into contact when swinging beyond the extended position. Thus, the swing of the drive-side arm member 520 can be stopped.

  As shown in FIGS. 42 (a) and 42 (b), the center of gravity G of the moving member 540 is formed on the side (the right side in FIG. 42) where the pair of moving members 540 is abutted in the left-right direction. In the direction, it is formed separately from the driving side arm member 520 and the driven side arm member 530.

  As shown in FIG. 43, a bridging member 528 fastened and fixed to the front side of the drive side arm member 520 is extended so as to cover the front side of the driven side arm member 530.

  Here, with reference to FIG. 44, a difference in a fastening position between the first bridge member 528a and the second bridge member 528b will be described. Due to the difference between the fastening portions, the ease with which the first bridge member 528a and the second bridge member 528b are turned from the drive-side arm member 520 differs.

  Here, “turning up” means that the bridging member 528 receives a force from the driven arm member 530 upward in FIG. 44 and is separated from the driving arm member 520.

  FIG. 44A is a cross-sectional view of the driving arm member 520, the driven arm member 530, and the first bridging member 528a taken along the line XXXXIVa-XXXIVa in FIG. 43, and FIG. It is sectional drawing of the drive side arm member 520, the driven side arm member 530, and the 2nd bridge member 528b in the -XXXIVb line.

  First, as a first difference, as shown in FIG. 44B, the second fastening holes 527b1 and the second pin fastening holes 527b2 for receiving the second bridging members 528b are different from the first fastening holes 527a. A platform 527b3 is formed. Thereby, the second embedding width Wb1, which is the embedding width of the insertion portion 528b2 in the second fastening hole 527b1, is longer than the first embedding width Wa1, which is the embedding width of the insertion portion 528a2 in the first fastening hole 527a1. Is done. Therefore, the second bridging member 528b can be fixed more firmly than the first bridging member 528a (the second bridging member 528b is harder to bend than the first bridging member 528a).

  As a second difference, the first overhang width Wa2, which is the overhang width of the insertion portion 528b2 from the main body plate portion 521 in the fastened and fixed state, is the overhang width of the insertion portion 528a2 from the main body plate portion 521. It is shorter than the second overhang width Wb2. Therefore, the second bridging member 528b can suppress deformation near the fastening position as compared with the first bridging member 528a (the second bridging member 528b has a smaller shape than the first bridging member 528a). It is hard to turn up compared).

  As a third difference, the first fastening hole 527a1 is formed on the opposite side of the driven arm member 530 with respect to the first pinning hole 527a2 (see FIG. 44A), but the second fastening hole 527b1 is The two-pin fastening hole 527b2 is formed on the side close to the driven arm member 530 as a reference (see FIG. 44B).

  In this case, the driven arm member 530 moves (bends and falls down) in a direction (upward in FIG. 44) approaching the bridging member 528, and is fastened when a load is applied from the driven arm member 530 to the bridging member. There is a difference in how to bear in the part.

  That is, when the first bridging member 528a is pushed by the driven arm member 530 and the main body 528a1 bends with the insertion portion 528a2 as a starting point, the auxiliary protrusion 528a3 separates from the driving arm member 520 (FIG. 44 (a)). Therefore, a frictional resistance between the side surface of the auxiliary protrusion 528a3 and the inner surface of the first pin hole 527a2 generates a resisting force against the turning of the main body 528a1.

  On the other hand, when the second bridging member 528b is pushed by the driven arm member 530 and the main body 528b1 bends from the insertion portion 528b2 as a starting point, the seating surface of the auxiliary projection 528b3 is pressed against the driving arm member 520. (See FIG. 44 (b)). Therefore, in addition to the frictional resistance between the side surface of the auxiliary protrusion 528b3 and the inner surface of the second pin hole 527b2, the seat surface of the auxiliary protrusion 528b3 is located on the front side (upper side in FIG. 44B) of the main body plate portion 521. , A resistance to turning of the main body 528b1 is generated.

  Accordingly, the resistance of the second bridging member 528b to turning can be increased as compared to the resistance of the first bridging member 528a to turning.

  The distance between the axes of the second fastening hole 527b1 and the second pinning hole 527b2 is longer than the distance between the axes of the first fastening hole 527a1 and the first pinning hole 527a2.

  Due to the first to third differences described above, a similar load is applied from the driven side arm member 530 to either the first bridging member 528a or the second bridging member 528b toward the front side (upward in FIG. 44). In this case, the second bridging member 528b has a stronger resistance at the root to the turning (a force to resist turning at the fastening position with the driving arm member 520) than the first bridging member 528a. growing.

  With reference to FIG. 45, a description will be given of an aspect of contact between the driven arm member 530 and the bridging member 528 when the driven arm member 530 is bent and deformed. FIG. 45 (a) is a partial side view of the swing operation unit 500 as viewed in the direction of the arrow XXXXVa in FIG. 43. FIGS. 45 (b) and 45 (c) show the state of FIG. FIG. 10 is a partial side view of the swing operation unit 500 illustrating a state in which an arm member 530 flexes to the front side in time series.

  Note that FIG. 45 (a) illustrates a state in which the longitudinal directions of the drive side arm member 520 and the driven side arm member 530 are parallel, and FIG. 45 (b) illustrates that the driven side arm member 530 is on the front side (FIG. 45). FIG. 45 (b) shows a state in which the driven arm member 530 is bent toward the front side from the state shown in FIG. 45 (b) in FIG. 45 (c). A state in which it is in contact with the bridging member 528b is illustrated. Further, in FIG. 45, the base member 510, the moving member 540, and the front plate member 560 are illustrated virtually by imaginary lines.

  As shown in FIG. 45, the first bridging member 528a is disposed closer to the moving member 540 than the second bridging member 528b. Therefore, when the upper end of the driven arm member 530 is bent to the front side (the left side in FIG. 45) due to factors such as the weight of the moving member 540 and the contact with other members, the first bridge is started first when the amount of bending is small. The driven arm member 530 abuts on the bridging member 528a (see FIG. 45B). Thereafter, when the amount of bending of the driven side arm member 530 increases, the first bridging member 528a bends and deforms, and the second bridging member 528b abuts on the driven side arm member 530 (see FIG. 45 (c)).

  That is, since the displacement of the driven arm member 530 is greater in the portion that abuts on the first bridge member 528a, a larger load is applied to the first bridge member 528a than in the second bridge member 528b. Can be

  Here, when the resistance of the first bridging member 528a to the bending deformation is as large as that of the second bridging member 528b, the first bridging member 528a bends and deforms even if the amount of bending of the driven arm member 530 increases. (The drive side arm member 520 may bend instead). In this case, the driven arm member 530 and the second bridging member 528b do not come into contact with each other, and only the first bridging member 528a receives the load from the driven side arm member 530 alone. The durability of the member 528a decreases.

  On the other hand, in the present embodiment, as described above, the first bridging member 528a is fastened to the drive-side arm member 520 in a manner that the first bridging member 528b is more easily turned at the root portion than the second bridging member 528b. Therefore, before the driven side arm member 530 contacts the second bridging member 528b, the first bridging member 528a is easily turned up (is deformed in the vicinity of the root with respect to the driving side arm member 520).

  In addition, the width of the first bridging member 528a in the lateral direction is smaller than that of the second bridging member 528b, and the plate thickness is formed to be equal (see FIG. 44). That is, the section modulus of the second bridge member 528b in the same direction is larger than that of the first bridge member 528a in the direction of the load applied to the bridge member 528 from the driven arm member 530. Is done. Therefore, the first bridging member 528a is more likely to bend in the short vertical direction (the left and right direction in FIG. 45A) than the second bridging member 528b.

  This allows the pair of bridging members 528 to contact the driven arm member 530 and receive the load (see FIG. 45 (c)), and distribute the load to the pair of bridging members 528 to bear the load. As a result, the durability of the first bridge member 528a and the second bridge member 528b can be improved.

  Note that the method of receiving the load from the driven arm member 530 by the pair of bridging members 528 is not limited to bending the first bridging member 528a. For example, by making the first overhang width Wa2 (see FIG. 44) of the first bridging member 528a longer than that of the present embodiment, the driven arm member 530 and the first bridge can be bent at the bending amount shown in FIG. The bridging member 528a may not be brought into contact, and the pair of bridging members 528 may start to come into contact with the driven arm member 530 at the same time with the amount of bending shown in FIG. In this case, both the first bridging member 528a and the second bridging member 528b can receive the load from the driven arm member 530, and the load is applied to the first bridging member 528a and the second bridging member 528b. Can be distributed and paid.

  On the other hand, when the amount of bending is small (see FIG. 45 (b)), the driven arm member 530 does not abut on any of the pair of bridging members 528, so it is difficult to suppress the bending of the driven arm member 530. (The bending is suppressed only by the rigidity of the driven arm member 530 until the bending amount of FIG. 45C is reached).

  In contrast, in the present embodiment, while the amount of bending of the driven side arm member 530 is small, bending can be suppressed by bringing the driven side arm member 530 into contact with the first bridge member 528a (FIG. 45). (B)). In addition, as described above, when the amount of bending of the driven side arm member 530 increases, the first bridging member 528a bends and deforms, and the driven side arm member 530 and the second bridging member 528b abut. Thereby, the load from the driven arm member 530 can be received by the pair of bridging members 528, and the load can be distributed to the pair of bridging members 528 and borne, so that the first bridging members 528a and The durability of the second bridge member 528b can be improved.

  Next, with reference to FIG. 46, a description will be given of the front-rear relationship of the driving arm member 520, the driven arm member 530, and the bridging member 528. FIG. 46 is a cross-sectional view of the drive-side arm member 520 and the driven-side arm member 530 along the line XXXXIV-XXXXXIV in FIG. Note that FIG. 46 shows only a cross-sectional view of a long portion of the drive-side arm member 520 and the driven-side arm member 530 for easy understanding, and the shapes of the ends of the arm members 520 and 530 are omitted. I do.

  As shown in FIG. 46, the drive-side arm member 520 and the driven-side arm member 530 have front side surfaces (upper side surfaces in FIG. 46) formed substantially in the same plane, and the bridging member 528 is connected to the driven-side arm member 530. It is put on the front side of. Accordingly, the driven arm member 530 moves to the front side along the arrow B1 (bending deformation and falling deformation), and the driving side arm member 520 moves to the back side along the arrow B2 (deflecting deformation and falling deformation). Or rotation (twist deformation) of the drive-side arm member 520 along the arrow B3 can be suppressed. That is, the relative movement (deformation) between the drive side arm member 520 and the driven side arm member 530 can be suppressed by abutting the bridge member 528 and the driven side arm member 530.

  Here, the moving member 540 (see FIG. 43) is disposed on the front side of the driving arm member 520 and the driven arm member 530, and the center of gravity G of the moving member 540 is formed on the front side of each arm member 520, 530. (See FIG. 42). As described above, the center of gravity G of the moving member 540 is formed closer to the side where the pair of moving members 540 abut (the right side in FIG. 43), so that the driven arm member 530 is There is a great risk of falling. On the other hand, when the driven side arm member 530 falls forward, the driven side arm member 530 is supported (contacted) from the front side of the bridge member 528. Accordingly, it is possible to prevent the driven arm member 530 from moving to the front side (the front side in FIG. 43), and to move the moving member 540 to the front side.

  Since the driving side arm member 520 is a member to which the driving force is transmitted, there is a possibility that the driving side arm member 520 may fluctuate in the swing axis direction (vertical direction in FIG. 46) depending on the degree of the transmission. The wobble can be suppressed by abutment of the bridge member 528 and the driven arm member 530.

  On the other hand, when the drive side arm member 520 moves to the front side along the arrow B1 (bending deformation or falling deformation) or rotates clockwise (twisting deformation) in the opposite direction to the arrow B3, the bridge Since the bridging member 528 is moved in a direction away from the driven arm member 530, it is difficult to suppress the movement of the driving arm member 520. Therefore, it is preferable to have a mechanism for preventing these movements. Next, referring to FIG. 47, it is possible to prevent the drive-side arm member 520 from moving forward (bending movement or falling down) along the arrow B1, or to set the drive-side arm member 520 in the direction opposite to the arrow B3. A mechanism for suppressing clockwise rotation (twist deformation) will be described.

  FIG. 47 is a partial cross-sectional view of the swing operation unit 500 along the line XXXXV-XXXXXV in FIG. As shown in FIG. 47, one end of the driving arm member 520 is in contact with the transmission gear 553 from the front side (the upper side in FIG. 47). That is, the gear portion 523 is abutted from the front side of the first gear portion 553a of the transmission gear 553, and the umbrella portion 523a is abutted from the front side of the second gear portion 553b. Here, regardless of the arrangement of the driving arm member 520, the transmission gear 553 is disposed on the opposite side of the driven arm member 530 with respect to the straight line connecting the shaft support holes 522 and 526 formed at both ends of the driving arm member 520. (See FIGS. 48 to 50).

  Therefore, when the side of the drive side arm member 520 that is close to the driven side arm member 530 moves to the front side (torsion deformation in the direction opposite to the arrow B3 in FIG. 46), the gear portion 523 is pressed against the first gear portion 553a. Is moved in a direction in which the umbrella portion 523a is pressed against the second gear portion 553b. In this case, the deformation resistance of the drive-side arm member 520 increases. Therefore, the movement (twisting deformation) of the driving side arm member 520 in the direction opposite to the arrow B3 in FIG. 46 can be suppressed.

  As shown in FIG. 47, a sensor passage plate 524 is disposed at the front end of one end of the drive-side arm member 520, in front of the front plate member 560. Accordingly, when the other end (the right side in FIG. 47) of the drive-side arm member 520 moves to the front side along the arrow B1 (bending deformation or falling deformation), one end sandwiching the second shaft 512b. The deformation resistance of the drive-side arm member 520 can be increased by contacting the sensor passage plate 524 with the front plate member 560 in the portion. Therefore, it is possible to suppress the other end of the drive-side arm member 520 from moving in the arrow B1 direction (bending deformation or falling deformation).

  As shown in FIG. 47, the collar member 525 is formed with a thickness substantially equal to the thickness of the first gear portion 553a of the transmission gear 553. As shown in FIG. 41, the collar member 525 is formed in a shape smaller than the outer shape of one end of the drive-side arm member 520 in a front view, so that the base member 510 and the drive-side arm member are formed by the collar member 525. 520 can be reduced in contact area. Therefore, the contact resistance when the drive side arm member 520 is swung can be suppressed, and the size of the drive motor 551 can be reduced.

  Next, the swing operation of the driving arm member 520 and the driven arm member 530 will be described with reference to FIGS. 48 to 50 are front views of the driving arm member 520 and the driven arm member 530. In FIG. 48, a state in which the driving arm member 520 and the driven arm member 530 are disposed at the retracted position as in FIG. 42, and in FIG. 49, the driving arm member 520 and the driven arm member 520 are changed from the state in FIG. FIG. 50 shows a state in which the member 530 has been swung by a predetermined amount, and FIG. 50 shows a state in which the drive-side arm member 520 and the driven-side arm member 530 are disposed at the extended positions, respectively. 48 to 50, the outer shape of the moving member 540 is illustrated by imaginary lines, the sensor passing plate 524 is not illustrated, and a part of the first gear portion 553a of the collar member 525 and the transmission gear 553 is indicated by a hidden line. As shown, the umbrella portion 523a of the gear portion 523 is partially omitted so that the gear teeth are visible.

  As shown in FIGS. 48 to 50, the distance between the drive side arm member 520 and the driven side arm member 530 is reduced from the retracted position to the extended position. Therefore, the area where the bridging member 528 covers the driven side arm member 530 increases from the retracted position to the overhanging position, and the driven side arm member 530 moves to the front side, and when the bridge member 528 comes into contact with the bridging member 528, The resistance generated from the bridging member 528 can be increased.

  As shown in FIG. 48, the rib portion 528a4 of the first bridging member 528a and the rib portion 528b4 of the second bridging member 528b are formed by the one side shaft support hole 532 and the other side shaft support hole of the driven arm member 530. 533 is formed below the straight line. Therefore, at the retracted position, the driven side arm member may change its posture in such a manner that a portion above a straight line connecting the one-side shaft support hole 532 and the other-side shaft support hole 533 falls forward (toward the front in FIG. 48). The distance between 530 and bridge member 528 can be kept large. Thereby, when the drive side arm member 520 and the driven side arm member 530 start from the retracted position, the driven side arm member 530 falls forward and comes into contact with the bridge member 528, so that the drive side arm member 520 and the driven side It is possible to prevent the swing resistance of the arm member 530 from increasing.

  On the other hand, as shown in FIG. 50, the rib portion 528a4 of the first bridging member 528a and the rib portion 528b4 of the second bridging member 528b are disposed at intermediate positions in the longitudinal direction of the driven arm member 530. . Therefore, at the overhang position, the distance between the driven arm member 530 and the bridging member 528, which may change in posture in a state of falling and deforming starting from the one shaft support portion 532, can be reduced. Thus, at the overhang position, the driven arm member 530 and the bridging member 528 can be brought into contact with each other since the amount of deformation of the driven arm member 530 falling down is small.

  That is, the rib portions 528a4 and 528b4 suppress the swing resistance when the driving arm member 520 and the driven arm member 530 start from the retracted position, and the driven arm member 530 is disposed at the extended position. In this state, the contact between the driven arm member 530 and the bridging member 528 can be made compatible from within a small amount of the tilt deformation of the driven arm member 530.

  Also, while the drive-side arm member 520 moves from the retracted position to the extended position, the bridge member 528 is at least partially disposed on the front side of the driven arm member 530. . Accordingly, while the bridging member 528 is not disposed on the front side of the driven arm member 530, the driven arm member 530 moves in the axial direction, and the side surface of the driven arm member 530 facing the driving arm member 520. And the bridge member 528 can be prevented from coming into contact with each other. Further, since the driven arm member 530 can always contact the bridging member 528, the effect of suppressing the axial displacement of the driven arm member 530 can be improved.

  As shown in FIG. 50, in a state where the moving member 540 is disposed at the extended position, the driving arm member 520 and the driven arm member 530 are on the side where the pair of moving members 540 abut (right side in FIG. 50). Take a posture inclined to the opposite side of the. Therefore, there is a possibility that it is necessary to keep operating the drive motor 551 in order to maintain the arrangement of the moving member 540 (to prevent the drive side arm member 520 from rotating counterclockwise in front view).

  On the other hand, in the present embodiment, the center of gravity G of the moving member 540 is formed on the side where the pair of moving members 540 abut (the right side in FIG. 50). Therefore, in a state where the moving member 540 is located at the extended position, the driving arm member 520 and the driven arm member 530 receive a load from the moving member 540 in the clockwise direction when viewed from the front. This can prevent the drive-side arm member 520 from rotating counterclockwise in front view, so that it is not necessary to keep the drive motor 551 operating while the moving member 540 is located at the extended position. Thus, power consumption of the drive motor 551 can be reduced.

  The transmission gear 553 and the gear portion 523 formed at one end of the drive-side arm member 520 are in contact in the front-rear direction as described above. As shown in FIGS. 48 to 50, the contact surfaces of the transmission gear 553 and the gear portion 523 are moved in substantially the same direction (leftward in FIG. 48) during the swinging operation of the driving arm member 520.

  That is, the driving force required for the rotation of the gear portion 523 is generated not only from the engagement of the transmission gear 553 with the second gear portion 553b, but also from the front side (the front side in FIG. 48) of the first gear portion 553a. It can also be transmitted by contact with the rear side surface of the portion 523. This can be said that the swing resistance of the drive-side arm member 520 has been reduced. Thus, the driving force required for the drive motor 551 can be reduced, and the size of the drive motor 551 can be reduced.

  As shown in FIG. 48, the collar member 525 has a longitudinal direction connecting the pair of fastening portions 525c and a short direction that is a direction perpendicular to the longitudinal direction, and the longitudinal direction is in a posture along the longitudinal direction of the driving arm member 520. The driving side arm member 520 is fastened and fixed. Thus, the collar member 525 and the base member 525 extend along the longitudinal direction of the drive side arm member 520 as compared with the range in which the collar member 525 and the base member 510 contact with each other along the lateral direction of the drive side arm member 520. The range of contact with 510 is increased.

  Therefore, the other end (the end on the left side in FIG. 48) of the drive-side arm member 520 starts from the second shaft portion 512b (see FIG. 40) inserted through the one-side shaft support hole 522, and starts in the front-rear direction (see FIG. 48). When deforming to bend in the direction perpendicular to the paper surface, the range in which the collar member 525 is pressed against the base member 510 (see FIG. 40) can be increased. Thus, the deformation resistance of the driving arm member 520 can be increased.

  The straight line L connecting the central axis of the collar member 525 and the central axis of the transmission gear 553 always intersects the circular outer shape of the main body 525a of the collar member 525. That is, it does not intersect with the outer shape of the fastening portion 525c. Thus, the center distance between the collar member 525 and the transmission gear 553 can be reduced to a minimum length.

  In other words, there is no need to insert the fastening portion 525c arranged in the longitudinal direction of the collar member 525 between the central axis of the collar member 525 and the central axis of the transmission gear 553, and therefore, the central axis of the collar member 525 and the transmission gear The center-to-center distance between the 553 and the central axis can be reduced. This inter-axis distance is a distance at which the main body 525a of the collar member 525 and the transmission gear 553 can be arranged to face each other. Thus, the degree of freedom in the arrangement of the collar member 525 can be improved, and the degree of freedom in the arrangement of the drive side arm member 520 can be improved.

  Further, even when the center distance between the center axis of the collar member 525 and the center axis of the transmission gear 553 is the same, when the fastening portion 525c enters between the center axis of the collar member 525 and the center axis of the transmission gear 553. In comparison, the contact area in the axial direction between the first gear portion 553a of the transmission gear 553 and the driving arm member 520 can be increased.

  Next, a swing operation unit 2500 according to the second embodiment will be described with reference to FIG. In the first embodiment, the case where the end of the bridging member 528 of the oscillating operation unit 500 is not fixed has been described. However, the oscillating operation unit 2500 according to the second embodiment is configured such that the main body 2561 of the front plate 2560 has It is provided with a thickened portion 2561a for accommodating the tip of the bridging member 2528. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIGS. 51A and 51B are partial front views of the swing operation unit 2500 in the second embodiment. Note that FIG. 51A illustrates a state in which the moving member 540 is disposed at the retracted position, and FIG. 51B illustrates a state in which the moving member 540 is disposed at the extended position. 51 (a) and FIG. 51 (b), the moving member 540 is illustrated by imaginary lines.

  As shown in FIGS. 51A and 51B, the main body 2528a of the bridging member 2528 is formed over the width direction of the driven arm member 530. Accordingly, when the driven arm member 530 moves toward the front side (downward in FIG. 51), the area of the main body 2528a contacting the driven arm member 530 is reduced to the first embodiment. It is possible to enlarge in comparison, and it is possible to suppress the movement of the driven arm member 530.

  The main body 2561 of the front plate member 2560 has a thickened portion 2561a formed by increasing the thickness in the front-rear direction (the direction perpendicular to the paper surface of FIG. 51) at the upper end thereof, and a concave portion provided downward from the upper end surface of the thickened portion 2561a. Accommodating portion 2561b.

  The accommodation portion 2561b is a depression that is recessed in a state where the four sides are closed when viewed from above, and in a state where the moving member 540 is disposed at the extended position, the depression where the distal end portion of the bridging member 2528 is accommodated. It is. The inner side surface of the accommodation portion 2561b includes a mode in which the movement trajectory of the tip portion (the upper end portion in FIG. 51A) of the bridging member 2528 is included (the tip portion of the bridging member 2528 is moved while the moving member 540 is moving). (A form that does not come into contact with the inner side surface of the housing portion 2561b). This prevents the bridging member 2528 from abutting on the rotation-side inner surface of the drive-side arm member 2520 of the inner surface of the storage portion 2561b while moving the moving member 540 from the retracted position to the extended position. can do.

  As shown in FIG. 51B, the end of the bridging member 2528 is housed in the housing part 2561b in a state where the moving member 540 is arranged at the overhang position. Therefore, for example, when the driven arm member 530 moves to the front side (for example, falls down) to apply a load to the bridging member 2528, the resistance to the load can be improved.

  That is, when the tip of the bridging member 2528 is not accommodated in the accommodating portion 2561b, the bridging member 2528 is cantilevered and resists a load from the driven arm member 530 (a load facing the front side in FIG. 51). (The bridging member 2528 is fastened to the driving arm member 2520). On the other hand, when the distal end of the bridging member 2528 is housed in the housing portion 2561b, it is possible to generate a resisting force by supporting both ends with respect to the load from the driven arm member 530 (fastening with the driving arm 2520). Position and the receiving portion 2561b). Accordingly, it is possible to prevent the driven arm member 530 from moving to the front side.

  Further, since the bridging member 2528 is fastened and fixed to the driving arm member 2520, the front end of the bridging member 2528 is housed in the housing part 2561b, so that the positioning of the driving arm member 2520 in the front-rear direction is performed. be able to.

  In this case, the positioning of the moving members 540 of the swinging operation unit 2500 formed in a pair on the left and right can be performed in the front-rear direction, and the pair of moving members 540 are arranged at the extended position (see FIG. 8). In this case, it is possible to suppress the occurrence of relative displacement between the pair of moving members 540 in the front-rear direction. The accommodation portion 2561b is disposed at a position closer to the abutment position (see FIG. 8) between the pair of moving members 540 than the driving side arm member 2520, so that the moving members 540 generated from the accommodation portion 2561b as a starting point. Can be reduced.

  Thereby, the effect of correcting the displacement between the pair of moving members 540 can be ensured, and the effect of rendering the pair of moving members 540 integrally visible in a state where the pair of moving members 540 are arranged at the extended position. Can be improved.

  Next, a swing operation unit 3500 in the third embodiment will be described with reference to FIG. In the first embodiment, the case where the outer surface of the umbrella portion 523a of the drive side arm member 520 is formed in an arc shape has been described, but the swing operation unit 3500 in the third embodiment extends outward from the umbrella portion 523a. An overhang portion 3523b is provided. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIGS. 52A to 52C are front views of the swing operation unit 3500 in the third embodiment, and FIG. 52D shows the swing along the line Ld-Ld in FIG. 52B. It is sectional drawing of operation unit 3500. In FIG. 52, for ease of understanding, only the base member 3510, the driving arm member 3520, and the driving device 550 are illustrated, and other members are not illustrated, and the photo sensor 514 and the driving of the base member 3510 are not illustrated. Illustration of the sensor passage plate 524 of the side arm member 3520 is omitted.

  FIG. 52A shows a state in which the driving arm member 3520 and the moving member 540 (see FIG. 7) are arranged at the retracted position. In FIG. 52B, the driving arm member 3520 and the moving member 540 are shown. FIG. 52 (c) shows a state in which the drive side arm member 3520 and the moving member 540 (see FIG. 7) are arranged at the extended position. Is illustrated.

  As shown in FIG. 52, the drive-side arm member 3520 includes a projecting portion 3523b extending from the umbrella portion 523a outward in the axial direction. The overhang portion 3523b is disposed below the second shaft portion 512b regardless of the posture of the drive-side arm member 3520, and has a width between the outer peripheral wall 3516 and the second gear portion 553b of the transmission gear 553. It is formed with the above width (see FIG. 52B). That is, during the swinging operation of the drive-side arm member 3520, one of the outer peripheral wall 3516 and the second gear portion 553b of the transmission gear 553 is disposed on the rear side of the overhang portion 3523b.

  The base member 3510 includes an outer peripheral wall 3516 that is curved and formed along the outer circumference of the umbrella portion 523a on the outer side in the axial direction of the umbrella portion 523a. The outer peripheral wall 3516 protrudes from the front side of the main body 511 of the base member 3510 to the same height as the front side surface of the second gear portion 553b of the transmission gear 553 (see FIG. 52D).

  As a result, it is possible to prevent the drive-side arm member 3520 from moving forward (falling or bending) starting from the second shaft portion 512b of the shaft support portion 512 as a starting point. That is, the drive-side arm member 3520 moves (falls down or bends) to the front side above the second shaft portion 512b due to the weight of the moving member 540 (see FIG. 43), and moves below the second shaft portion 512b. Moves to the back side (falling down or bending). In this case, in addition to the umbrella portion 523a contacting the front side surface of the transmission gear 553, the overhang portion 3523b contacts the front end surface of the outer peripheral wall 3516. Thereby, the movement (tilting deformation or bending deformation) of the driving side arm member 3520 can be suppressed by contact at two positions.

  Further, as shown in FIG. 52 (c), when the drive side arm member 3520 is arranged at the extended position, the drive side arm member 3520 is compared with the case where the drive side arm member 3520 is arranged at another position. The contact position between the transmission shaft 3520 and the transmission gear 553 in the front-rear direction can be set at a position separated from the second shaft portion 512b in the shaft radial direction.

  That is, when the drive-side arm member 3520 is located at the overhang position, the umbrella portion 523a is opposed to the front side surface of the gear tooth portion of the second gear portion 553b, while the overhang portion 3523b is located at the second gear portion. 553b is disposed opposite to the front side surface of the main body. In this case, the overhang portion 3523b can abut on the main body portion of the second gear portion 553b in the front-rear direction. Such an arrangement is not seen in FIGS. 52 (a) and 52 (b).

  Further, the state in which the drive side arm member 3520 is disposed at the overhang position is such that the longitudinal direction of the drive side arm member 3520 runs along the up and down direction. This is a state in which movement in the front-rear direction (tilting deformation or bending deformation) tends to occur with a large width. In the present embodiment, as described above, the contact position between the drive-side arm member 3520 and the transmission gear 553 in the front-rear direction can be set at a position separated from the second shaft portion 512b in the shaft radial direction. The resistance to the movement of the 3520 in the front-rear direction can be increased, and the movement can be suppressed.

  Next, a composite operation unit 4400 according to the fourth embodiment will be described with reference to FIGS. In the first embodiment, the case has been described where the guide hole 424b of the guide plate 424 is a smooth long hole without being caught. However, the combined operation unit 4400 in the fourth embodiment has a concave portion on the upper side surface of the guide hole 4424b. 4424c is formed. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 53 is a front view of the combined operation unit 4400 according to the fourth embodiment in a state where the main body member 410 is disposed at the intermediate position. 53 and 54, the illustration of the collar member of the slide shaft portion 423e is omitted, and the shaft portion is made visible.

  As shown in FIG. 53, when the main body 410 of the combined operation unit 4400 moves down from the retracted position and is located at the intermediate position, the slide shaft 423e of the connecting member 423 contacts the inner end of the guide hole 4424b. Touch A recess 4424c, which is a recess capable of accommodating a part of the slide shaft portion 423e, is formed on the upper side surface of the guide hole 4424b disposed right above the contact position. The concave portion 4424c is formed in an arc shape, and the radius of curvature of the concave portion 4424c is formed to be equal to or larger than the radius of the slide shaft portion 423e.

  Here, when the main body member 410 moves downward from the retracted position, the shaft support hole 423d arranged at the end of the connecting member 423 opposite to the slide shaft 423e moves in the vertical direction. Therefore, when the slide shaft portion 423e of the connecting member 423 comes into contact with the inner end of the guide hole 4424b and rebounds, the shaft support hole 423d rebounds in the vertical direction. Therefore, the slide shaft portion 423e also rebounds upward due to the upward rebound momentum.

  With reference to FIG. 54, the effect of the concave portion 4424c will be described. FIGS. 54A and 54B are partial front views of the composite operation unit 4400. FIG. FIG. 54A shows a state immediately before the slide shaft 423e of the connecting member 423 comes into contact with the inner end of the guide hole 4424b. In FIG. 54B, the slide shaft 423e of the connecting member 423 is The state immediately after contacting the inner end of the guide hole 4424b is illustrated. In FIG. 54, the slide lever 473, the solenoid 474, the wiring guide arm 480, and the like are omitted for easy understanding, and the slide shaft 423e and the direction of movement of the opposite end of the slide shaft 423e. Are shown by arrows C41 to C44.

  As shown in FIG. 54 (a), when the main body member 410 is moved downward and the opposite end of the connecting member 423 on the opposite side of the slide shaft 423e is moved downward along the arrow C42, the slide shaft is moved. 423e contacts the lower side surface of the guide hole 4424b and slides along the arrow C41. Therefore, the slide shaft portion 423e is not accommodated in the recessed portion 4424c.

  On the other hand, as shown in FIG. 54 (b), the slide shaft 423e abuts against the inner end of the guide hole 4424b and rebounds, and the end of the connecting member 423 on the side opposite to the slide shaft 423e follows the arrow C44. In the case of bouncing upward, the slide shaft 423e is also pressed upward. In this case, the slide shaft portion 423e contacts the upper side surface of the guide hole 4424b and tries to slide along the arrow C43. Therefore, the slide shaft portion 423e is housed in the concave portion 4424c.

  Therefore, the slide shaft portion 423e and the concave portion 4424c can be brought into contact with each other in the left-right direction that is the long direction of the guide hole 4424b. In this case, a large resistance can be generated for the slide shaft portion 423e that is moving in the long direction of the guide hole 4424b.

  Accordingly, it is possible to prevent the slide shaft portion 423e from moving along the left and right directions of the guide hole 4424b. Therefore, the rebound width of the slide shaft portion 423e can be reduced, and the arrangement of the shielding member 420 can be stabilized. By moving the main body member 410 (see FIG. 21) upward by the driving device 460, the slide shaft 423e is driven inside the guide hole 4424b in the left-right direction.

  Next, a composite operation unit 5400 in the fifth embodiment will be described with reference to FIGS. In the first embodiment, the case where the end on the slide shaft 423e side of the connecting member 423 is in contact with only the guide plate 424 has been described. A leaf spring member 5425, which is a plate-shaped spring member, which is in contact with the end on the shaft portion 423e side, is formed. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 55 is a rear view of the combined operation unit 5400 according to the fifth embodiment in a state where the main body member 410 is located at the retracted position. As the main body member 410 moves downward from the retracted position, the slide shaft 423e of the connecting member 5423 moves in the left and right direction inside the guide hole 424b of the guide plate 5424.

  The connecting member 5423 includes a protruding portion 5423f that protrudes from an end of the rod member 423a on the slide shaft portion 423e side. The protruding portion 5423f is protruded vertically upward in a state where the slide shaft portion 423e of the connecting member 5423 is disposed at an inner end portion of the guide hole 424b, and also has a right side in rear view (FIG. 56 (c)). The right corner is rounded and the left corner in rear view is formed at a right angle.

  The guide plate 5424 is provided with a grip portion 5424c projecting in a U-shape on the rear side of the base plate 424a at the upper outer ends of the pair of guide holes 424b. The holding portion 5424c is formed in such a manner that the open side of the U-shaped portion is directed inward in the left-right direction, and one end of the leaf spring member 5425 is sandwiched by the inner surface of the U-shaped portion.

  The details of the leaf spring member 5425 will be described with reference to FIG. FIGS. 56A to 56C are partial rear views of the composite operation unit 5400. FIG. 56 (a) to 56 (c), the movement of the connecting member 5423 is illustrated in chronological order, and the periphery of the guide hole 424b on the left side in rear view is partially illustrated. ) Shows a state in which the main body member 410 (see FIG. 55) is arranged at the retreat position, and FIG. 56B shows a state in which the main body member 410 has moved a predetermined distance from the retreat position to the intermediate position. In c), the state in which the main body member 410 is disposed at the intermediate position is illustrated.

  56, only the decorative member 422, the connecting member 5423, the guide plate 5424, and the leaf spring member 5425 are illustrated in FIG. 56, and other members are not illustrated. Further, only the outer shape of the decorative member 422 and the connecting member 5423 is illustrated, and illustration of the internal pattern and the like is omitted.

  As shown in FIG. 56 (a), the leaf spring member 5425 is disposed in a posture in which the elongate direction is directed to the left and right, and one end portion is a fixed portion 5425a having a shape of a straight plate that is gripped by the grip portion 5424c. And a curved portion 5425b which is connected to the other end of the fixed portion 5425a and protrudes toward the connecting member to form a curved portion, and from the end inside the curved portion 5425b (the right side in FIG. 56 (a)) in the left-right direction. And a fall prevention part 5425c extended to the main part.

  The curved portion 5425b is formed such that the first inclined surface 5425b1 formed on the outside in the left-right direction and the second inclined surface 5425b2 formed on the inside in the left-right direction have different inclination angles with respect to the left-right direction. That is, the first inclined surface 5425b1 is gently inclined from the left and right direction (the inclination angle is reduced), and the second inclined surface 5425b2 is rapidly inclined from the left and right direction (the inclination angle is increased to near a right angle).

  The fall prevention portion 5425c is in contact with the upper end of the protruding portion 5423f in a state where the slide shaft portion 423e of the connecting member 5423 is disposed at the inner end (right side in FIG. 56A) of the guide hole 424b. Accordingly, even if the end of the leaf spring member 5425 on the opposite side to the gripping portion 5424c may drop downward due to aging or the like, in the state of FIG. 56 (c), the protruding portion 5423f causes the leaf spring member 5425 to move. By lifting, the positional relationship between the leaf spring member 5425 and the protruding portion 5423f can be maintained. That is, it is possible to prevent the end of the leaf spring member 5425 on the opposite side of the grip portion 5424c from hanging downward.

  Here, a change in the direction of the force generated between the projecting portion 5423f and the leaf spring member 5425 during the movement of the connecting member 5423 will be described. When the slide shaft portion 423e of the connecting member 5423 is disposed at the left end of the guide hole 424b, the projecting portion 5423f and the leaf spring member 5425 are separated from each other. No force is generated (see FIG. 56 (a)).

  As the slide shaft portion 423e of the connecting member 5423 moves inward in the left-right direction of the guide hole 424b (the right side in FIG. 56 (a)), the posture of the connecting member 5423 changes, and the protruding portion 5423f is attached to the leaf spring member 5425. It gradually approaches and comes into contact soon (see FIG. 56 (b)). Subsequently, the connecting member 5423 moves inward in the left-right direction, and the upper end of the protruding portion 5423f is gradually moved upward, so that the free end side of the leaf spring member 5425 (the right end side in FIG. 56B). The edge gradually moves upward.

  When the projecting portion 5423f and the first inclined surface 5425b1 of the curved portion 5425b of the leaf spring member 5425 are in contact with each other, the force F51 applied to the leaf spring member 5425 from the projecting portion 5423f is applied to the first inclined surface 5425b1 of the curved portion 5425b. It propagates in the normal direction of. That is, the force F51 is directed to the thickness direction of the leaf spring member 5425, that is, the direction in which the leaf spring member 5425 is bent. In this case, of the force applied to the connecting member 5423 as a reaction of the force F51, the component directed to the left and right is small, so that when the slide shaft portion 423e of the connecting member 5423 moves to the right, the leaf spring member 5425 The hindrance of the movement of the connecting member 5423 is suppressed. Thus, while the main body member 410 (see FIG. 55) reaches the intermediate position, the insertion shaft portion 421c (see FIG. 55) is maintained at the lower end of the guide hole 413 (see FIG. 55). can do.

  When the slide shaft portion 423e of the connecting member 5423 reaches the inner end in the left-right direction of the guide hole 424b (the right end in FIG. 56 (c)) and rebounds, the projecting portion 5423f becomes the curved portion 5425b of the leaf spring member 5425. (See FIG. 56 (c)).

  In this case, the force F52 applied from the protruding portion 5423f to the leaf spring member 5425 is transmitted in the normal direction of the second inclined surface 5425b2 of the curved portion 5425b. That is, the force F52 has a large component directed in the longitudinal direction of the leaf spring member 5425, that is, in the longitudinal direction of the leaf spring member 5425.

  Here, the leaf spring easily undergoes elastic deformation in the thickness direction, but elastic deformation in the longitudinal direction of the leaf spring hardly occurs. In the present embodiment, the direction of the force F52 can be directed to the longitudinal direction of the leaf spring member 5425 by increasing the inclination angle of the right side surface of the curved portion 5425b to near a right angle to the left-right direction. Thus, the resistance of the leaf spring member 5425 to the rebound of the connecting member 5423 can be increased, and the movement of the connecting member 5423 can be prevented. Therefore, the connecting member 5423 can be maintained at the inner end (the right side in FIG. 56 (c)) of the guide hole 424b.

  Further, as described above, the protruding portion 5423f is formed such that the corner on the right side in the rear view (the right side in FIG. 56 (c)) is rounded and the corner on the left side in the rear view is formed at a right angle. Thereby, when the right corner of the protruding portion 5423f in rear view comes into contact with the leaf spring member 5425 (see FIG. 56 (b)), the protruding portion 5423f contacts smoothly (without biting) the left side of the protruding portion 5423f in rear view. When the corner comes into contact with the leaf spring member 5425 (see FIG. 56C), the projecting portion 5423f bites into the leaf spring member 5425. That is, the left-side corner of the protruding portion 5423f is fitted between the second inclined surface 5425b2 of the leaf spring member 5425 and the fall prevention portion 5425c.

  By moving the main body member 410 (see FIG. 55) upward by the driving device 460 (see FIG. 21), the slide shaft 423e is driven inside the guide hole 4424b in the left-right direction. In this case, the projecting portion 5423f moves by pushing the curved portion 5425b of the leaf spring member 5425.

  Next, a composite operation unit 6400 according to the sixth embodiment will be described with reference to FIGS. In the first embodiment, the case where the wiring guide arm 480 that guides the wiring is expanded and contracted by folding is described. However, the composite operation unit 6400 according to the sixth embodiment can expand and contract the wiring guide slide 6480 that guides the wiring by sliding movement. Formed. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 57 is a partial front view of the combined operation unit 6400 according to the sixth embodiment in a state where the main body member 410 is located at the extended position. In FIG. 57, the extended state of the wiring guide slide 6480 is illustrated. In the extended state of the wiring guide slide 6480, the wiring W provided inside the wiring guide slide 6480 has almost no bent portions and is formed substantially linearly. Therefore, the required length of the wiring W can be suppressed.

  The wiring guide slide 6480 is pivotally supported about a shaft support 472 and supported by a first guide slide 6481 through which the wiring W is inserted, and a sliding elongated hole 6481b of the first guide slide 6481 in the extending direction. A second guide slide 6482 that slides along and has a wire W inserted therein, and a third guide that slides along the extending direction of the elongated slide hole 6482b of the second guide slide 6482 and has the wire W inserted therein. And a slide 6483.

  The first guide slide 6481 has a rectangular cylindrical main body 6481a in which a substantially rectangular through hole 6481a1 is formed in the longitudinal direction, and a pair of side surfaces (front and rear) which are opposed to each other among the side surfaces of the main body 6481a. And a pair of slide long holes 6481b formed in the longitudinal direction of the main body 6481a, and a shaft support 472 penetrated in the front-rear direction at the end of the main body 6481a. It mainly includes a shaft support hole 6481c, and a cylindrical column portion 6481d that is bridged in the front-rear direction at the lower end of the through hole 6481a1 of the main body portion 6481a.

  The extending direction of the slide elongated hole 6481b and the lower side surface (the left side surface in FIG. 57) of the main body 6481a are formed in parallel. The wiring W is wound around the cylindrical portion 6481d from below.

  The second guide slide 6482 has a rectangular cylindrical main body 6482a in which a substantially rectangular through hole 6482a1 is formed in a slidable manner inside the through hole 6481a1 of the first guide slide 6481, and the main body 6482a. A pair of sliding long holes 6482b formed facing the pair of side surfaces (side surfaces arranged front and rear) facing each other among the side surfaces of the main body portion 6482a, and a main body portion 6482a And a pair of projecting portions 6482c that are projected outward from the front and rear side surfaces of the first guide slide 6481 and inserted into the elongated slide holes 6481b of the first guide slide 6481.

  The extending direction of the slide elongated hole 6482b and the lower side surface (the left side surface in FIG. 57) of the main body 6482a are formed in parallel. The protruding portion 6482c is formed in a cylindrical shape having a diameter slightly smaller than the width of the slide elongated hole 6481b.

  The second guide slide 6482 has a protruding portion 6482c formed so as to be slidable inside the elongated slide hole 6481b of the first guide slide 6481. During the movement, the outer surface of the second guide slide 6482 is connected to the main body 6481a. Of the through hole 6481a1. That is, the distance from the central axis of the slide elongated hole 6481b of the first guide slide 6481 to the inner surface of the lower side surface (the left side surface in FIG. 57) of the main body 6481a is equal to the distance from the central axis of the projecting portion 6482c to the main body portion 6482a. It is formed substantially equal to the distance from the lower side surface to the outer side surface. Accordingly, when the second guide slide 6482 is slid with respect to the first guide slide 6481, the posture of the second guide slide 6482 can be stabilized.

  The third guide slide 6483 is fitted inside the through hole 6482a1 of the second guide slide 6482 so as to be slidable and has a substantially rectangular through hole 6483a1 formed in the longitudinal direction. And a pair of projecting portions 6483b projecting outward from the front and rear side surfaces of the portion 6483a and inserted through the elongated slide hole 6482b of the second guide slide 6482.

  The third guide slide 6483 has a projecting portion 6483b formed so as to be slidable inside the elongated slide hole 6482b of the second guide slide 6482. During the movement, the outer surface of the third guide slide 6483 is connected to the main body 6482a. Of the through hole 6482a1. That is, the distance from the central axis of the slide elongated hole 6482b of the second guide slide 6482 to the inner surface of the lower side surface (the side surface on the left side in FIG. 57) of the main body portion 6482a is equal to the distance from the central axis of the protruding portion 6483b to the main body portion 6483a. It is formed substantially equal to the distance from the lower side surface to the outer side surface. Accordingly, when the third guide slide 6483 is slid with respect to the second guide slide 6482, the posture of the third guide slide 6482 can be stabilized.

  Here, while the inner surface of the first guide slide 6481 and the outer surface of the second guide slide 6482 are formed as smooth surfaces, the inner surface of the second guide slide 6482 and the outer surface of the third guide slide 6483 are different from each other. It is formed with a rough surface. In this case, the frictional resistance of the sliding movement of the second guide slide 6482 with respect to the first guide slide 6481 is formed smaller than the frictional resistance of the sliding movement of the third guide slide 6483 with respect to the second guide slide 6482.

  As a result, the second guide slide 6482 slides prior to the third guide slide 6483. That is, when the main body member 410 moves upward from the state of FIG. 57, the second guide slide 6482 is first stored in the first guide slide 6481, and after the storage is completed, the second guide slide 6482 is moved in the third guide slide 6482. 6483 are stored.

  FIGS. 58A and 58B are partial front views of the composite operation unit 6400. FIG. 58A illustrates a state where the main body member 410 is disposed at the intermediate position (see FIG. 30), and FIG. 58B illustrates a state where the main body member 410 is disposed at the retracted position. You.

  As shown in FIG. 58, the wiring guide slide 6480 does not include a portion where the wiring W may be pinched, so that the wiring W can be prevented from being disconnected. Further, since there is no possibility of sandwiching the wiring W, the arrangement interval between the wiring W and the inner surface of each guide slide 6481, 6482, 6483 can be reduced. Thereby, the width of the wiring guide slide 6480 in the short direction can be suppressed.

  In a state where the main body member 410 is arranged at the intermediate position, the wiring W remains inside the wiring guide slide 6480 (see FIG. 58A). Therefore, it is possible to temporarily remove the tension applied to the wiring W.

  Next, a swing operation unit 7500 according to a seventh embodiment will be described with reference to FIG. In the first embodiment, the case where the pair of bridging members 528 is fixed to the drive-side arm member 520 has been described. However, the swing operation unit 7500 according to the seventh embodiment includes the first bridge of the pair of bridging members 7528. The bridging member 7528a is formed to be swingable with respect to the driving arm member 7520. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIGS. 59A and 59B are partial front views of the swing operation unit 7500 in the seventh embodiment. Note that FIG. 59 (a) illustrates a state where the moving member 540 is arranged at the retracted position, and FIG. 59 (b) illustrates a state where the moving member 540 is arranged at the extended position. Is illustrated by imaginary lines.

  As shown in FIG. 59 (a), the first bridging member 7528a, which is the smaller side of the pair of bridging members 7528, is inserted into a shaft support hole 7529 formed in the main body plate portion 7521 of the driving arm member 7520. It is pivotally supported and is urged clockwise in a front view by a torsion spring (not shown). Note that the main body plate portion 521 is different from the main body plate portion 521 in the first embodiment except that the formation of the first fastening holes 527a1 corresponding to the first bridging members 7528a is omitted and a shaft support hole 7529 is formed instead. It is formed similarly. The second bridging member 7528b, which is the larger side of the pair of bridging members 7528, is fastened and fixed to the main body plate portion 7521 of the driving arm member 7520.

  The driven arm member 7530 has a projecting portion 7534 projecting from the front side of the main body plate portion 531 and abutting on the first bridging member 7528a in the swing direction.

  Here, when the driving side arm member 7520 and the driven side arm member 7530 are disposed at the retracted position and at the extended position, the relative position of the projecting portion 7534 with respect to the shaft support hole 7529 is determined. The position changes (the position changes similarly to the relative movement of the other-side shaft support hole 526 and the other-side shaft support hole 533 along the longitudinal direction of the drive-side arm member 7520).

  By swinging the first bridging member 7528a along the projecting portion 7534, the distance between the first bridging member 7528a and the second bridging member 7528b at the extended position (see FIG. 59B) is increased. Can be spread. Accordingly, when the driven-side arm member 7530 bends to the front side, the distance between the positions where the bridge member 7528 can abut (the end of the first bridge member 7528a and the end of the second bridge member 7528b). Can be expanded. In this case, the length in the longitudinal direction in which the driven side arm member 7530 can flex freely without being in contact with the bridging member 7528 can be divided into shorter portions, and the amount of bending of the driven side arm member 7530 (in the longitudinal direction) Movement amount) can be suppressed.

  As shown in FIG. 59, the distance between the first bridging member 7528a and the other-side shaft support hole 533 can be maintained regardless of whether the moving member 540 is located at the retracted position or the extended position. it can. Here, the displacement of the driven-side arm member 7530 with respect to the drive-side arm member 7520 is likely to occur in the other-side shaft support hole 533 which is the connection position with the moving member 540, and the displacement width is likely to be large. In the present embodiment, the first bridge member 7528a can be prevented from separating from the other-side shaft support hole 533, and the effect of suppressing the displacement of the driven arm member 7530 with respect to the drive arm member 7520 can be increased. Can be.

  When the drive-side arm member 7520 and the driven-side arm member 7530 are disposed at the retracted position (see FIG. 59A), the first bridge member 7528a is biased by a torsion spring (not shown). It swings in the direction approaching the second bridge member 7528b. As a result, the drive-side arm member 7520 is moved to the retracted position while the distance between the first bridge member 7528a and the second bridge member 7528b is increased, and the first bridge member 7528a and the other-side shaft support hole 533 are moved. Can be prevented from interfering with each other.

  Next, a game board 8013 according to the eighth embodiment will be described with reference to FIGS. In the first embodiment, the case where light is irradiated from the light irradiation device 331c to the specific winning opening 65a has been described. However, the game board 8013 according to the eighth embodiment has an outer rail formed by being planted on the base plate 8060. Light is radiated to the vicinity of the upper half of 62. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 60 is a front view of a game board 8013 according to the eighth embodiment. As shown in FIG. 60, since the light irradiation device 8610 is disposed outside the outer rail 62, the degree of freedom of decoration of the game area is reduced by a shielding member for partially hiding the light irradiation device 8610. Can be prevented. In addition, since the light irradiation device 8610 is provided in the embedding hole 8013a formed in the game board 8013, it is possible to prevent the light irradiation device 8610 from increasing the thickness of the game board 8013 in the front-rear direction.

  The light irradiating device 8610 irradiates light inside the game area through the back side of the outer rail 62. A mechanism for changing the traveling direction of the irradiated light to the front side (the front side in FIG. 60) will be described with reference to FIG.

  FIG. 61 is a partial sectional view of the game board 8013 taken along the line LXI-LXI in FIG. As shown in FIG. 61, the light irradiation device 8610 mainly includes a main body 8611 fixed to the embedding hole 8013a, and a light irradiation unit 8612 disposed on a side surface of the main body 8611.

  The game board 8013 is formed of a light-transmissive resin material, and has a buried hole 8013a in which the light irradiation device 8610 is provided, and a lower portion (from the buried hole 8013a along the back surface of the game board 8013 and beyond the outer rail 62). A light projecting passage 8013b, which is a concave portion extending to the inside of the game area, and a mode formed at an extended end of the light projecting path 8013b, the closer to the front side as it goes downward (inward of the game area). And a direction change portion 8013c formed in an inclined manner.

  The embedding hole 8013a, the light projecting passage 8013b, and the direction changing portion 8013c can be formed by processing such as cutting and drilling, or by forming a protrusion having an appropriate shape in a resin mold.

  The path E81 of the light emitted from the light irradiating section 8612 is formed inside the light projecting path 8013b, reaches the direction changing section 8013c and is reflected, so that the traveling direction of the light is from the path E81 to the front side (FIG. 61). The route changes to the route E82 (to the left). Here, since the direction change portion 8013c for changing the traveling direction of light is formed by the game board 8013 formed of a light-transmissive resin material, the direction change portion 8013c is inconspicuous and may have a small effect on the decoration of the game area. it can. Thus, the degree of freedom in designing the game area can be improved.

  As shown in FIG. 61, the light traveling on the route E82 is applied from below to a nail implanted in front of the game board 8013. Thereby, the shadow formed below the nail by the illumination of the hall can be brightened. Therefore, it is possible to improve the performance ability in the area below the nail, and to make it easier to see the ball when the ball passes through the area below the nail, thereby reducing the burden felt by the player due to the difficulty in viewing the ball. be able to.

  In particular, the nails implanted on the upper part of the game board 8013 are arranged at positions where the nails are looked up from the player, so that light is radiated from below the nails to direct the light reflected by the nails to the player. be able to. In this way, the nail that defines the flow path of the sphere can be used as a member for producing light.

  The lower part (lower half) of the nail is less likely to collide with the ball, so that even if it is processed, the influence on the flow of the ball is small. For example, by processing the lower part (lower half) of the nail in a crystal shape, light can be reflected in a plurality of directions, and the performance of the nail can be enhanced.

  Further, by setting the color of the light emitted from the light irradiating unit 8612 to a color (for example, red) different from the color of the nail (for example, yellow), it is possible to distinguish between the nail that has been irradiated and other nails. Can be made easier.

  In this case, for example, a plurality of light irradiation devices 8610 (six in this embodiment, see FIG. 60) may be arranged on the game board 8013, and light may be irradiated in order. That is, after the light is irradiated from the light irradiation device 8610 at the left end in front view, the light is irradiated from the light irradiation device 8610 on the right (the second from the left end in front view), and then the light is irradiated on the right (front) Light may be emitted from the light irradiation device 8610 (third from the left end when viewed), and may continue thereafter.

  According to this, the nails implanted in the game board 8013 glow in order along the curved arrow R81 by the light emitted from the light irradiation device 8610. For example, in a case where it is more advantageous for the player to perform right-handing, the nails implanted in the game board 8013 are sequentially illuminated along the curved arrow R81 so that the player performs right-handing. Can be signaled. Thereby, the nail that forms the flow path of the ball is given an effect of telling the player where to hit the ball, so that the attention power of the nail can be improved.

  Note that the light irradiated from the light irradiation device 8610 is not necessarily limited to the nail. For example, light may be applied to a windmill provided on the game board 8613, the through gate 67 (see FIG. 60), or the like.

  Next, a wiring guide arm 9480 in the ninth embodiment will be described with reference to FIGS. In the first embodiment, the case where the first guide arm 481 and the second guide arm 482 of the wiring guide arm 480 do not overlap in the front-rear direction except for the pivot portion, but the wiring guide arm 9480 in the ninth embodiment is different from the first embodiment. The second front arm 9482f disposed on the second guide arm 9482 overlaps the first guide arm 9481 in the front-rear direction. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted. 62 to 64, illustration of the enlarged diameter portion 481c1 and the reduced diameter portion 482b1 is omitted for easy understanding.

  FIG. 62 (a) is a front view of the first guide arm 9481 in the ninth embodiment, FIG. 62 (b) is a bottom view of the first guide arm 9481, and FIG. It is a perspective view of locking member 9481f. In FIG. 62A, the detachable front locking member 9481f is partially viewed in cross section, and the fitting portion between the attachment portion 9481d and the removable front locking member 9481f can be visually recognized.

  As shown in FIG. 62 (a), the first guide arm 9481 includes a detachable front locking member 9481f formed so as to be detachable from the attachment portion 9481d, and a plate-like arm portion 9481a from both ends of the linear portion of the attachment portion 9481d. It mainly includes a plate-shaped non-slip plate portion 9481g extending toward the rear side and an other-side auxiliary bottom portion 9481h extending from the back side of the other-side bottom portion 481e2.

  The notch 481a1 (see FIG. 25A) of the plate-shaped arm 9481a is omitted. In the present embodiment, since the detachable front locking member 9481f is molded separately from the attachment portion 9481d as described later, the notch portion 481a1 is unnecessary. Thereby, the strength of the plate-shaped arm portion 9481a can be secured.

  As shown in FIG. 62A, the attachment portion 9481d includes a fitting recess 9481d1 which is a semicircular recess extending in the front-rear direction.

  The fitting dent 9481d1 is a semicircular dent into which a cylindrical fitting arm 9481f2 of a detachable front locking member 9481f described later is fitted, and has a short side direction of the attachment part 9481d (FIG. 62 (a) perpendicular to the sheet surface). Direction). Thus, a shape for the fitting recess 9481d1 is added to the molding die of the fitting portion 9481d, and the fitting portion 9481d1 is pulled out in one direction (the direction perpendicular to the paper surface of FIG. 62A), whereby the fitting recess 9481d1 is formed. 9481d can be easily manufactured.

  The fitting recess 9481d1 is formed in a semicircular shape having a radius equal to or slightly smaller than the radius of the fitting arm 9481f2. Thereby, the fitting arm portion 9481f2 can be fitted into the fitting recess 9481d1, and the sliding movement of the detachable front locking member 9481f in the longitudinal direction of the attachment portion 9481d can be suppressed.

  In this case, the contact area with respect to the thickness of the fitting arm 9481f2 can be increased as compared with the case where the attachment portion 9481d and the fitting arm 9481f2 abut on each other, and the frictional force can be increased. Can be. Accordingly, it is possible to prevent the detachable front locking member 9481f from dropping off from the attachment portion 9481d.

  As shown in FIG. 62 (c), the detachable front locking member 9481f includes a long plate-shaped main body plate 9481f1 and a plurality of columns extending vertically from the side in the thickness direction of the main body plate 9481f1. And a fitting arm 9481f2.

  Since the detachable front locking member 9481f can be detached from the attachment portion 9481d, when the wiring W is replaced, for example, when the wiring W is disconnected, the detachable front locking member 9481f is detached to allow the detachable front locking. The trouble of replacing the wiring W while avoiding the member 9481f can be omitted, and the replacement of the wiring W can be facilitated.

  The plurality of fitting arms 9481f2 are portions for fixing the detachable front locking member 9481f to the attachment portion 9481d by sandwiching the attachment portion 9481d, and are juxtaposed at intervals slightly shorter than the plate thickness of the attachment portion 9481d. A pair of bar-shaped members are continuously provided in two sets. When the detachable front locking member 9481f is fixed to the attachment portion 9481d, the pair of rod-shaped members of the plurality of fitting arms 9481f2 are elastically deformed by being pushed from the attachment portion 9481d, and the attachment portion is elastically restored by the elastic recovery force. 9481d.

  Note that the length of the fitting arm 9481f2 is formed slightly longer than the length of the attachment portion 9481f in the width direction, and the tip of the fitting arm 9481f2 is directed toward the mating arm 9481f2 of the mating side that sandwiches the attachment 9481f. A protruding portion 9481f3 is formed. Since the projecting portion 9481f3 is hooked on the attachment portion 9481f, it is possible to prevent the detachable front locking member 9481f from coming off the attachment portion 9481f to the front side (the front side in FIG. 62A).

  In this case, since the fitting arm 9481f2 is formed in a columnar shape and the fitting recess 9481d1 is formed as a recess having a semicircular cross section, when the fitting arm 9481f2 holds the attachment portion 9481d with elastic recovery force. The axial center of the fitting arm 9481f2 is moved to the center of the fitting recess 9481d1. This facilitates positioning when the detachable front locking member 9481f is attached to the attachment portion 9481d, and shortens the time required for attachment.

  The non-slip plate portion 9481g is a portion for holding the wiring W between the plate-like arm portion 481a and is formed continuously over the width direction of the attachment portion 9481d (the vertical direction in FIG. 62B). The attachment portion 9481d and the plate-shaped arm portion 481a can be elastically deformed in the thickness direction. The gap between the tip end of the anti-slip plate portion 9481g and the plate-shaped arm portion 481a is usually formed so as to have a thickness equal to or less than the thickness of the wiring W, and the anti-slip plate portion 9481g is inserted by inserting the wiring W therethrough. The wire W is elastically deformed, and the elastic recovery force suppresses the wiring W from sliding with respect to the plate-shaped arm portion 481a.

  The direction of the non-slip plate portion 9481g is elastically deformable along the longitudinal direction of the attachment portion 9481d. Thereby, the wiring W can be sandwiched between the non-slip plate portion 9481d and the plate-shaped arm portion 481a in the width direction, and the wiring W can be suppressed from moving and rubbing in the longitudinal direction of the attachment portion 9481d. The durability of the wiring W can be improved.

  The directions of the pair of non-slip plate portions 9481g are opposite to each other at both ends of the attachment portion 9481d. Thereby, regardless of the moving direction of the wiring W, it is possible to suppress the attachment portion 9481d and the wiring W from moving in the longitudinal direction of the attachment portion 9481d. The non-slip plate portion 9481g is arranged to face the rib portion N. Accordingly, the wiring W can be suppressed not at the tip end of the anti-slip plate portion 9481g but at the middle part (antinode), so that the resistance applied to the wiring W can be increased (see FIG. 64).

  The other-side auxiliary bottom portion 9481h is a plate-shaped portion having the same outer peripheral shape as the other-side bottom portion 481e2. The other-side auxiliary bottom portion 481c2 extends in the circumferential direction of the other-side cylindrical portion 481c from the back surface of the other-side bottom portion 481e2. And about 120 degrees, and has an inclined side surface 9481h1 at the extension end. As shown in FIG. 64 (a), the extending distal end of the other-side auxiliary bottom 9481h and the end of the one-side bottom 482e1 of the second guide arm 9482 overlap in a front view. Accordingly, it is possible to prevent the wiring W from dropping to the back side (the back side in FIG. 64A).

  The inclined side surface 9481h1 is inclined to the rear side (downward in FIG. 62 (b)) as the distance from the other side bottom portion 481e2 increases.

  FIG. 63 (a) is a front view of the second guide arm 9482, FIG. 63 (b) is a bottom view of the second guide arm 9482, and FIG. 63 (c) is LXIIIc of FIG. 63 (a). It is sectional drawing of the 2nd guide arm 9482 in the -LXIIIc line.

  As shown in FIG. 63 (a), the second guide arm 9482 includes a projecting front locking portion 9482f extending from the front end of the attachment portion 482d in both directions in the thickness direction of the attachment portion 482d, and an attachment portion. 482d and a non-slip plate portion 9482g extending from the end of the linear portion of the plate-shaped arm portion 482a to the plate-shaped arm portion 482a and the attachment portion 482d that are arranged to face each other.

  The overhanging front locking portion 9482f is attached to the extension end portion extending on the opposite side of the plate-like arm portion 482a with the attachment portion 482d interposed therebetween, and the rear side (FIG. 63) as the extension tip approaches the attachment portion 482. (C) An inclined side surface 9482f1 inclined to the right side is provided.

  Since the technical idea of the anti-slip plate portion 9482g is the same as the technical idea of the anti-slip plate portion 9481g, the description is omitted here.

  FIGS. 64 (a) and 64 (b) are front views of the first guide arm 9481 and the second guide arm 9482 of the wiring guide arm 9480, and FIG. 64 (c) is the LXIVc- of FIG. 64 (a). It is sectional drawing of the 1st guide arm 9481 and the 2nd guide arm 9482 of the wiring guide arm 9480 in the LXIVc line. FIG. 64A illustrates a state where the first guide arm 9481 and the second guide arm 9482 are folded, and FIG. 64B illustrates a state where the first guide arm 9481 and the second guide arm 9482 are pivoted and opened. The state where it was put is illustrated. 64 (a) and 64 (b) show the wiring W, and FIG. 64 (c) does not show the wiring W.

  Here, in order to secure an arrangement area for other movable members, it is desirable to suppress the arrangement area of the wiring guide arm 9480. Therefore, it is difficult to provide a margin in a region for accommodating the wiring W (for example, between the plate-shaped arm portion 481a and the attachment portion 9481d of the first guide arm 9481). In this case, when the wiring guide arm 9480 is folded or opened, each time the state changes, the wiring W rubs against the inner side surface of the wiring guide arm 9480, and the wiring W deteriorates early, and the durability of the wiring W decreases. May drop.

  On the other hand, in the wiring guide arm 9480 according to the present embodiment, the wiring W is sandwiched between the non-slip plates 9481g and 9482g and the plate-shaped arms 481a and 482a, so that the wiring W is connected to the plate-shaped arms 481a. , 482a and attachment portions 9481d, 482d. Thereby, the durability of the wiring W can be ensured.

  Further, when the second guide arm 9482 is deformed in a twisted manner with respect to the first guide arm 9481, the wiring W may be twisted, and the durability of the wiring W may be reduced.

  On the other hand, in the wiring guide arm 9480 according to the present embodiment, when the first guide arm 9481 and the second guide arm 9482 are opened (see FIG. 64B), the other side auxiliary bottom portion 9481h is connected to the second guide arm. 9482 overlaps with one side bottom portion 482e1 in the front-rear direction. Here, the other-side auxiliary bottom portion 9481h extends in the circumferential direction of the other-side cylindrical portion 481c along the back surface of the other-side bottom portion 481e2 (see FIG. 62B).

  Therefore, in a state where the first guide arm 9481 and the second guide arm 9482 are opened (see FIG. 64B), the other side auxiliary bottom portion 9481h and the one side bottom portion 482e1 are in a positional relationship in which they can abut in the front-rear direction. It is formed. That is, when the second guide arm 9482 is twisted and deformed against the first guide arm 9481 in a direction of pressing the one bottom 482e1 against the other auxiliary bottom 9481h, the one bottom 482e1 and the other auxiliary bottom 9481h are abutted. In addition, the deformation resistance of the torsional deformation increases. In this case, the first guide arm 9481 and the second guide arm 9482 can be suppressed from being twisted. Therefore, the wire W can be prevented from being twisted and deformed, and the durability of the wire W can be ensured.

  In the present embodiment, in a state where the first guide arm 9481 and the second guide arm 9482 are folded (see FIG. 64 (a)), the overhanging front locking portion 9482f moves forward and backward with the attachment portion 9481d of the first guide arm 9481. It overlaps in the direction and is formed in a positional relationship capable of abutting in the front-rear direction (see FIG. 64C). That is, when the second guide arm 9482 is twisted and deformed with respect to the first guide arm 9481 in a direction of pressing the overhanging front locking portion 9482f against the attachment portion 9481d, the overhanging front engagement portion 9482f and the attachment portion 9481d come into contact with each other. And the deformation resistance of the torsional deformation increases. In this case, the first guide arm 9481 and the second guide arm 9482 can be suppressed from being twisted. Therefore, the wire W can be prevented from being twisted and deformed, and the durability of the wire W can be ensured.

  When the other auxiliary bottom portion 9481h is further extended in the circumferential direction from the present embodiment, the second guide arm 9481 and the second guide arm 9482 are folded in the second state (see FIG. 64A). The guide arm 9482 and the other side auxiliary bottom part 9481h are in contact, and the first guide arm 9481 and the overhanging front locking part 9482f are in contact.

  In this case, the rear side of the second guide arm 9482 and the other side auxiliary bottom portion 9481h are in contact with each other, so that the front side of the second guide arm 9482 can be prevented from falling down. On the other hand, since the front side of the first guide arm 9481 is in contact with the overhanging front locking portion 9482f, it is possible to prevent the rear side of the second guide arm 9482 from falling down. Therefore, in a state where the first guide arm 9481 and the second guide arm 9482 are folded (see FIG. 64A), the second guide arm 9482 is twisted relative to the first guide arm 9481 regardless of the direction. Can be suppressed.

  The same effect can be obtained by adding the overhanging front locking portion 9482f to the rear side of the second guide arm 9482. Since the guide arm 9482 is sandwiched between the first and second guide arms 9481 and 9482, the positioning accuracy of the first and second guide arms 9481 and 9482 needs to be increased.

  On the other hand, in the present embodiment, since the portion for suppressing the twist of the second guide arm 9482 is formed so as to be shifted in the longitudinal direction of the second guide arm 9482, the alignment of the first guide arm 9481 and the second guide arm 9482 is performed. The degree required for the precision of the image can be reduced.

  In the present embodiment, the first guide arm 9481 and the second guide arm 9482 are opened (see FIG. 64A), and the first guide arm 9481 and the second guide arm 9482 are opened (FIG. 64). Before reaching (b), there is a possibility that the extended distal end of the other-side auxiliary bottom portion 9481h may come into contact with the end surface of the one-side bottom portion 482e1 of the second guide arm 9482.

  On the other hand, the inclined side surface 9481h1 (see FIG. 62 (a)) is formed at the extension end of the other side auxiliary bottom portion 9481h, so that the extension end of the other side auxiliary bottom portion 9481h comes into contact with the end surface of the one side bottom portion 482e1. Even in the case of contact, the other-side auxiliary bottom portion 9481h can ride on the back side of the one-side bottom portion 482e1 (the back side in FIG. 64B). This makes it easy to form the first guide arm 9481 and the second guide arm 9482 in an open state (see FIG. 64A).

  In addition, the first guide arm 9481 and the second guide arm 9482 are folded from the state where the first guide arm 9481 and the second guide arm 9482 are opened (see FIG. 64B) (FIG. 64A). (See Reference), there is a possibility that the extended distal end of the overhanging front locking portion 9482f may come into contact with the side surface of the attachment portion 9481d.

  On the other hand, since the inclined side surface 9482f1 (see FIG. 63 (c)) is formed at the extending end of the overhanging front locking portion 9482f, the extending end of the overhanging front locking portion 9482f is attached to the attachment portion 9481d. Even in the case of contact with the side surface, the overhanging front locking portion 9482f can be made to ride on the front side of the attachment portion 9481d (the front side of the drawing in FIG. 64A) (see FIG. 64C). This makes it easy to form the first guide arm 9481 and the second guide arm 9482 in a folded state (see FIG. 64A).

  In the present embodiment, the case where the projecting front locking portion 9482f that abuts on the attachment portion 9481d is formed on the front side is described, but the present invention is not necessarily limited to this. For example, the overhanging front locking portion 9482f may be formed as a pair of a front side and a back side. Thus, regardless of the direction of the torsional deformation of the second guide arm 9482, the overhanging front locking portion 9482f can be brought into contact with the attachment portion 9481d, and the first guide arm 9481 and the second guide arm 9482 are twisted and deformed. Can be suppressed.

  As described above, the present invention has been described based on the above embodiments. However, the present invention is not limited to the above embodiments, and various modifications and improvements can be easily made without departing from the gist of the present invention. It can be inferred.

  In each of the above embodiments, some or all of the configuration in one embodiment may be combined with or replaced by part or all of the configuration in another embodiment to form another embodiment.

  In each of the above embodiments, the case where the gap is formed by the pair of decorative members 422 of the combined operation unit 400 swinging has been described, but the present invention is not necessarily limited to this. For example, the decoration member 422 may be guided to be slidable in the left-right direction, and the pair of decoration members 422 may be slid in the direction away from each other to form a gap for accommodating the swing member 430. In this case, the width of the gap formed between the pair of decorative members 422 can be secured in the vertical direction.

  In the above embodiments, the case where the movable upper cover member 332 of the lower panel unit 300 slides in the front-rear direction has been described, but the present invention is not necessarily limited to this. For example, a pair of left and right long plate-shaped movable members are pivotally supported on the inner side surfaces of the pair of step portions 324a, and the movable members are in the direction in which the pair of step portions 324a are continuously provided. In a closed state in which the ball is positioned along the longitudinal direction to prevent passage of the ball to the specific winning opening 65a, and an opening that swings upward or downward from that state to allow the ball to pass to the specific winning opening 65a. And the state may be formed. Further, the second winning port 640 may be configured instead of the specific winning port 65a with the same configuration.

  In each of the above embodiments, the case where the light irradiated from the light irradiation device 331c is reflected to the front side when the movable upper cover member 332 of the lower panel unit 300 is in the retracted state has been described, but it is not necessarily limited to this. Not something. For example, a portion that reflects the light emitted from the light irradiation device 331c to the front side when the movable upper lid member 332 is in the extended state may be formed below the movable upper lid member 332. In this case, the light reflected by the movable upper lid member 332 is not blocked by the sphere, and the light effect can be improved.

  In each of the above-described embodiments, the case where the positioning unit 543 is combined with the moving member 540 of the swing operation unit 500 by the concave-convex fitting has been described, but the present invention is not necessarily limited to this. For example, a magnet may be provided at a position where a pair of moving members 540 are arranged close to each other, and the moving members 540 may be united by magnetic force. In this case, the moving members 540 can be attracted to each other by the magnetic force, and it becomes unnecessary for the driving device 550 to generate a holding force when the moving members 540 are arranged at the extended position. Therefore, power consumption of the driving device 550 can be suppressed.

  In each of the above embodiments, the case where the guide hole 413 of the combined operation unit 400 is formed in a straight line has been described, but the present invention is not necessarily limited to this. For example, the guide hole 413 may be formed in a curved shape. In this case, even if the moving speed of the main body member 410 is the same, the swing speed of the shielding member 420 can be made slower or faster.

  In the above embodiments, the case where the main body member 431 of the swing member 430 of the combined operation unit 400 swings has been described, but the present invention is not necessarily limited to this. For example, the swing member 430 may include a slide member that slides in a direction away from the main body member 410, and the decoration member 422 may be accommodated between the slide member and the main body member 410.

  In each of the above embodiments, the case where the respective guide arms of the wiring guide arms 480 of the combined operation unit 400 are vertically stacked has been described, but the present invention is not necessarily limited to this. For example, each guide arm of the wiring guide arm 480 may be stacked in the front-rear direction. In this case, since the vertical width of the wiring guide arm 480 can be reduced, the width of the bottom wall portion 211 necessary for housing the wiring guide arm 480 outside the opening 211a can be reduced. Thereby, the arrangement area of the third symbol display device 81 can be increased.

  In each of the above embodiments, the case where the moving member 540 is supported by the pair of arm members of the drive side arm members 520, 2520, 3520, 7520 and the driven side arm members 530, 7530 has been described, but is not necessarily limited to this. is not. For example, the moving member 540 may be supported by three or more arm members. In this case, for example, the bridge members 528, 2528, and 7528 are fastened and fixed to the intermediate arm members, and are disposed so as to cover the front sides of the arm members at both ends, thereby suppressing the positional deviation between the arm members. Can be improved. That is, when one of the arm members at both ends pushes one end of the bridging members 528, 2528, 7528, and the bridging members 528, 2528, 7528 bend, the other end becomes the other end. It moves toward the arm member and is supported by the other arm member. As described above, the arm members at both ends act to suppress the bending of the bridging members 528, 2528, and 7528. As a result, displacement of the plurality of arm members can be suppressed, and the posture of the moving member 540 can be stabilized. Can be done.

  In the first to fifth embodiments and the seventh embodiment described above, each of the guide arms 481 to 483 of the wiring guide arm 480 includes a columnar portion (for example, one side support portion 482b) and a cylindrical portion ( For example, although the case where it is pivotally supported by the other cylindrical portion 481c) has been described, it is not necessarily limited to this. For example, the portion supporting the columnar portion may be formed by an elongated hole extending in the longitudinal direction of each of the guide arms 481 to 483. In this case, in addition to expansion and contraction in the vertical direction in which the guide arms 481 to 483 are bent, expansion and contraction in the horizontal direction in which the guide arms 481 to 483 slide in the extending direction of the elongated hole can be performed.

  In the first to fifth embodiments and the seventh embodiment, the lower side surface (for example, the plate-shaped arm portion 481a) of each arm member (for example, the first guide arm 481) constituting the wiring guide arm 480. Has described the case where the width is shorter than the upper side surface (for example, the attachment portion 9481d), but the present invention is not necessarily limited to this. For example, the lower side surface (for example, the plate-shaped arm portion 481a) of each arm member (for example, the first guide arm 481) may be wider than the upper side surface (for example, the attachment portion 9481d). In this case, it is possible to suppress the wiring W from slipping down from the lower side surface (for example, the plate-shaped arm portion 481a) due to gravity.

  In the above-described first to fifth embodiments, the seventh embodiment and the ninth embodiment have described the case where the width of the wiring W is shorter than the attachment portions 481d and 9481d. However, the present invention is not necessarily limited to this. . For example, the formation of the front locking portion 481f may be omitted, and the width of the wiring W may be longer than the width of the plate-shaped arm portion 481a and the attachment portions 481d and 9481d. In this case, since a part of the wiring W protrudes from the plate-shaped arm portion 481a and the attachment portions 481d and 9481d, the protruding portion can be pinched (fingered by a finger) to easily take out the wiring W. Thereby, maintenance of the wiring W can be easily performed.

  In the above-described first to fifth embodiments, the seventh embodiment and the ninth embodiment have described the case where the widths of the attachment portions 481d and 9481d are constant. However, the present invention is not necessarily limited to this. For example, portions of the attachment portions 481d and 9481d other than the portion where the front locking portion 481f is fixed may be formed with the same width as the plate-shaped arm portion 481a. In this case, by making the width of the wiring W longer than the plate-shaped arm portion 481a, a part of the wiring W can protrude from the plate-shaped arm portion 481a and the attachment portions 481d and 9481d. Therefore, the protruding portion can be picked up with a finger (and hooked with a finger) to easily take out the wiring W. Thereby, maintenance of the wiring W can be easily performed.

  In the fourth embodiment, the case where the concave portion 4424c is formed on the upper side surface of the guide hole 4424b has been described, but the present invention is not necessarily limited to this. For example, the thickness of the upper surface of the guide hole 4424b may be thicker than the thickness of the lower surface. In this case, the friction generated between the upper surface of the guide hole 4424b and the connecting member 423 can be larger than the friction generated between the lower surface of the guide hole 4424b and the connecting member 423. The rebound of the connecting member 423 that occurs when the connecting member 423 is moved can be suppressed.

  In the fourth embodiment, the case where the concave portion 4424c is formed on the upper side surface of the guide hole 4424b has been described, but the present invention is not necessarily limited to this. For example, a recess capable of accommodating the slide shaft portion 423e may be formed on the upper side surface of the lower end portion of the guide hole 413 of the main body member 410. In this case, when the insertion shaft 421c is disposed at the lower end of the guide hole 413, the resistance F applied to the insertion shaft 421c from the side surface of the guide hole 413 can be increased.

  In the above-described eighth embodiment, the case where the direction changing portion 8013c is provided only at the extending end of the light projecting passage 8013b has been described, but the present invention is not necessarily limited to this. For example, a direction changing portion 8013c may be additionally provided in the middle of the light projecting passage 8013b. In this case, the light reflected to the front side from the direction changing portion 8013c disposed in the middle of the light projecting passage 8013b and the light reflected through the direction changing portion 8013c and disposed at the extending end of the light projecting passage 8013b. The light can be divided into light reflected from the direction changing unit 8013c and light reflected frontward. That is, since the light emitted from the light irradiation device 8610 can be divided into a plurality of light components, the number of light beams visible in a front view can be larger than the number of light irradiation device 8610. Thus, the number of light irradiation devices 8610 can be reduced while maintaining the effect of the light irradiation device 8610.

  The present invention may be implemented in a pachinko machine or the like of a type different from the above embodiments. For example, once a jackpot has been hit, a pachinko machine (commonly known as a twice-rights item or a three-times right item) can increase the jackpot expectation value until a jackpot state occurs a plurality of times (for example, two or three times). ). Further, after the big hit symbol is displayed, the game may be implemented as a pachinko machine that generates a special game for giving a predetermined game value to a player on condition that a ball is won in a predetermined area. Further, a prize winning device having a special area such as a V zone may be provided, and the pachinko machine may be put into a special game state on condition that a ball is awarded in the special area. Further, in addition to the pachinko machine, the present invention may be implemented as various game machines such as areaches, sparrow balls, slot machines, so-called game machines in which a so-called pachinko machine and a slot machine are combined.

  In the slot machine, for example, a symbol is changed by operating an operation lever in a state where a coin is inserted and a symbol valid line is determined, and the symbol is stopped and determined by operating a stop button. Things. Therefore, the basic concept of the slot machine is as follows: "a display device for variably displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information is provided. The variable display of the identification information is started, and the variable display of the identification information is stopped and confirmed and displayed due to the operation of the stop operation means (for example, a stop button) or after a predetermined time has elapsed. A slot machine that generates a special game that gives a predetermined game value to a player on the condition that the combination of the identification information at the time is a specific one, and in this case, coins, medals, etc. are representative of game media. As an example.

  Further, as a specific example of a gaming machine in which a pachinko machine and a slot machine are integrated, a display device for variably displaying a symbol row including a plurality of symbols and then displaying the symbols in a fixed manner is provided, and a handle for hitting a ball is provided. Not included. In this case, after throwing in a predetermined amount of balls based on a predetermined operation (button operation), for example, the fluctuation of the symbol is started due to the operation of the operation lever, for example, due to the operation of the stop button, or By the passage of time, the fluctuation of the symbol is stopped, and a special game that gives a predetermined game value to the player is generated on the condition that the confirmed symbol at the time of the stop is a so-called big hit symbol, and the player is given a special game. Is a method in which a large amount of balls are paid out to a lower saucer. If such a gaming machine is used in place of a slot machine, only balls can be treated as a game value in a game hall, and thus a game value seen in a current game hall where pachinko machines and slot machines are mixed. Problems such as the burden on equipment due to the separate handling of medals and balls and restrictions on the location of gaming machines can be solved.

<First control example>
Next, display contents of the third symbol display device 81 in the first control example will be described with reference to FIGS. 65 to 78. FIG. 65 is a diagram showing a display screen of the third symbol display device 81.

  The symbol, which is a type of symbol displayed on the third symbol display device 81, is composed of nine types of main symbols, each of which has a number from "1" to "9", and a sub symbol composed of a shell-shaped symbol. It is configured. More specifically, nine types of character designs such as an octopus are numbered "1" to "9" to form a main design.

  As shown in FIG. 65 (a), on the display screen (display area) of the third symbol display device 81, three symbol rows Z1, Z2, Z3 of an upper row, an interruption, and a lower row are set as a plurality of display areas. ing. In the lower symbol row Z3, nine types of main symbols "1" to "9" are arranged in ascending numerical order, and one sub symbol is arranged between each main symbol.

  That is, the upper symbol row Z1 and the lower symbol row Z3 are composed of 18 symbols. On the other hand, in the middle symbol row Z2, nine types of main symbols “1” to “9” are arranged in ascending numerical order, and the main symbol “9” and the main symbol “1” are arranged. , A main symbol of “4” is additionally arranged, and one sub symbol is arranged between these main symbols. That is, only the middle symbol row Z2 is composed of 20 symbols with 10 main symbols arranged. Then, on the display screen, the symbols in each of the symbol rows Z1 to Z3 are variably displayed so as to scroll in a predetermined direction with a periodicity.

  As shown in FIG. 65 (b), on the display screen, three symbols are stopped and displayed for each symbol row, and as a result, a total of 9 symbols of 3 × 3 are stopped and displayed. It has become. Further, five effective lines, that is, a left line L1, a middle line L2, a right line L3, a right-down line L4, and a right-up line L5 are set on the display screen. Then, the variable display is stopped in the order of the upper symbol row Z1 → the lower symbol row Z3 and the middle symbol row Z2, and all the symbol rows Z1 are formed in a state in which a combination of the symbols having the same number assigned to any of the activated lines is formed. When the variable display of .about.Z3 is finished, it is determined that a big hit has occurred and a big hit moving image is displayed.

  In this pachinko machine 10, the main symbols with odd numbers (1, 3, 5, 7, 9) correspond to “probable symbols”, and jackpot A, which is a 16R variable jackpot, or jackpot B, which is a 4R variable jackpot. If it occurs, the same combination of probable symbols is stopped and displayed. In addition, the main symbol with an even number (2,4,6,8) corresponds to a “normal symbol”, and when a jackpot C that is a 16R normal jackpot or a jackpot D that is a 4R normal jackpot occurs. , The same combination of normal symbols is stopped and displayed.

  In addition, the mode of the variable display of the symbol in the third symbol display device 81 is not limited to the above, and is arbitrary. The number of symbol columns, the direction of the variable display of the symbol in the symbol column, and the The number of symbols and the like can be changed as appropriate. Further, the pattern variably displayed on the third symbol display device 81 is not limited to the above-described symbol, and for example, a configuration in which only numbers are variably displayed as a symbol may be employed.

  Further, if a ball enters the first winning opening 64 while the variable display is being performed on the third symbol display device 81 (the first symbol display device 37), the number of entered balls is suspended up to four times. The number of retained balls is indicated by the first symbol display device 37 and also by the third symbol display device 81. The third symbol display device 81 displays one reserved ball number symbol per reserved ball number, and displays the number of reserved balls according to the number of displayed reserved ball number symbols. That is, when one reserved ball number symbol is displayed on the third symbol display device 81, it indicates that the number of reserved balls is one ball, and when four reserved ball number symbols are displayed, the reserved ball number symbol is reserved. Indicates that the number of balls is four. In addition, when the number-of-retained-balls symbol is not displayed on the third symbol display device 81, it indicates that the number of reserved balls is 0, that is, there is no reserved ball.

  In the present control example, although the ball entering the first winning port 64 is configured to be held up to four times, the maximum number of held balls is not limited to four, and is not more than three. Alternatively, the number may be set to 5 or more times (for example, 8 times). Further, instead of displaying the number of reserved balls on the third symbol display device 81, the number of retained balls is replaced by a numeral on a part of the third symbol display device 81, or the area divided into four is divided by the number of retained balls. However, the display may be performed in a different form (for example, a color or a lighting pattern). Further, since the number of reserved balls is indicated by the first symbol display device 37, the number of reserved balls may not be displayed on the third symbol display device 81. Further, the variable display device unit 80 may be provided with four holding lamps indicating the number of reserved balls for the maximum reserved number, and displaying the number of reserved balls according to the number of the reserved lamps in the lighting state.

  Next, with reference to FIG. 66 and FIG. 67, a description will be given of a super background announcement effect which is one of the effects executed in the pachinko machine 10 of the present control example. This super background announcement effect is an effect in which a player can operate the scroll direction of the background by using the selection switch 270. When a specific image (an image in which the door blinks in the present control example) is displayed in the background image of the super background notice, by operating the determination switch 270e, it is expected whether or not there is a big hit in the hold. A background image (background inside the door) indicating the value is displayed. Therefore, a player who wants to know information about whether or not there is a big hit in the hold plays a game by paying attention to the appearance of the specific image in the background image of the super background notice. As a result, the interest of the player can be improved.

  In addition, the background image of the super background notice can be scrolled and displayed in an arbitrary direction of the player by operating the switch, so that it is possible to give the player an impression as if searching in the background image. . Thereby, the interest of the player can be improved.

  FIG. 66A is a diagram illustrating an example of the background image of the super background notice effect. If the right switch 270b is pressed, for example, when the background image of the super background announcement effect is displayed, the background image is scrolled to the right. Here, in the present control example, the background image is set to be scrolled to the right based on the pressing of the right switch 270b, and then the scroll is continued until the selection switch 270 in another direction is operated. Have been. However, the present invention is not limited to this configuration, and the background image may be scrolled according to the pressing time of the selection switch 270. As a result, it is possible to flexibly respond to the operation of the player, and the interest of the player can be improved.

  FIG. 66B shows a case where the background image of the above-described super background notice effect is displayed (see FIG. 66A), and the rear image is scrolled to the right based on the pressing of the right switch 270b. FIG. By scrolling the rear image to the right, the image of the door, which is only partially displayed at the right end of the screen in FIG. 66A, can be visually recognized in the center of the screen in FIG. 66B. It is displayed in the state.

  The image of the door is data that blinks at regular intervals. As a result, when a certain period of time has passed while the door is visible as shown in FIG. 66 (b), the door blinks and is displayed as shown in FIG. 67 (a). In this case, when the enter button 270e is pressed, an effect indicating the display of the background inside the door, which is a special image, is displayed. Specifically, as shown in FIG. 67 (b), an image in which the door is opened is displayed, and the character “Enter next time!” Is displayed. Here, in the present control example, the blinking display of the door is configured to be performed at regular time intervals. However, the present invention is not limited to this, and the blinking interval may be irregular. Further, in the present control example, data that blinks at regular intervals is prepared in advance, and the blinking display of the door is configured. However, the present invention is not limited to this. It may be configured to change to.

  Note that the background inside the door (not shown), which is a special image, indicates the degree of expectation as to whether or not there is a big hit in the hold, as described above. Although the detailed processing will be described later, the background in the door is displayed from the time it is displayed until the end of the 20 changes. When the 20 changes are completed, it is determined again whether or not there is a big hit in the hold, and the background image is changed based on the determination result. Specifically, if it is determined that there is a jackpot in the hold, the same image of the background in the door as the previous time is displayed with a high probability, otherwise, the display of the background in the door is terminated. It becomes. Next, with reference to FIG. 68 to FIG. 71, a description will be given of the super reach A effect, which is one of the super reach effects executed in the pachinko machine 10 of the present control example. The effect of the super reach A is an effect executed during the fluctuation period of the third symbol, and is an effect in which a stop symbol is displayed based on the pressing of the frame button 22.

  In Super Reach A, the loose-eye display mode is displayed and a small bubble is displayed. Here, the staggered eye display mode is, for example, as shown in FIG. 68 (a), a sixth design in which the main design of the anglerfish has a number "6" attached to the left line L1 of the upper design row Z1. The symbol, the middle symbol L2, the sub symbol shell symbol, the right line L3, the main symbol of the whale, and the symbol with the number "7" are stopped and displayed, and the lower symbol row Z3 has five symbols on the left line L1, This is a display mode in which the shell pattern is stopped and displayed on the middle line L2 and the four symbols are stopped and displayed on the right line L3, and no reach is achieved on any of the lines (L1 to L5).

  Next, the character "Bubble Chance" is displayed, and the loose eye display mode is changed to the double reach display mode. Here, the double-reach display mode means that, for example, as shown in FIG. 68 (b), the same symbol as that of FIG. 68 (a) is stopped and displayed in the upper symbol column Z1, and is displayed in the left line L1 of the lower symbol column Z3. The seven symbols are a shell symbol on the middle line L2, the six symbols are stopped and displayed on the right line L3, a reach display mode of six symbols on the downward line L4, and a reach display mode of seven symbols on the upward line L5. It is an aspect.

  Then, as shown in FIG. 69 (a), a character indicating “please stop bubbles by touch!” Is displayed together with the display that a plurality of bubbles rotate, and thereafter, the bubbles rotate as shown in FIG. 69 (b). A display is displayed in which a symbol (6 symbols, 7 symbols, and a special symbol) which will be a big hit is entered in the bubble.

  Next, as shown in FIG. 70 (a), the color of the bubble containing the symbol that becomes a big hit changes, and the character "Colored bubble hit!" Is displayed. At the lower right of the screen, an indicator for displaying the remaining time during which the button can be pressed is displayed.

  Then, if the frame button 22 is pressed within the remaining time in which the button can be pressed, colored bubbles or non-colored bubbles are stopped and displayed. FIG. 70B is a diagram exemplifying a screen on which the colored bubbles are stopped and displayed.

  When the colored bubbles are stopped and displayed, as shown in FIG. 71, the colored bubbles change to a symbol (seven symbols) that becomes a big hit, and the big hit is notified. On the other hand, when the non-colored bubbles are stopped, the non-colored bubbles change to a symbol (for example, five symbols) that is detached, and the detachment is notified (not shown).

  As described above, in Super Reach A in the present control example, the symbols to be a big hit (6 symbols, 7 symbols, and the special symbol in the above example) are unified into colored bubbles, and the outlying symbols (6 symbols, 7 symbols) (The symbols other than the symbol and the special symbol) are unified as uncolored bubbles. This allows the player to press the button only by paying attention to the presence or absence of the color, thereby providing an easy-to-understand gaming machine.

  Next, with reference to FIGS. 72 to 74, a description will be given of the jackpot effect performed in the pachinko machine 10 of the present control example. In this jackpot effect, a map in which squares like sugoroku are arranged is displayed, and the square of the map can be selected based on an operation of the selection switch 270 or the like. An event is set for each of the selected cells, and a round effect during a jackpot effect is performed based on the event. The mass event is set based on the jackpot type, the number of continuations of the jackpot, the value of the display effect counter 233o, and the like.

  In addition, when the jackpot continues (when the jackpot becomes a big hit in the probable change state or the time saving state), an effect continued from the square selected in the previous jackpot effect is executed. Further, there is provided a continuum which is not the cell selected in the previous jackpot effect but can start (restart) a continuous effect. It is determined whether or not the restart from the continuum can be executed based on the history of the cells that have passed. Also, if all the squares on the map have been passed, a new map will be displayed from the next jackpot effect. Furthermore, at the end (ending) of the jackpot effect, the mass event may be changed depending on whether or not there is a jackpot in the hold.

  FIG. 72 (a) shows a case in which the first cell has been selected from the start point in the previous jackpot effect, and thereafter the jackpot effect is started continuously (a jackpot occurs during probable change or during working hours). FIG. In addition, the square in which "S" was written in the figure means the starting point, and the area starts from here at the time of the first big hit. In addition, “G” in the figure means a goal point, and the operation when reaching the goal point will be described later with reference to FIG. 73 (b).

  As shown in FIG. 72 (a), when the continuous jackpot effect is started, the effect is continuously started from the cell selected in the previous jackpot effect. When the jackpot effect is started, the cell (the previously selected cell), which is the current operation start point, is displayed in a different color from the other cells, and a dog character is displayed. Thus, the player can easily recognize where the current operation start point is. The mode in which the player can recognize the operation start point is not limited to this. For example, a form in which the cell at the operation start point blinks may be displayed, or the cell is indicated by a symbol such as an arrow. It may be something.

  An arrow indicating an operable direction is displayed near the square at the operation start point. Thus, the player can easily recognize in which direction the player can operate. In this control example, an arrow indicating that the operation can be performed in the right direction and the downward direction is displayed. Here, when the right switch 270b is pressed, the square immediately to the right of the square at the operation start point (that is, the square two points away from the start point) is lit, and a dog character is displayed.

  On the other hand, when the selection switch 270 corresponding to a direction not shown as an operable direction is operated, it is considered that the switch operation has not been performed, and the display is not changed. In the above case, a display may be performed on the screen or a sound may be output to indicate that the switch operation is invalid.

  Here, when the decision switch 270e is pressed in a state in which the cell on the right of the cell at the operation start point (that is, the cell two ahead of the start point) is selected, the cell responds to the cell event set in the cell. Is performed.

  FIG. 72 (b) shows a jackpot effect (see FIG. 72 (a)) in the case where the cell immediately after the start point is the operation start point (see FIG. 72 (a)). After the right switch 270b is pressed, the decision switch 270e is It is a figure which shows an example of the effect when pressed. In FIG. 72 (b), when it is determined based on the operation of the decision switch 270e that a cell two points ahead of the start point has been selected, an effect corresponding to the cell event set for the cell is performed. Specifically, a display indicating the content of the mass event, "The number of available backgrounds has increased!" Is displayed at the upper left of the third symbol display device 81. Thereby, the player can easily recognize the contents of the mass event.

  Further, when the continued big hit effect is started, the previous map and mass event are read, and a new mass event is read based on the value of the display effect counter 233o of the display control device 114. When a new mass event is set by comparing the previous mass event with the new mass event, for example, as shown in FIG. 73 (a), the character “Continue mass has increased!” Is displayed. Is done.

  Thereby, the player can easily recognize that the mass event has changed. On the other hand, the present invention is not limited to this, and the mass event may be changed so that the player cannot recognize it. As a result, it is possible to provide an unexpected effect for the player, and it is possible to improve the interest of the player.

  With reference to FIG. 73 (b), a description will be given of a display in the case where the jackpot effect is continuously executed after passing the continuum. In the jackpot effect of the present control example, when passing through a continuum provided on the map of the jackpot effect, it is possible to execute an effect (restart) continued from the passing cell in the next continuous jackpot effect. Become. Specifically, when there is a route (one or a plurality of squares) that has passed the continuum and has not been passed, the route is restarted from the continuum that has the unpassed route closest to the start point. You. In this case, as shown in FIG. 73 (b), the character "Restart point is here" is displayed, and a cell corresponding to the restart point is indicated by an arrow.

  Thereby, it is possible to make the player easily recognize that the continuous big hit effect is started from the cell. It should be noted that the squares that have passed are marked with “Exit” and are hatched, and the squares that have not passed are marked with “Not”. This makes it possible for the player to easily recognize which square has not passed. By this restart, it is possible to restart from not only the cell selected last time but also a continuum where there is a route that has not passed, so that it is easy to pass a cell that has not passed.

  When all the cells have passed, a new map is displayed. In this case, as shown in FIG. 74 (a), a new map is displayed, and characters "New map found!" Are displayed. This allows the player to easily recognize that the new map has been displayed.

  When it is determined that there is a big hit in the hold at the end (ending) of the big hit effect, a mass event is set based on the big hit. Specifically, as shown in FIG. 74 (b), a cell two cells ahead of the cell at the current point (that is, a cell that can be reached by generating two jackpots) is set as a special cell. By setting the two squares as the special squares, the player expects at least two more jackpots to continue the game. As a result, the interest of the player can be improved.

  Next, the effect of the super reach B in the present control example will be described with reference to FIGS. 75 to 78. FIGS. 75 and 76 are schematic diagrams schematically showing the production timing of the super reach B, and FIGS. 77 and 78 are diagrams illustrating the production of the super reach B.

  The production of Super Reach B is based on the operation of the frame button 22 by operating the frame button 22 (see FIG. 77 (a)), in which the character (girl) on the screen holds the pattern (shark, shrimp, etc.) An effect to be thrown (see FIG. 77 (b)) or an effect not to be thrown is executed. When this throwing effect is performed, the symbol in hand is changed to the next symbol. Then, if the same symbol as the reach symbol appears, the effect is to notify the big hit (see FIG. 78 (b)).

  In addition, in the case of the super-reach B effect of the jackpot, the effect of throwing until the same symbol as the reach symbol appears can be executed based on the operation of the frame button 22. If there is, based on the operation of the frame button 22, throwing is not possible until the same symbol as the reach symbol appears.

  In this control example, if the throwing effect (see FIG. 77 (a)) is executed three times, an effect for notifying the big hit (see FIG. 78 (b)) is executed. Specifically, when the reach is achieved with the symbol 7, the effect is started by throwing the symbol 4. When the effect of throwing the symbol of 4 is executed based on the operation of the frame button 22, the process then shifts to the effect of throwing the symbol of 5. Similarly, when the effect of throwing the symbol 5 is executed, the process shifts to the effect of throwing the symbol 6, and when the effect of throwing the symbol 6 is executed, the symbol 7 appears.

  On the other hand, if the frame button 22 is not pressed in the super-reach B effect of the jackpot, the jackpot will be a jackpot even though the throwing effect has not been performed. Is a different effect (replacement effect). Here, in super reach B, it is necessary to operate the frame button 22 a plurality of times before the effect for notifying the big hit is executed. Therefore, at the timing (replacement timing) when it is considered that the operation of the frame button 22 is insufficient until the performance of reporting the jackpot, the normal production is replaced with the replacement production in advance. This replacement timing is variable according to the number of times the frame button 22 is operated, and will be described later in detail.

  First, with reference to FIG. 75 (a), a description will be given of a case where the frame button 22 has never been pressed in the effect of Super Reach B. When the fluctuation of the super reach B is started, the fluctuation of the symbol (normal effect) is started. Then, the upper symbol row Z1 and the lower symbol row Z3 are stopped in the display mode of reaching, and the reach effect is started. The reach effect period is a frame SW effective period in which an effect based on pressing of the frame button 22 is executed. If there is no pressing of the frame button 22 during the frame SW valid period, the effect for notifying the big hit is replaced with the replacement effect at the replacement timing. Thereby, even if there is no pressing of the frame button 22 and there is no effect to throw, there is a big hit, and it is possible to execute a big hit notification without a sense of incongruity for the player.

  Next, with reference to FIG. 75 (b), a description will be given of a case where the frame button 22 is pressed only once in the super reach B effect. When the fluctuation of the super reach B is started, the upper symbol row Z1 and the lower symbol row Z3 are stopped in the display mode of reaching, as in the case of FIG. 75 (a) described above, and the reach effect is started. . Then, based on the fact that the frame button 22 has been pressed during the frame SW valid period, an effective effect that is an effect of throwing a symbol is executed. Here, the effect of throwing a symbol (effective effect) or the effect of not throwing a symbol (false effect), which is executed based on the button operation, is a lottery based on the effect counter 223i of the audio lamp control device 113. is there.

  When the effective effect is executed, the timing (replacement timing) at which the operation of the frame button 22 is considered to be insufficient changes before the effect for notifying the jackpot, so the replacement timing is delayed by the delay time dt. You. Thereby, even if the operation of the frame button 22 is in time by the execution of the effect for notifying the jackpot, it is possible to prevent the effect for notifying the jackpot from being replaced.

  In FIG. 75 (b), since the frame button 22 is not pressed after the frame button 22 is pressed once, the jackpot is notified at the replacement timing (after the change) delayed by the delay time dt as described above. The effect will be replaced with a replacement effect.

  Next, with reference to FIG. 76 (a), a description will be given of a case where the effect of Super Reach B is such that the frame button 22 is depressed, and the effect of notifying the jackpot is replaced with the jackpot.

  When the fluctuation of the super reach B is started, the upper symbol row Z1 and the lower symbol row Z3 are stopped in the display mode in which the symbol reaches 7 in the same manner as in the case of FIGS. 75 (a) and (b) described above. And the reach production is started. Then, based on the pressing of the frame button 22 during the frame SW valid period, an effective effect or a false effect is executed. In FIG. 76 (a), a false effect, which is an effect in which the symbol 4 cannot be thrown by the first press, is executed. Then, an effective effect is executed by the second and third presses, and the symbol possessed by the character is changed to the symbol 6. When the frame button 22 is pressed during the stoppable period in a state where the symbol 6 is displayed, a stop display effect as an effective effect is executed, and a stop display in which the symbol 7 appears is executed.

  On the other hand, even if the frame button 22 is pressed during the non-stoppable period, an effective effect is not executed, and a fake effect is executed. Thereby, it is possible to prevent the effect of the stop display from being executed at an early timing when the display period of the stop display is insufficient.

  Next, with reference to FIG. 76 (b), a description will be given of a case where the frame button 22 is depressed in the effect of Super Reach B, and the effect of notifying the jackpot is reported without replacement.

  In FIG. 76 (b), similarly to FIG. 76 (a) described above, in the frame SW valid period, a false effect and two valid effects are executed based on the operation of the frame button 22 three times. The symbol appears. Here, in FIG. 76 (a), when the frame button 22 is pressed during the stoppable period, a stop display effect, which is an effective effect, is executed, and the symbol 7 appears. On the other hand, in FIG. 76 (b), when the frame button 22 is pressed during the stoppable period, a stop display effect that is a false effect is executed, and the symbol 7 does not appear. Thereby, it is possible to prevent a symbol that is a big hit from being displayed even when the display mode of the out-of-reach super reach B is being executed.

  As shown above, FIG. 77 (a) illustrates a screen in which an effective effect based on the frame button 22 is not executed when the reach is reached with the symbol 7 in the super reach B. At the upper left of the screen, 7 symbols are displayed to indicate that the reach has been reached with 7 symbols. In addition, the character at the center of the screen has a symbol of 4 and the effective effect is executed three times, so that the symbol changes from symbol 5 to symbol 6 → symbol 7 and is a reach symbol 7. Will be displayed. In the lower right part of the screen, an indicator indicating the effective period of the frame SW is displayed.

  FIG. 77 (b) illustrates a screen in which an effective effect is executed based on the operation of the frame button 22 when the symbol 4 is displayed in the frame SW valid period of the super reach B as described above. It was done. An effect in which the character in the center of the screen throws the symbol 4 based on the operation of the frame button 22 is displayed.

  FIG. 78 (a) is a diagram illustrating an example of a screen that has a jackpot due to the above-described replacement effect. The notification of the jackpot by the replacement effect is executed when the jackpot has been achieved even though the operation of the frame button 22 has not been executed. In this case, since the operation of the frame button 22 has not been executed, the stop display is performed in an out of form. Therefore, in the present control example, after the stop display, an effect for notifying the big hit in which the character “Resurrection big hit” is displayed as shown in FIG. 78A is executed. This allows the player to recognize that it is a jackpot effect that appears to be off. As a result, the jackpot is notified in spite of the stop display in the off state, so that the uncomfortable feeling felt by the player can be reduced.

  FIG. 78 (b) is a diagram exemplifying an effect in which a big hit is notified by a normal effect in which replacement is not performed. This effect is a diagram in a case where the frame button 22 is pressed a specified number of times during the frame SW valid period and a big hit symbol appears as shown in FIG. 76 (a). In FIG. 78 (b), based on the pressing of the frame button 22 during the stoppable period, the effect of throwing the symbol 6 to the upper right of the screen is achieved.

<Electrical Configuration in First Control Example>
Next, the RAM 203 provided in the main control device 110 will be described with reference to FIGS. In the main control device 110, a special symbol lottery, a normal symbol lottery, a display setting on the first symbol display device 37, a display setting on the second symbol display device 83, and a display setting on the third symbol display device 81 are set. The main processing of the pachinko machine 10 is executed. The RAM 203 is provided with various counters for controlling these processes. Here, a counter and the like provided in RAM 203 of main controller 110 will be described with reference to FIG. These counters and the like are used for special symbol lottery, ordinary symbol lottery, display setting on the first symbol display device 37, display setting on the second symbol display device 83, and display setting on the third symbol display device 81. It is used by the MPU 201 of the main control device 110 to perform such operations.

  In order to select the special symbol lottery and the display setting of the first symbol display device 37 and the third symbol display device 81, the first random number counter C1 used for the special symbol lottery and the special symbol big hit type are selected. , A first type random number used for setting an initial value of a first random number counter C1, a stop type selection counter C3 used for selecting an outage type of stop in a special symbol, A counter CINI1 and a variation type counter CS1 used for variation pattern selection are used. In addition, the second random number counter C4 is used for the lottery of the normal symbols, and the second initial value random number counter CINI2 is used for setting the initial value of the second random number counter C4. Each of these counters is a loop counter that adds 1 to the previous value and returns to 0 after reaching the maximum value each time the counter is updated.

  Each counter is updated, for example, at an interval of 2 milliseconds, which is the execution interval of the timer interrupt process (see FIG. 92), and some counters are updated irregularly in the main process (see FIG. 100). Then, the updated value is appropriately stored in the counter buffer 203h of the RAM 203. The RAM 203 is provided with a special symbol reserved ball storage area 203a including one execution area and four reserved areas (reserved first to fourth areas), and each of these areas has a first winning port 64. Alternatively, the respective values of the first random number counter C1, the first hit type counter C2, and the stop type selection counter C3 are stored in synchronization with the timing of entering the second winning opening 640. Further, the RAM 203 is provided with a normal symbol holding sphere storage area 203b including one execution area and four holding areas (holding first to fourth areas). The value of the second random number counter C4 is stored in synchronization with the timing of passing through the symbol starting port (through gate) 67.

  Each counter will be described in detail. The first random number counter C1 is incremented by one in order within a predetermined range (for example, 0 to 399), and reaches 0 after reaching the maximum value (for example, 399 in the case of a counter that can take a value of 0 to 399). The configuration is returned to. In particular, when the first random number counter C1 makes one round, the value of the first initial value random number counter CINI1 at that time is read as the initial value of the first random number counter C1.

  In addition, the first initial value random number counter CINI1 is configured as a loop counter that is updated in the same range as the first random number counter C1. That is, for example, when the first random number counter C1 is a loop counter that can take a value of 0 to 399, the first initial value random number counter CINI1 is also a loop counter in the range of 0 to 399. The first initial value random number counter CINI1 is updated once each time the timer interrupt process (see FIG. 92) is executed, and is repeatedly updated within the remaining time of the main process (see FIG. 100).

  The value of the first random number counter C1 is, for example, updated periodically (once for each timer interrupt processing in the present control example), and the RAM 203 is updated at the timing when the ball wins the first winning opening 64 or the second winning opening 640. Is stored in the special symbol holding ball storage area 203a. Then, the value of the random number to be the special symbol jackpot is set by the first random number table 202a stored in the ROM 202 of the main control device 110, and the value of the first random number counter C1 is set to the first random number table. If the value matches the value of the random number which becomes the jackpot set by 202a, it is determined that the special symbol is a jackpot. In addition, the first random number table 202a includes a special symbol for a low probability (a period during which the special symbol is in a low probability state) and a high symbol for a special symbol having a higher probability of being a big hit than the low probability. For the special symbol high-probability state). That is, in each state, the number of jackpot random numbers included in the table is different. In this way, by making the number of random numbers which are big hits different, the probability of big hits is changed between a low probability of a special symbol and a high probability of a special symbol.

  The first hit type counter C2 determines the display mode of the first symbol display device 37 when a special symbol hits, and adds one by one in a predetermined range (for example, 0 to 99). Then, after reaching the maximum value (for example, 99 in the case of a counter that can take a value of 0 to 99), it returns to 0. The value of the first hit type counter C2 is, for example, updated periodically (once every timer interrupt processing in the present control example), and at the timing when the ball wins the first winning opening 64 or the second winning opening 640. It is stored in the special symbol holding ball storage area 203a of the RAM 203.

  Here, the value of the first random number counter C1 stored in the special symbol holding ball storage area 203a or the special symbol 2 holding ball storage area 203b is not a random number which is a big hit of the special symbol, that is, the special symbol is out. If the random number is, the display mode corresponding to the stop symbol displayed on the first symbol display device 37 is the one when the special symbol is removed.

  On the other hand, if the value of the first random number counter C1 stored in the special symbol holding ball storage area 203a is a random number that is a special symbol jackpot, the value corresponding to the stop symbol displayed on the first symbol display device 37 is displayed. The display mode is that at the time of the special symbol jackpot. In this case, the specific display mode at the time of the big hit is the display mode indicated by the value of the first hit type counter C2 stored in the same special symbol holding ball storage area 203a.

  The first random number counter C1 in the pachinko machine 10 of this control example is configured as a 2-byte loop counter in the range of 0 to 299. In the first random number counter C1, when the special symbol has a low probability, there are three random numbers which are the big hits of the special symbol, and the random numbers "0 to 2" are the first random numbers for the low probability. This is stored in the table 202a (see FIG. 81 (b)). As described above, when the special symbol has a low probability, the total number of random numbers is 400 out of the total number of random numbers, and the total number of random numbers to be a jackpot is 3, so the probability of the special symbol to be a jackpot is “3/400”.

  On the other hand, when the special symbol has a high probability, there are thirty random number values which are the big hits of the special symbol, and the values “0 to 29” are stored in the first random number table 202a for the high probability time (FIG. 81 (b)). ) See). As described above, when the special symbol has a high probability, the total number of random number values is 30 out of 400, and the total number of random number values to be a jackpot is 30, so the probability of a special symbol to be a jackpot is “3/40”.

  Further, the value of the first hit type counter C2 in the pachinko machine 10 of this control example is configured as a loop counter in the range of 0 to 99, and is provided in the ROM 202 with the value of the first hit type counter C2. The big hit type is determined based on the first hit type selection table 202b (see FIG. 81 (c)). As shown in FIG. 81 (c), in the case of a special symbol jackpot, the jackpot type when the random value is “0 to 24” is “big hit A” in the first hit type counter C2. If the random number is “25 to 49”, the jackpot type is “jackpot B”. When the random number is “50 to 74”, the jackpot type is “big hit C”, and when the random number is “75 to 99”, the jackpot type is “big hit D”.

  The stop type selection counter C3 is configured to be incremented by one in order within a range of 0 to 99, for example, and to return to 0 after reaching the maximum value (that is, 99). In this control example, the stop type at the time of disconnection displayed on the third symbol display device 81 is selected by the stop type selection counter C3, and after the reach occurs, the final stop symbol is shifted by one before and after the reach symbol. "Reach out of front and rear" (e.g., 98, 99), and "reach other than front and rear out" (e.g., in a range of 90 to 97) in which the final stop symbol stops at positions other than before and after the reach symbol after reaching. Three stop (effect) patterns of "completely out of range" (for example, in the range of 0 to 89) where no reach occurs are selected. The value of the stop type selection counter C3 is updated, for example, periodically (once for each timer interrupt process in the present control example), and the value of the RAM 203 at the timing when the ball wins the first winning opening 64 or the second winning opening 640. It is stored in the special symbol holding ball storage area 203a.

  The random number value for determining the special symbol stop type from the value of the stop type selection counter C3 (random value) is set by a stop type selection table (not shown). It is provided in the ROM 202 of the device 110. Also, in this control example, this table is divided into a special symbol for the high probability case and a special symbol for the low probability case. Is changing. This is because the selection ratio of the stop type is changed according to whether the pachinko machine 10 is in the special symbol high-probability state or the special symbol low-probability state.

  For example, in the high-probability state, the jackpot is likely to occur, so that the reach effect is not selected more than necessary. Is selected, and it becomes easier to select “completely off”. In this table, the "reach out of front and rear" is narrowed to 98 and 99, and the "reach other than front and rear out" is also narrowed to 90 to 97, so that it is difficult to select "reach out of front and rear" and "reach other than front and rear out". In the low probability state, the range of the random value corresponding to the stop type of “completely out of range” is 0 to 79 in order to secure the ball entry time to the first winning opening 64 or the second winning opening 640. And a narrow low probability table is selected, and it is difficult to select “completely out of place”. In the low-probability state, the range of the random number value corresponding to the stop type of “reach other than front and rear out” is widened to 80 to 97, and “reach other than front and back out” is easily selected. Therefore, in the low probability state, it is possible to perform many reach displays with a long production time, so that the ball entry time to the first winning opening 64 or the second winning opening 640 can be secured, and the fluctuation by the third symbol display device 81 can be ensured. The display is easily performed continuously. Also in the latter table, the range of the random number value corresponding to the stop type of “out-of-reach reach” is set to 98,99.

  The variation type counter CS1 is configured to be incremented by one, for example, in the range of 0 to 198, and to return to 0 after reaching the maximum value (that is, 198). A rough display mode such as a so-called normal reach and a super reach is determined by the variation type counter CS1. The determination of the display mode is, specifically, the determination of the variation time of the symbol variation. Here, the fluctuating time refers to the time from the start of the change of the special symbol until the symbol is stopped and displayed and the symbol is fixed. For example, if a symbol is stopped and displayed for 0.4 seconds after the symbol variation of 9.6 seconds is executed and the symbol is determined, the variation time is 10 seconds (9.6 seconds + 0.4 seconds). It is written as Based on the fluctuation time, the reach type and the fine symbol fluctuation mode of the third symbol displayed on the third symbol display device 81 are determined by the sound lamp control device 113 and the display control device 114. The value of the variation type counter CS1 is updated once each time a main process (see FIG. 100) described below is executed once, and is repeatedly updated even within the remaining time in the main process. The fluctuation pattern selection table 202d (see FIGS. 82 (a) to (d)) which stores a random number value for determining one fluctuation time of the symbol fluctuation from the value (random number value) of the fluctuation type counter CS1 is the main control. It is provided in the ROM 202 of the device 110 (see FIG. 82A).

  The variation pattern selection table 202d (see FIGS. 82 (a) to (d)) includes, for example, “out (for a long time)”, “out (for a short time)”, “out of Various types of "Normal reach", various types of "Super-reach", various types of "Special out-of-reach" are specified, and the fluctuation patterns for jackpots include various types of "Normal hit", "Super-reach", and "Special". ing. Then, from the various variation patterns defined in the variation pattern selection table 202d, a variation pattern is selected according to a lottery result and a stop type (in the case of a big hit, a big hit type). The variation time of the variation pattern effect of 5 seconds to 30 seconds specified in the variation pattern selection table 202d is, for example, a variation time of 5 seconds to 30 seconds.

  Here, the types of super reach will be described. In the present control example, “super reach A”, “super reach B”, and various other super reach are defined as types of super reach. “Super reach A” is a reach effect that performs an effect based on the player pressing the frame button 22 as an example of the effect screens of FIGS. 68 to 71 described above, and “super reach B” This is a reach effect in which an effect based on the player pressing the frame button 22 is given by taking the effect screens of FIGS. 77 and 78 as an example.

  The second random number counter C4 is configured as, for example, a loop counter that is incremented by one in the range of 0 to 239, and returns to 0 after reaching the maximum value (that is, 239). When the second random number counter C4 makes one round, the value of the second initial value random number counter CINI2 at that time is read as the initial value of the second random number counter C4. In the present control example, the value of the second random number counter C4 is updated, for example, periodically at each timer interrupt processing, and is acquired when it is detected that the ball has passed the normal symbol starting port (through gate) 67. Are stored in the ordinary symbol holding ball storage area 203b of the RAM 203.

  Then, the value of the random number which is the hit of the ordinary symbol is set by the second random number table (FIG. 81 (d)) stored in the ROM 202 of the main control device, and the value of the second random number counter C4 is If it matches the value of the random number as a win set by the second random number table, it is determined that the hit is a normal symbol. In addition, the second random number table is used for a low probability of a normal symbol (a period during which the symbol is in a normal state) and for a high probability (a normal symbol is more likely to be hit) than the low probability. ), And the number of jackpot random numbers contained therein is set differently. As described above, by making the number of winning random numbers different, the probability of winning is changed between a low probability of a normal symbol and a high probability of a normal symbol.

  At the time of the low probability of the ordinary symbol, there are 24 random numbers which are the hits of the ordinary symbol, and the range is "5-28". These random numbers are stored in a second random number table for low probability. As described above, when the normal symbol has a low probability, the total number of random number values to be a big hit is 24 out of a total of 240 random numbers, so that the probability of a special symbol to be a big hit is “1/10”.

  When the pachinko machine 10 is in the low probability state of the ordinary symbol, when the ball passes through the ordinary symbol starting port 67, the value of the second random number counter C4 is acquired, and the second symbol display device 83 displays the value of the ordinary symbol. The fluctuation display is executed for 30 seconds. If the acquired value of the second random number counter C4 is in the range of “5 to 28”, it is determined that the winning has occurred, and after the variable display on the second symbol display device 83 has been completed, the stop symbol (the second symbol) ), The symbol of “」 ”is illuminated and displayed, and the second winning opening 640 is opened for“ 0.2 seconds × 1 time ”. In the present control example, when the pachinko machine 10 is in the low probability state of the ordinary symbol, the second winning opening 640 is opened only for “0.2 seconds × 1 time” when the ordinary symbol is hit. The opening time and the number of times may be set arbitrarily. For example, “0.5 seconds × 2 times” may be opened.

  On the other hand, when the ordinary symbol has a high probability, there are 200 random numbers which are the jackpots of the ordinary symbol, and the range is "5 to 204". These random numbers are stored in a random number table per symbol for high probability. As described above, when the special symbol has a low probability, the total number of random number values to be a big hit is 200 out of a total of 240 random numbers, and thus the probability of a special symbol to be a big hit is “1 / 1.2”.

  When the pachinko machine 10 is in the high probability state of the ordinary symbol, when the ball passes the ordinary symbol starting port 67, the value of the second random number counter C4 is obtained and the second symbol display device 83 displays the normal symbol. The fluctuation display is executed for 3 seconds. If the acquired value of the second random number counter C4 is in the range of “5 to 204”, it is determined that the winning has occurred, and after the variable display on the second symbol display device 83 has been completed, the stop symbol (the second symbol) ), The symbol of “」 ”is illuminated and displayed, and the second winning opening 640 is opened“ 1 second × 2 times ”. As described above, when the normal symbol has a high probability, the time of the variable display becomes very short as “30 seconds → 3 seconds” as compared with when the normal symbol has a low probability, and the opening period of the second winning opening 640 is further reduced. Is extremely long, such as “0.2 seconds × 1 time → 1 second × 2 times”, so that the ball easily enters the second winning opening 640. The ROM 202 stores a table (not shown) that stores a random number value for determining whether or not a normal symbol has been hit based on the value of the second random number counter C4 (random number value). In the present control example, when the pachinko machine 10 is in the high probability state of the ordinary symbol, the second winning opening 640 is opened by “1 second × 2 times” when the ordinary symbol is hit. And the number of times may be set arbitrarily. For example, “3 seconds × 3 times” may be opened.

  The second initial value random number counter CINI2 is configured as a loop counter that is updated in the same range as the second random number counter C4 (value = 0 to 239), and is updated once every timer interrupt processing (see FIG. 92). At the same time, it is repeatedly updated within the remaining time of the main processing (see FIG. 100).

  As described above, the RAM 203 is provided with various counters and the like, and the main control device 110 performs the jackpot lottery and the display of the first symbol display device 37 and the third symbol display device 81 in accordance with the values of the counters and the like. The main processing of the pachinko machine 10 such as setting and lottery of the display result on the second symbol display device 83 can be executed.

  Returning to FIG. 80, the description will be continued. The RAM 203 includes, in addition to the various counters shown in FIG. 79, a stack area in which the contents of internal registers of the MPU 201 and a return address of a control program executed by the MPU 201 are stored, various flags and counters, I / Os, and the like. And a work area (work area) in which the value is stored.

  The RAM 203 has a configuration in which a backup voltage is supplied from the power supply 115 to retain data (backup) even after the power of the pachinko machine 10 is cut off, and all data stored in the RAM 203 is backed up. .

  When the power is shut down due to the occurrence of a power failure or the like, the stack pointer and the value of each register at the time of the power shutdown (including when a power failure occurs; the same applies hereinafter) are stored in the RAM 203. On the other hand, when the power is turned on (including turning on the power by turning off the power, the same applies hereinafter), the state of the pachinko machine 10 is returned to the state before the power was turned off based on the information stored in the RAM 203. The writing to the RAM 203 is executed when the power is turned off by the main process (see FIG. 100), and the restoration of each value written to the RAM 203 is executed in the startup process when the power is turned on (see FIG. 99). The power failure signal SG1 from the power failure monitoring circuit 252 is input to the NMI terminal (non-maskable interrupt terminal) of the MPU 201 when the power is cut off due to a power failure or the like, and the power failure signal SG1 is output to the MPU 201. , An NMI interrupt process (see FIG. 98) as a power failure process is immediately executed.

  In addition, as shown in FIG. 50, the RAM 203 stores a special symbol retaining ball storage area 203a, a normal symbol retaining ball storage area 203b, a special symbol retaining ball number counter 203c, and a normal symbol retaining ball number counter 203d. It has a flag 203e, a time saving counter 203f, a prefetch certainty changing flag 203g, a counter buffer 203h, and a memory area 203z.

  The special symbol holding ball storage area 203a is a storage area for the first winning opening 64 and the second winning opening 640, and includes one execution area and four holding areas (first holding area to fourth holding area). Each of these areas stores a value of a first random number counter C1, a first type counter C2, and a stop type selection counter C3.

  More specifically, at the timing when the ball wins the first winning opening 64 or the second winning opening 640 (start winning), each value of each of the counters C1 to C3 is acquired, and the acquired data is four times. Of the vacant areas of the reserved areas (the first reserved area to the fourth reserved area), the areas are stored in order from the area having the smallest area number (first to fourth). That is, the data corresponding to the winning in time is stored in an area having a smaller area number, and the data corresponding to the winning in time is stored in the reserved first area. If data is stored in all four holding areas, nothing is newly stored.

  Thereafter, when a special symbol lottery is performed in the main control device 110, the values of the counters C1 to C3 stored in the reserved first area of the special symbol reserved ball storage area 203a are shifted to the execution area. Then, based on each value of each of the counters C1 to C3 stored in the execution area, a determination such as a lottery of a special symbol is made.

  When data is shifted from the reserved first area to the execution area, the reserved first area becomes empty. Therefore, there is a shift process of packing the winning data stored in the other reserved areas (the reserved second area to the reserved fourth area) into the reserved area having the smaller area number (the reserved first area to the reserved third area). Done. In the present control example, in the special symbol reserved ball storage area 203a, data shift is performed only for the reserved areas (second reserved area to fourth reserved area) in which winning data is stored.

  In the pachinko machine 10, the ball wins (starts winning) in the first winning opening 64 or the second winning opening 640, and as soon as each value of each of the counters C1 to C3 is obtained in accordance with the starting winning, the ball is turned on. A winning information command including the value is transmitted to the sound lamp control device 113. When the winning information command is received by the sound lamp control device 113, the sound lamp controlling device 113 extracts each value of each of the counters C1 to C3 from the winning information command, and uses them as winning information as a winning information storage area of the RAM 233. 223a.

  The normal symbol holding ball storage area 203b has one execution area and four holding areas (first holding area to fourth holding area), similarly to the special symbol holding ball storage area 203a. Each of these areas stores a second random number counter C4.

  More specifically, the value of the counter C4 is acquired at the timing when the ball has passed the ordinary symbol starting port 67, and the acquired data is stored in the four holding areas (first holding area to fourth holding area). Among the vacant areas, the area numbers (first to fourth) are stored in order from the smallest area. That is, similarly to the special symbol reserved ball storage area 203a, the data corresponding to the winning is stored while the winning order is maintained. If data is stored in all four holding areas, nothing is newly stored.

  Thereafter, in the main control device 110, when the lottery for the normal symbol is performed, the value of the counter C4 stored in the first reserved area of the ordinary symbol reserved ball storage area 203b is shifted to the execution area ( Is moved), and based on the value of the counter C4 stored in the execution area, a determination such as a lottery for a normal symbol is made.

  Note that when the data is shifted from the reserved first area to the execution area, the reserved first area becomes empty, so that the prize winning data stored in the other reserved areas is stored in the same manner as the special symbol reserved ball storage area 203a. , A shift process is performed to fill the reserved area with the smaller area number. The data shift is also performed only for the reserved area in which the winning data is stored.

  The special symbol holding ball number counter 203c is a variable display of a special symbol (first symbol) performed by the first symbol display device 37 based on a ball (start winning) into the first winning port 64 or the second winning port 640. This is a counter for counting the number of reserved balls (the number of times of standby) of (variable display performed by the third symbol display device 81) up to four times. The special symbol reserved ball count counter 203c has an initial value set to zero, and each time a ball enters the first winning port 64 or the second winning port 640 and the number of reserved balls in the variable display increases, One is added to the maximum value 4 (see S404 in FIG. 95). On the other hand, the special symbol reserved ball number counter 203c is decremented by one each time a new variable display of the first special symbol is executed (see S205 in FIG. 93).

  The value of this special symbol reserved ball number counter 203c (the number of times N of the variable display in the special symbol is retained) is notified to the sound lamp control device 113 by a reserved ball number command (see S206 in FIG. 93 and S405 in FIG. 95). The reserved ball count command is a command transmitted from the main control device 110 to the sound lamp control device 113 each time the value of the special symbol reserved ball count counter 203c is changed.

  Each time the value of the special symbol reserved ball number counter 203c is changed, the sound ramp control device 113 uses the reserved ball number command transmitted from the main control device 110 to display the variable display reserved ball retained in the main control device 110. You can get the value of the number itself. As a result, the number of retained balls of the variable display, which is managed by the special symbol reserved ball number counter 223b of the audio lamp control device 113, is changed to the actual number of retained balls of the variable display retained by the main control device 110 due to noise or the like. Even if it has shifted, the shift can be corrected by the next received ball count command.

  The voice lamp control device 113 manages the number of reserved balls based on the reserved ball number command, and displays the reserved ball number for notifying the display control device 114 of the reserved ball number every time the reserved ball number changes. Send the ball count command. The display control device 114 displays the reserved ball count symbol on the third symbol display device 81 based on the reserved ball count notified by the display reserved ball count command.

  The ordinary symbol holding ball number counter 203d maximizes the number of waiting balls (the number of waiting times) of the variable display of the ordinary symbol (second symbol) performed by the second symbol display device 83 based on the passage of the ball at the ordinary symbol starting port 67. This is a counter that counts up to four times. The normal symbol reserved ball number counter 203d has an initial value set to zero, and each time a ball passes through the regular symbol start port 67 and the number of retained balls of the variable display increases, one is added to the maximum value of four. (See S604 in FIG. 97). On the other hand, the normal symbol holding ball number counter 203d is decremented by one each time a new variable display of the normal symbol (second symbol) is executed (see S505 in FIG. 96).

  When the ball passes through the ordinary symbol starting port 67, if the value of the ordinary symbol retaining ball number counter 203d (the number of times M of the variable display in the ordinary symbol is retained) is less than 4, the value of the second random number counter C4 is increased. The acquired data is stored in the ordinary symbol holding ball storage area 203b (S605 in FIG. 97). On the other hand, when the ball passes through the ordinary symbol starting port 67, if the value of the ordinary symbol retaining ball number counter 203d is 4, nothing is newly stored in the ordinary symbol retaining ball storage area 203b (see FIG. 97). S603: No).

  The probable changing flag 203e is a flag indicating whether or not the pachinko machine 10 is in the probable changing state of the special symbol (high probability state of the special symbol). If the value of the probable changing flag 203e is on, the pachinko machine 10 is turned off. It indicates that the special symbol is in the probable state, and if the value of the probable changing flag 203e is off, it indicates that the pachinko machine 10 is in the normal state of the special symbol (low probability state of the special symbol). The initial value of the probable changing flag 203e is set to off, and the main controller 110 sets the timing at which the specific winning opening (large opening) 65a closes in the final round of the jackpot (ie, the end timing of the jackpot) in the main round of the jackpot. A value corresponding to the jackpot type is set. Specifically, in the case of "big hit type A" or "big hit type B", ON is set, and in the case of "big hit type C" and "big hit type D", OFF is set.

  When the special symbol change start process (see FIG. 59) is executed by the MPU 201, a special symbol lottery is performed. In the special symbol change start process, the value of the probable changing flag 203e is referred to, and if the value is on, a special symbol lottery is performed based on the high probability determination value in the first random number table 202a. On the other hand, if the value of the probable changing flag 203e is off, a special symbol lottery is performed based on the low probability determination value in the first random number table 202a.

  The time reduction counter 203f is a counter that indicates whether or not the pachinko machine 10 is in the normal symbol time reduction state. If the value of the time reduction counter 203f is 1 or more, the pachinko machine 10 is in the normal symbol time reduction state. If the value of the counter 203f during time reduction is 0, it indicates that the pachinko machine 10 is in a normal state of a normal symbol. The initial value of the time reduction counter 203f is set to zero, and the timing corresponding to the type of the jackpot at the closing timing of the specific winning opening (large opening opening) 65a (ie, the end timing of the jackpot) in the last round of the jackpot. Is set. Specifically, in the case of "big hit type A" or "big hit type C", 100 is set, and in the case of "big hit type B" or "big hit type D", 0 is set. Thereafter, 1 is decremented each time the special symbol fluctuating effect ends until the value of the counter 203f during working hours decreases to 0 (S223 in FIG. 57).

  When a lottery for a normal symbol is performed, the value of the counter 203f during time saving is referred to, and if the value is 1 or more, a lottery for a normal symbol is performed based on a random number per symbol symbol for a high probability time. On the other hand, if the value of the counter 203f during time-saving is 0, the lottery of the ordinary symbols is performed based on the random number table per symbol for low probability time (see S710 and S711 in FIG. 62).

  As described above, the counter buffer 203h is a buffer area used for counting each counter value.

  The other memory area 203z is provided as an area for storing data other than the above-described data, and is an area for temporarily storing other counter values used by the MPU 201 of the main control device 110.

  Next, the ROM 202 provided in the MPU 201 of the main control device 110 will be described with reference to FIGS. The ROM 202 stores various control programs executed by the MPU 201 and fixed value data as described above.

  FIG. 81A is a diagram schematically showing the contents of the ROM 202 provided in the main control device 110. As shown in FIG. 81A, the ROM 202 is provided with at least a first random number table 202a, a first random type selection table 202b, a second random number table 202c, and a variation pattern selection table 202d. .

  The first hit random number table 202a (see FIG. 81 (b)) is a table in which the value of the random number which is the big hit of the special symbol is defined as described above. When the random number value defined in the first random number table 202a matches the value of the first random number counter C1, it is determined that the special symbol is a big hit. The first random number table 202a includes a table (a first random number table 202a for low probability) for determining whether or not a special symbol is a big hit when the special symbol has a low probability. There is provided a table (first random number table 202a for high probability) for discriminating whether or not a special symbol is a jackpot at the time of probability, and the number of jackpot random numbers included in each table is different. I have. In this way, by making the number of random numbers which are big hits different, the probability of big hits is changed between a low probability of a special symbol and a high probability of a special symbol.

  The first hit type selection table 202b (see FIG. 81 (c)) is a data table in which the determination value of the first hit type counter C2 for determining the big hit type is set for each big hit type. . As shown in FIG. 81 (c), in the first hit type selection table 202b, the big hit A, the big hit B, the big hit C, and the big hit D are set to be selectable, respectively. The value “0-24” of the type counter C2, “25-49” as the jackpot B determination value, “50-74” as the jackpot C determination value, and “74-99” as the jackpot D determination value are set. I have.

  The second hit random number table 202c (see FIG. 81 (d)) is a data table in which hit determination values of ordinary symbols are stored. As shown in FIG. 81 (d), when the normal symbol has a low probability (in the normal state of the ordinary symbol), the value of the second random number counter C3 stored in the second random number counter buffer is in the range of 5-28. In the case of, it is determined that the hit is a normal symbol. As described above, when it is determined that a normal symbol has been hit, after the variable display on the second symbol display device 83 is completed, a symbol of “」 ”is displayed as a stopped symbol (second symbol) while being lit and displayed. The electric accessory 640a attached to the second winning opening 640 is opened for “0.2 seconds × 1 time”.

  On the other hand, at the time of the high probability of the ordinary symbol (during the time saving state of the ordinary symbol), when the value of the second random number counter C3 is in the range of 5 to 204, it is determined that the symbol is a normal symbol hit. As described above, when it is determined that a normal symbol has been hit, after the variable display on the second symbol display device 83 is completed, a symbol of “」 ”is displayed as a stopped symbol (second symbol) while being lit and displayed. Then, the electric accessory 640a attached to the second winning opening 640 is opened “1 second × 2 times”.

  Next, the variation pattern selection table 202d will be described with reference to FIG. The fluctuation pattern selection table 202d (see FIG. 82A) is a data table used to determine the display mode of the fluctuation pattern, and the display mode is defined for each value of the fluctuation type counter CS1. A plurality of different tables corresponding to the special symbol lottery results are defined in the variation pattern selection table 202d. More specifically, as shown in FIG. 82 (a), the variation pattern selection table 202d includes a special jackpot variation pattern table 202d1 (see FIG. 82 (b)) when the hit determination result is a big hit, and The result is out of range, and when the game is in the normal game state, a special (normal) variation pattern table 202d2 (see FIG. 82 (c)) is used. Each of them is at least constituted by a use (probable change) variation pattern selection table 202d3 (see FIG. 82D).

  Here, the various super reach selected by each variation pattern table includes “super reach A”, “super reach B”, or other super reach selected by the value of the variation type counter CS1. The type of the super reach selected by the variation pattern table is transmitted from the main control device 110 to the voice control device 113, and is transmitted from the voice control device 113 to the display control device 114, so that various super reach effects are executed. Is done.

  Next, the ROM 222 and the RAM 223 of the audio lamp control device 113 will be described with reference to FIG. The ROM 222 of the audio ramp control device 113 stores at least a fluctuation pattern table. The variation pattern table will be briefly described because it is already known. However, based on the variation pattern command output from the main controller 110, the rough variation contents (variation time, variation type) indicated by the variation pattern command are described. (Reach, departure, etc.)). As a result, various variations can be determined.

  As shown in FIG. 83, the RAM 223 of the sound lamp control device 113 includes a winning information storage area 223a, a special symbol holding ball counter 223b, a change start flag 223c, a stop type selection flag 223d, At least a flag 223e, a frame SW valid period 223f, a replacement timing 223g, a replacement flag 223h, an effect counter 223i, and another memory area 223z are provided.

  The prize information storage area 223a has one execution area and four areas (first area to fourth area). Each of these areas has a counter C1 to C3 as prize information. Each value is stored. In the present pachinko machine 10, when the main controller 110 wins a start, each value of the first random number counter C1, the first hit type counter C2, and the stop type selection counter C3 acquired according to the start winning is obtained. The main controller 110 predicts (estimates) various information (acceptance, stop type, variation pattern) obtained when a special symbol corresponding to the start winning is selected, and the predicted various information is The main controller 110 notifies the sound lamp controller 113 of a winning information command.

  When the prize information command is received, the sound lamp control device 113 extracts various information (acceptance, stop type, change pattern) notified by the prize information command, as the prize information, and divides the prize information into the prize information. It is stored in the storage area 223a. More specifically, the extracted winning information is stored in ascending order of the area numbers (first to fourth) among the vacant areas of the four areas (first area to fourth area). Is done. That is, the data corresponding to the winning in time is stored in the area having the smaller area number, and the data corresponding to the winning in time is stored in the first area.

  The special symbol retaining ball number counter 223b is a variable effect (variable display) performed by the first symbol display device 37 (and the third symbol display device 81), similarly to the special symbol retaining ball number counter 203c of the main controller 110. The counter is a counter that counts up to four times the number of suspended balls (the number of times of waiting) of the variable effect that is suspended in the main control device 110.

  As described above, the sound lamp control device 113 cannot directly access the main control device 110 and acquire the value of the special symbol reserved ball count counter 203c stored in the RAM 203 of the main control device 110. Therefore, the sound lamp control device 113 counts the number of reserved balls based on the reserved ball number command transmitted from the main control device 110, and manages the reserved ball number with the special symbol reserved ball number counter 223b. Has become.

  Specifically, the main control device 110 adds the number of reserved balls of the variable display by entering the first winning opening 64 or the second winning opening 640, or the first special symbol in the main controlling device 110. When the change display is executed and the number of retained balls is subtracted, a retained ball number command indicating the value of the special symbol retained ball number counter 203c after addition or subtraction is transmitted to the voice lamp control device 113.

  When receiving the reserved ball count command transmitted from the main control device 110, the sound ramp control device 113 obtains the value of the special symbol reserved ball count counter 203c of the main control device 110 from the reserved ball count command, and It is stored in the symbol holding ball number counter 223b (see S1308 in FIG. 104). As described above, the voice lamp control device 113 updates the value of the special symbol reserved ball number counter 223b in accordance with the reserved ball number command transmitted from the main control device 110. The value can be updated while synchronizing with 203c.

  The value of the special symbol reserved ball number counter 223b is used for displaying the reserved ball number symbol on the third symbol display device 81. That is, in response to the reception of the reserved ball number command, the sound lamp control device 113 stores the reserved ball number indicated by the command in the special symbol reserved ball number counter 223b, and also stores the stored special symbol reserved ball number counter 223b. Is transmitted to the display control device 114 to notify the display control device 114 of the value.

  When the display control device 114 receives the display reserved ball number command, the value of the reserved ball number indicated by the command, that is, the reserved ball number corresponding to the value of the special symbol reserved ball number counter 223b of the voice lamp control device 113, is displayed. The drawing of the image is controlled so that the symbol is displayed in the lower display area Ds of the third symbol display device 81. As described above, the value of the special symbol reserved ball number counter 223b is changed in synchronization with the special symbol reserved ball number counter 203c of the main controller 110. Therefore, the number of reserved ball count symbols displayed in the lower display area Ds of the third symbol display device 81 can also be changed while synchronizing with the value of the special symbol reserved ball count counter 203c of the main control device 110. . Therefore, the third symbol display device 81 can accurately display the number of the reserved balls for which the variable display is suspended.

  The fluctuation start flag 223c is turned on when a fluctuation pattern command transmitted from the main control device 110 is received (see S1302 in FIG. 104), and turned off when the fluctuation display is set on the third symbol display device 81. (See S1402 in FIG. 105). When the variation start flag 223c is turned on, a variation pattern command for display is set based on the variation pattern extracted from the received variation pattern command.

  The display variation pattern command set here is stored in a command transmission ring buffer provided in the RAM 223, and is included in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the display control device 114. The display control device 114 receives the display variation pattern command, so that the third symbol display device 81 performs the variation display of the third symbol in the variation pattern indicated by the display variation pattern command. The display control of the variable effect is started.

  The stop type selection flag 223d is turned on when a stop type command transmitted from the main control device 110 is received (see S1305 in FIG. 104), and turned off when the stop type is set in the third symbol display device 81. (See S1410 in FIG. 105). When the stop type selection flag 223d is turned on, the stop type (big hit type in the case of a big hit) extracted from the received stop type command is set. Further, the set stop type is notified to the display control device 114 by a display stop type command. The display control device 114 displays the stop effect of the variable effect such that the stop symbol corresponding to the stop type indicated by the display stop type command received from the audio lamp control device 113 is stopped and displayed on the third symbol display device 81. Is controlled.

  The power-off flag 223e is set to ON by receiving a command indicating power failure detection from the main control device 110. Thereafter, in the startup process, when it is determined that the power-off flag 223e is on, the work area of the RAM is cleared and set to off.

  The frame SW valid period 223f is a counter for indicating a period in which the effect based on the operation of the frame button 22 is possible in the effect of the super reach A or the super reach B. This frame SW valid period 223f is set when Super Reach A or Super Reach B is executed, and is executed every 1 ms in the main process of the sound lamp control device 113. SW input monitoring and effect processing (see FIG. 106). Is subtracted by one.

  The replacement timing 223g indicates a timing for replacing with an effect for notifying a jackpot in spite of the fact that the frame button was not pressed in the super reach B. The replacement timing 223g is referred to in the super reach B operation process (see FIG. 109), and is reset based on the number of executions of the effective effect based on the pressing of the frame button 22.

  The replacement flag 223h is set to ON when a replacement effect is set when it is determined that the replacement timing has elapsed in the super reach B operation process (see FIG. 109). Thus, it is determined that the replacement timing has passed once after the replacement effect has been set, thereby preventing the replacement effect from being set again. This replacement flag 223h is turned off (initialized) when the frame SW validity period becomes zero.

  The effect counter 223i is updated in the main process (see FIG. 103) of the sound lamp control device 113. The effect counter 223i selects an effect mode based on the pressing of the frame button 22.

  The other memory area 223z is provided as an area for storing data other than the above-described data, and is an area for temporarily storing other counter values used by the MPU 221 of the audio ramp control device 113.

  The RAM 223 further includes a command storage area (not shown) for temporarily storing a command received from the main control device 110 until a process corresponding to the command is performed. The command storage area is formed by a ring buffer, and data is read and written by a FIFO (First In First Out) method. When the command determination process (see FIG. 104) of the sound ramp processing device 113 is executed, the command stored first among the unprocessed commands stored in the command storage area is read, and the command determination process performs The command is analyzed, and processing according to the command is performed.

  The display control device 114 is connected to the voice lamp control device 113 and the third symbol display device 81, and based on a command received from the voice lamp control device 113, displays the variation of the third symbol on the third symbol display device 81 (variation). Direction) and a continuous announcement effect. Details of the display control device 114 will be described later with reference to FIG.

  The power supply unit 115 includes a power supply unit 251 for supplying power to each unit of the pachinko machine 10, a power failure monitoring circuit 252 for monitoring power interruption due to a power failure or the like, and a RAM provided with a RAM erase switch 122 (see FIG. 3). And an erase switch circuit 253. The power supply unit 251 is a device that supplies a required operating voltage to each of the control devices 110 to 114 and the like via a power supply path (not shown). As an outline, the power supply unit 251 takes in a voltage of AC 24 volts supplied from the outside, and outputs a voltage of 12 volts for driving various switches such as various switches 208, a solenoid such as the solenoid 209, a motor, and the like. A voltage of 5 volts for logic, a backup voltage for RAM backup, and the like are generated, and these 12 volts, 5 volts and backup voltage are supplied to necessary voltages to the control devices 110 to 114 and the like.

  The power failure monitoring circuit 252 is a circuit for outputting a power failure signal SG1 to each NMI terminal of the MPU 201 of the main control device 110 and the MPU 211 of the payout control device 111 when the power is cut off due to the occurrence of a power failure or the like. The power failure monitoring circuit 252 monitors a DC stable voltage of 24 volts, which is the maximum voltage output from the power supply unit 251, and determines that a power failure (power interruption, power interruption) has occurred if this voltage falls below 22 volts. Then, the power outage signal SG1 is output to the main control device 110 and the payout control device 111. Based on the output of the power failure signal SG1, the main control device 110 and the payout control device 111 recognize the occurrence of the power failure and execute the NMI interrupt processing. Note that, even after the DC stable voltage of 24 volts becomes less than 22 volts, the power supply unit 251 outputs the voltage of 5 volts, which is the drive voltage of the control system, for a time sufficient for executing the NMI interrupt processing. Is maintained at a normal value. Therefore, main controller 110 and payout controller 111 can normally execute and complete the NMI interrupt process (see FIG. 98).

  The RAM erasure switch circuit 253 is a circuit for outputting a RAM erasure signal SG2 for clearing the backup data to the main controller 110 when the RAM erasure switch 122 (see FIG. 3) is pressed. The main controller 110 clears the backup data when the RAM erasing signal SG2 is input when the power of the pachinko machine 10 is turned on, and also controls the payout control device 111 to execute a payout initialization command for clearing the backup data. Transmit to the device 111.

  Next, an electrical configuration of the display control device 114 will be described with reference to FIG. FIG. 84 is a block diagram showing an electrical configuration of the display control device 114. The display control device 114 includes an MPU 231, a work RAM 233, a character ROM 234, a resident video RAM 235, a normal video RAM 236, an image controller 237, an input port 238, an output port 239, and bus lines 240 and 241. have.

  The input side of the input port 238 is connected to the output side of the audio lamp control device 113, and the output side of the input port 238 is connected to the MPU 231, the work RAM 233, the character ROM 234, and the image controller 237 via the bus line 240. . The resident video RAM 235 and the normal video RAM 236 are connected to the image controller 237, and an output port 239 is connected via a bus line 241. The third symbol display device 81 is connected to the output side of the output port 239.

  In addition, the pachinko machine 10 is a symbol displayed on the third symbol display device 81, even if it is a different model having different lottery probabilities of special symbol jackpots and different numbers of prize balls paid out in one special symbol jackpot. Since there are models having exactly the same configuration, the display control device 114 is made a common component to reduce costs.

  Hereinafter, the MPU 231, the character ROM 234, the image controller 237, the resident video RAM 235, and the normal video RAM 236 will be described first, and then the work RAM 233 will be described.

  First, the MPU 231 controls the display contents of the third symbol display device 81 based on the display variation pattern command output from the audio lamp control device 113 based on the variation pattern command of the main control device 110. The MPU 231 has a built-in instruction pointer 231a, reads and fetches an instruction code stored at an address indicated by the instruction pointer 231a, and executes various processes according to the instruction code. The MPU 231 is configured to perform a system reset from the power supply device 115 immediately after power-on (including power recovery from a power failure; the same applies hereinafter). When the system reset is released, the instruction pointer 231 a Is automatically set to “0000H” by the hardware of the MPU 231. Each time the instruction code is fetched, the value of the instruction pointer 231a is incremented by one. When the MPU 231 executes an instruction pointer setting instruction, the pointer value specified by the setting instruction is set in the instruction pointer 231a.

  Although details will be described later, in this control example, a control program executed by the MPU 231 and various fixed value data used in the control program are provided in a dedicated program ROM like a conventional gaming machine. Instead, the character data is stored in a character ROM 234 provided to store image data to be displayed on the third symbol display device 81.

  As will be described later in detail, the character ROM 234 is constituted by a NAND flash memory 234a capable of increasing the capacity with a small area. Thereby, not only the image data but also the control program and the like can be sufficiently stored. If a control program and the like are stored in the character ROM 234, there is no need to provide a dedicated program ROM for storing the control program and the like. Therefore, the number of components in the display control device 114 can be reduced, the manufacturing cost can be reduced, and an increase in the failure rate due to an increase in the number of components can be suppressed.

  On the other hand, the NAND flash memory has a problem that the reading speed is reduced particularly when random access is performed. For example, in a case where data arranged continuously on a plurality of pages is read, high-speed reading of data on the second and subsequent pages is possible, but an address is specified for reading data of the first page. It takes a long time from when the data is output until the data is output. In addition, when data that is not continuous is read, a long time is required every time the data is read. As described above, since the reading speed of the NAND flash memory is low, if the MPU 231 is configured to directly read the control program from the character ROM 234 and execute various processes, it takes time to read the instructions constituting the control program. However, even if a high-performance processor is used as the MPU 231, the processing performance of the display control device 114 may be deteriorated.

  Therefore, in the present control example, when the system reset of the MPU 231 is released, first, the control program stored in the NAND flash memory 234a of the character ROM 234 is transferred to the work RAM 233 provided for temporarily storing various data. And store. Then, the MPU 231 executes various processes according to the control program stored in the work RAM 233. The work RAM 233 is constituted by a DRAM (Dynamic RAM), as will be described later, and reads and writes data at a high speed. Therefore, the MPU 231 can read instructions constituting the control program without delay. Therefore, high processing performance can be maintained in the display control device 114, and diversified and complicated effects can be easily executed using the third symbol display device 81.

  The character ROM 234 is a memory that stores a control program executed by the MPU 231 and data of an image displayed on the third symbol display device 81, and is connected to the MPU 231 via the bus line 240. The MPU 231 directly accesses the character ROM 234 via the bus line 240 after the system reset is released, and transfers the control program stored in the second program storage area 234a1 of the character ROM 234 to the program storage area 233a of the work RAM 233. An image controller 237 is also connected to the bus line 240. The image controller 237 stores image data stored in a character storage area 234a2 (described later) of the character ROM 234 into a resident video RAM 235 connected to the image controller 237, The data is transferred to the normal video RAM 236.

  The character ROM 234 is configured by modularizing a NAND flash memory 234a, a ROM controller 234b, a buffer RAM 234c, and a NOR ROM 234d.

  The NAND flash memory 234a is a nonvolatile memory provided as a main storage unit in the character ROM 234, and stores most of the control program executed by the MPU 231 and fixed value data for driving the third symbol display device 81. It has at least a second program storage area 234a1 for storing, and a character storage area 234a2 for storing data of an image (such as a character) to be displayed on the third symbol display device 81.

  Here, the NAND flash memory has a feature that a large storage capacity can be obtained in a small area, and the capacity of the character ROM 234 can be easily increased. Thus, in the present pachinko machine, by using the NAND flash memory 234a having a capacity of, for example, 2 gigabytes, many images can be stored in the character storage area 234a2 as images to be displayed on the third symbol display device 81. it can. Therefore, in order to further enhance the interest of the player, the image displayed on the third symbol display device 81 can be diversified and complicated.

  Further, the NAND flash memory 234a can further store a control program and fixed value data in the second program storage area 234a1 in a state where much image data is stored in the character storage area 234a2. As described above, the control program and the fixed value data are provided for storing the data of the image to be displayed on the third symbol display device 81 without providing and storing the dedicated program ROM as in a conventional gaming machine. Since the number of components in the display control device 114 can be reduced, the manufacturing cost can be reduced, and an increase in the failure rate due to an increase in the number of components can be suppressed.

  The ROM controller 234b is a controller for controlling the operation of the character ROM 234. For example, based on an address transmitted from the MPU 231 or the image controller 237 via the bus line 240, the corresponding data from the NAND flash memory 234a or the like is read. And outputs it to the MPU 231 or the image controller 237 via the bus line 240.

  Here, due to the nature of the NAND flash memory 234a, a relatively large number of error bits (bits in which erroneous data has been written) occur when writing data, or a defective data block in which data cannot be written occurs. Or Therefore, the ROM controller 234b performs a known error correction on the data read from the NAND flash memory 234a, and reads and writes the data to the NAND flash memory 234a while avoiding the defective data block. Executes the conversion of the data address.

  Since the ROM controller 234b performs error correction on the data read from the NAND flash memory 234a including the error bit, even if the NAND flash memory 234a is used as the character ROM 234, the error is corrected based on the erroneous data. Thus, it is possible to prevent the MPU 231 from performing processing and the image controller 237 from generating various images.

  Further, the defective data block of the NAND flash memory 234a is analyzed by the ROM controller 234b, and access to the defective data block is avoided, so that the MPU 231 and the image controller 237 use different defective data for each NAND flash memory 234a. Access to the character ROM 234 can be easily performed without considering the address position of the block. Therefore, even when the NAND flash memory 234a is used as the character ROM 234, it is possible to suppress complicated access control to the character ROM 234.

  The buffer RAM 234c is a memory used as a buffer for temporarily storing data read from the NAND flash memory 234a. When an address allocated to the character ROM 234 is specified from the MPU 231 or the image controller 237 via the bus line 240, the ROM controller 234b operates for one page (for example, 2 kilobytes) including data corresponding to the specified address. Is set in the buffer RAM 234c. If it is not set, the data of one page (for example, 2 kilobytes) including the data corresponding to the designated address is read from the NAND flash memory 234a (or the NOR ROM 234d) and temporarily set in the buffer RAM 234c. I do. Then, the ROM controller 234b performs a known error correction process, and outputs data corresponding to the designated address to the MPU 231 and the image controller 237 via the bus line 240.

  The buffer RAM 234c is composed of two banks, and one bank of data of the NAND flash memory 234a can be set per bank. Accordingly, the ROM controller 234b outputs data of the NAND flash memory 234a to the outside using the other bank while the data is set in one bank, or specifies the data from the MPU 231 or the image controller 237. One page of data including the data corresponding to the specified address is transferred from the NAND flash memory 234a to one bank and set, and the data corresponding to the address specified by the MPU 231 or the image controller 237 is transferred to the other bank. The process of reading out from the bank and outputting it to the MPU 231 and the image controller 237 can be processed in parallel. Therefore, the response in reading the character ROM 234 can be improved.

  The NOR ROM 234d is a non-volatile memory provided as a sub storage unit in the character ROM 234, and has a much smaller capacity (for example, 2 kilobytes) than the NAND flash memory 234a for the purpose of complementing the NAND flash memory 234a. ). In the NOR ROM 234d, among the control programs stored in the character ROM 234, the programs not stored in the second program storage area 234a1 of the NAND flash memory 234a, specifically, the MPU 231 first stores the program after the system reset is released. At least a first program storage area 234d1 for storing a part of the boot program to be executed is provided.

  The boot program is a control program for activating the display control device 114 so that various controls on the third symbol display device 81 can be executed. After the system reset is released, the MPU 231 first executes the boot program. Thus, the display control device 114 can be put into a state in which various controls can be executed. The first program storage area 234d1 has a capacity of one bank of the buffer RAM 234c (that is, one page of the NAND flash memory 234a) of the boot program, and should be processed first by the MPU 231 after the system reset is released. A predetermined number of instructions (for example, if the capacity of one page is 2 kilobytes, instructions for 1024 words (1 word = 2 bytes)) are stored. The number of instructions of the boot program stored in the first program storage area 234d1 only needs to be smaller than the capacity of one bank of the buffer RAM 234c, and is appropriately set according to the specifications of the display control device 114. There may be.

  When the system reset is released, the MPU 231 sets the value of the instruction pointer 231a to “0000H” by hardware and specifies the address “0000H” indicated by the instruction pointer 231a to the bus line 240. It is configured. On the other hand, when the ROM controller 234b of the character ROM 234 detects that the address “0000H” is specified on the bus line 240, the ROM controller 234b stores the boot program stored in the first program storage area 234d1 of the NOR type ROM 234d in one bank of the buffer RAM 234c. And outputs the corresponding data (instruction code) to the MPU 231.

  When the MPU 231 fetches the instruction code received from the character ROM 234, it executes various processes according to the fetched instruction code, adds one to the instruction pointer 231a, and sends the address indicated by the instruction pointer 231a to the bus line 240. To specify. Then, while the address specified by the bus line 240 is an address indicating the program stored in the NOR-type ROM 234d, the ROM controller 234b of the character ROM 234 selects a program from among the programs previously set from the NOR-type ROM 234d to the buffer RAM 234c. , Reads the instruction code at the corresponding address from the buffer RAM 234c, and outputs it to the MPU 231.

  Here, in the present control example, instead of storing the entire control program in the NAND flash memory 234a, a predetermined number of instructions to be processed first by the MPU 231 after the system reset is released are replaced by the NOR ROM 234d in the boot program. Is stored for the following reason. That is, as described above, the NAND flash memory 234a requires a large amount of time from when an address is specified to when data is output in reading data of the first page, which is unique to the NAND flash memory. There's a problem.

  When all the control programs are stored in such a NAND flash memory 234a, the address “0000H” is designated from the MPU 231 via the bus line 240 to fetch the instruction code to be executed first by the MPU 231 after the system reset is released. In this case, the character ROM 234 must read out one page of data including the data (instruction code) corresponding to the address “0000H” from the NAND flash memory 234a and set the data in the buffer RAM 234c. Then, due to the nature of the NAND flash memory 234a, a great amount of time is required from the reading to the setting to the buffer RAM 234c. Therefore, the MPU 231 specifies the address “0000H” and then executes the instruction Spend a lot of time waiting to receive the code. Therefore, since the time required to start the MPU 231 becomes longer, there is a problem that the control of the third symbol display device 81 in the display control device 114 may not be started immediately.

  On the other hand, since the NOR ROM is a memory from which data can be read at high speed, a predetermined number of instructions of the boot program to be processed first by the MPU 231 after the system reset is released are stored in the NOR ROM 234d. When the address “0000H” is designated from the MPU 231 via the bus line 240 after the system reset is released, the character ROM 234 immediately stores the boot program stored in the first program storage area 234d1 of the NOR type ROM 234d in the buffer RAM 234c. And the corresponding data (instruction code) can be output to the MPU 231. Therefore, the MPU 231 can receive the instruction code corresponding to the address “0000H” in a short time after specifying the address “0000H”, and can start the MPU 231 in a short time. Therefore, even if the control program is stored in the character ROM 234 composed of the NAND flash memory 234a having a low reading speed, the control of the third symbol display device 81 in the display control device 114 can be started immediately.

  The boot program is a control program stored in the second program storage area 234a1 of the NAND flash memory 234a, that is, a control program excluding the boot program stored in the first program storage area 234d1 of the NOR ROM 234d, The fixed value data (for example, a display data table, a transfer data table, and the like, which will be described later) used in the control program is stored in a predetermined amount (for example, the capacity of one page of the NAND flash memory 234a) in the program storage area 233a or It is programmed to transfer to the data table storage area 233b. Then, the MPU 231 sets the control program stored in the second program storage area 234a1 according to the boot program read from the first program storage area 234d1 after the system reset is released, and sets the boot program in the first program storage area 234d1. A predetermined amount is transferred to and stored in the program storage area 233a while using a bank different from the bank of the buffer RAM 234c.

  Here, since the boot program stored in the first program storage area 234d1 has a capacity corresponding to one bank of the buffer RAM 234c as described above, the address of the internal bus is designated as "0000H". When the boot program in the first program storage area 234d1 is set in the buffer RAM 234c in response to the setting, the boot program is set in only one bank of the buffer RAM 234c. Therefore, when transferring the control program stored in the second program storage area 234a1 to the program storage area 233a in accordance with the boot program in the first program storage area 234d1, the first program set in one bank of the buffer RAM 234c is used. The transfer process can be executed using the other bank while leaving the boot program in the storage area 234d1. Therefore, it is not necessary to reset the boot program in the first program storage area 234d1 in the buffer RAM 234c after the transfer process, so that the time required for the boot process can be shortened.

  When the control program stored in the second program storage area 234a1 is transferred to the program storage area 233a by a predetermined amount, the boot program stored in the first program storage area 234d1 moves the instruction pointer 231a into the program storage area 233a. It is programmed to set to the first predetermined address. Thus, after the system reset is released, when the control program stored in the second program storage area 234a1 by the MPU 231 is transferred to the program storage area 233a by a predetermined amount, the instruction pointer 231a moves to the first predetermined area of the program storage area 233a. The address is set.

  Therefore, when a predetermined amount of programs among the control programs stored in the second program storage area 234a1 is stored in the program storage area 233a, the MPU 231 reads out the control program stored in the program storage area 233a, Various processes can be executed. That is, the MPU 231 does not read out the control program from the NAND flash memory 234a having the second program storage area 234a1 and fetches the instruction, but reads out the control program transferred to the work RAM 233 having the program storage area 233a and fetches the instruction. Then, various processes are executed. As will be described later, the work RAM 233 is constituted by a DRAM, so that a high-speed read operation is performed. Therefore, even when most of the control program is stored in the NAND flash memory 234a having a low reading speed, the MPU 231 can fetch an instruction at high speed and execute processing for the instruction.

  Here, the control programs stored in the second program storage area 234a1 include the remaining boot programs not stored in the first program storage area 234d1. On the other hand, the boot programs stored in the first program storage area 234d1 include the remaining boot programs in the control programs transferred from the second program storage area 234a1 by a predetermined amount to the program storage area 233a of the work RAM 233. The program is programmed so as to be included, and the instruction pointer 231a is set such that the start address of the remaining boot program stored in the program storage area 233a is the first predetermined address.

  Accordingly, the MPU 231 transfers the control program stored in the second program storage area 234a1 by a predetermined amount to the program storage area 233a by the boot program stored in the first program storage area 234d1, and then transfers the control program. Execute the remaining boot program included in the control program.

  In the remaining boot programs, all of the remaining control programs not transferred to the program storage area 233a and fixed value data (for example, a display data table and a transfer data table described later) used in the control programs are stored in the second program storage. A process of transferring a predetermined amount from the area 234a1 to the program storage area 233a or the data table storage area 233b is executed. At the end of the boot program, the instruction pointer 231a is set to a second predetermined address in the program storage area 233a. Specifically, the start address of the program corresponding to the boot processing by the boot program (see S1901 in FIG. 111) stored in the program storage area 233a is set as the second predetermined address.

  By executing the remaining boot program, the MPU 231 transfers all control programs and fixed value data stored in the second program storage area 234a1 to the program storage area 233a or the data table storage area 233b. When the boot program is executed to the end by the MPU 231, the instruction pointer 231a is set to the second predetermined address. Thereafter, the MPU 231 is transferred to the program storage area 233a without referring to the NAND flash memory 234a. Various processes are executed using the control program.

  Therefore, even when most of the control programs are stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, the control programs are transferred to the program storage area 233a of the work RAM 233 after the system reset is released. Thus, the MPU 231 can perform various controls by reading the control program from the work RAM constituted by a DRAM having a high read speed. Therefore, high processing performance can be maintained in the display control device 114, and diversified and complicated effects can be easily executed using the third symbol display device 81.

  Further, as described above, without storing all the boot programs in the NOR ROM 234d, a predetermined number of instructions to be processed first by the MPU 231 after the system reset is released are stored, and for the remaining boot programs, Even when the control program is stored in the second program storage area 234a1 of the NAND flash memory 234a, the control program stored in the second program storage area 234a1 can be reliably transferred to the program storage area 233a. Therefore, the character ROM 234 can start the MPU 231 in a short time only by adding the NOR-type ROM 234d having a very small capacity. Can be.

  The image controller 237 is a digital signal processor (DSP) that draws an image and displays the drawn image on the third symbol display device 81 at a predetermined timing. The image controller 237 draws an image for one frame based on a drawing list (see FIG. 91) described later transmitted from the MPU 231 and outputs one of the frames of a first frame buffer 236b and a second frame buffer 236c described later. The image drawn in the buffer is expanded, and the image information of one frame previously expanded in the other frame buffer is output to the third symbol display device 81, thereby displaying the image on the third symbol display device 81. . The image controller 237 performs this one-frame image drawing process and one-frame image display process for one frame of image display time on the third symbol display device 81 (20 milliseconds in this control example). In parallel.

  The image controller 237 transmits a vertical synchronization interrupt signal (hereinafter, referred to as a “V interrupt signal”) to the MPU 231 every 20 milliseconds when the rendering processing of the image for one frame is completed. Each time the MPU 231 detects the V interrupt signal, it executes a V interrupt process (see FIG. 112B) and instructs the image controller 237 to draw an image for the next one frame. In response to this instruction, the image controller 237 executes a process of drawing the next one frame of image and a process of displaying the image developed by the drawing on the third symbol display device 81.

  As described above, the MPU 231 executes the V interrupt processing in accordance with the V interrupt signal from the image controller 237 and issues a drawing instruction to the image controller 237. Therefore, the image controller 237 performs the image drawing processing and display. An image drawing instruction can be received from the MPU 231 at each processing interval (20 milliseconds). Therefore, the image controller 237 does not receive a drawing instruction of the next image at a stage where the image drawing processing or the display processing is not completed, so that the image controller 237 starts drawing a new image during drawing of the image, It is possible to prevent an image from being developed in a frame buffer in which image information being displayed is stored in accordance with a new drawing instruction.

  The image controller 237 also executes processing for transferring image data from the character ROM 234 to the resident video RAM 235 or the normal video RAM 236 based on a transfer instruction from the MPU 231 and transfer data information included in the drawing list.

  The image is drawn using the image data stored in the resident video RAM 235 and the normal video RAM 236. That is, the image data necessary for drawing is transferred from the character ROM 234 to the resident video RAM 235 or the normal video RAM 236 based on an instruction from the MPU 231 before the drawing is performed.

  Here, the NAND flash memory facilitates increasing the capacity of the ROM, but has a lower read speed than other ROMs (such as a mask ROM and an EEPROM). On the other hand, in the display control device 114, the MPU 231 instructs the image controller 237 to transfer a part of the image data stored in the character ROM 234 to the resident video RAM 235 after turning on the power. It is configured to be. Then, as described later, the image data stored in the resident video RAM 235 is controlled to be resident without being overwritten.

  Thereby, after the transfer of the image data to be resident in the resident video RAM 235 after the power is turned on, the image controller 237 draws the image while using the image data resident in the resident video RAM 235. Processing can be performed. Therefore, if the image data used for the drawing process is resident in the resident video RAM 235, it is not necessary to read the corresponding image data from the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed when drawing an image. The time required for the reading can be omitted, and the image can be drawn immediately and the drawn image can be displayed on the third symbol display device 81.

  In particular, in the resident video RAM 235, image data of frequently displayed images and image data of images to be displayed immediately after the display is determined by the main control device 110 or the display control device 114 are resident. Even if the character ROM 234 is configured by the NAND flash memory 234a, the responsiveness until a certain image is displayed on the third symbol display device 81 can be kept high.

  Further, when drawing an image using non-resident image data in the resident video RAM 235, the display control device 114 needs to perform drawing from the character ROM 234 to the normal video RAM 236 before the drawing is performed. The MPU 231 is configured to instruct the image controller 237 to transfer image data. As will be described later, the image data transferred to the normal video RAM 236 may be deleted by overwriting after being used for drawing an image. It is not necessary to read out the corresponding image data from the character ROM 234 composed of, and the time required for reading out the image data can be omitted. Therefore, it is possible to immediately draw the image and display the drawn image on the third symbol display device 81. it can.

  Further, since the image data is also stored in the normal video RAM 236, it is not necessary to keep all the image data resident in the resident video RAM 235. Therefore, it is not necessary to prepare a large-capacity resident video RAM 235. Therefore, an increase in cost due to the provision of the resident video RAM 235 can be suppressed.

  The image controller 237 has a buffer RAM 237a composed of a 132 kilobyte SRAM which is the capacity of one block of the NAND flash memory 234a.

  The transfer instruction of the image data performed by the MPU 231 to the image controller 237 based on the transfer instruction or the transfer data information of the drawing list includes the start address (storage source start address) of the character ROM 234 in which the image data to be transferred is stored. Last address (storage source final address), transfer destination information (information indicating to which of the resident video RAM 235 and the normal video RAM 236 to transfer), and the beginning of the transfer destination (the resident video RAM 235 or the normal video RAM 236) Contains the address. The data size of the image data to be transferred may be included in place of the storage source final address.

  The image controller 237 reads one block of data from a predetermined address of the character ROM 234 and temporarily stores the data in the buffer RAM 237a in accordance with the various information of the transfer instruction. When the resident video RAM 235 or the normal video RAM 236 is not used, the buffer RAM 237a Is transferred to the resident RAM 235 or the normal video RAM 236. Then, the processing is repeatedly executed until all the image data stored from the storage source start address indicated by the transfer instruction to the storage source end address is transferred.

  As a result, the image data read from the character ROM 234 over time is temporarily stored in the buffer RAM 237a, and then the image data is transferred from the buffer RAM 237a to the resident video RAM 235 or the normal video RAM 236 in a short time. Can be. Therefore, while the image data is transferred from the character ROM 234 to the resident video RAM 235 or the normal video RAM 236, the resident video RAM 235 or the normal video RAM 236 is prevented from being occupied for a long time by the transfer of the image data. be able to. Therefore, since the resident video RAM 235 and the normal video RAM 236 are occupied by the transfer of the image data, the video RAMs 235 and 236 cannot be used for the image drawing processing. In addition, it is possible to prevent the display on the third symbol display device 81 from being missed.

  Further, the transfer of the image data from the buffer RAM 234c to the resident video RAM 235 or the normal video RAM 236 is performed by the image controller 237. It is possible to easily determine a period that is not used for display processing on the device 81, and to simplify the processing.

  The resident video RAM 235 is used so that the image data transferred from the character ROM 234 is maintained without being overwritten while the power is turned on. The power-on main image area 235a, the rear image area 235c, and the character design area are used. 235e, an error message image area 235f, and at least a power-on fluctuation image area 235b and a third symbol area 235d.

  The power-on main image area 235a stores a power-on main image displayed on the third symbol display device 81 from when the power is turned on to when all image data to be resident in the resident video RAM 235 is stored. An area for storing corresponding data. Further, in the power-on fluctuation image area 235b, the game is started by the player while the power-on main image is displayed on the third symbol display device 81, and the entrance to the first winning port 64 is detected. This is an area for storing image data corresponding to a power-on fluctuation image in which the result of the lottery performed in the main control device 110 is displayed in a fluctuation effect when the power control is performed.

  The MPU 231 transfers the image data corresponding to the power-on main image and the power-on fluctuation image from the character ROM 234 to the power-on main image area 235a when the power supply from the power supply unit 251 is started. A transfer instruction is transmitted to the controller 237 (see S1803 and S1804 in FIG. 40). The power-on main image is an image displayed on the third symbol display device 81 immediately after power-on, while image data to be stored in the resident video RAM 235 is being transferred from the character ROM 234, This is a simple image with a smaller amount of data than an image displayed during a normal game. Therefore, the image data can be transferred quickly after the power is turned on, and the image can be displayed.

  During display of the main image at power-on, when a display variation pattern command transmitted from the sound lamp control device 113 is received based on a variation pattern command from the main control device 110 which is a variation start instruction command, the display control device 114 On the power-on main image display screen, the power-on fluctuation image of the “○” symbol in the lower right position toward the screen and the “×” symbol in the same position as the “○” symbol when the power is turned on The change image is alternately and repeatedly displayed during the change period. Then, based on the fluctuation pattern command and the stop type command from the main controller 110, the display fluctuation pattern command and the display stop type command transmitted from the sound lamp controller 113 are used to determine the lottery performed by the main controller 110. Judging the result, if it is a "special symbol jackpot", display the "○" symbol for a fixed period after stopping the variable effect, and if it is "special symbol loss", display the "x" symbol after the variable effect stops Display for a certain period.

  The MPU 231 uses the image data stored in the power-on main image area 235a to the image controller 237 until all image data to be resident in the resident video RAM 235 is transferred to the resident video RAM 235. Instructs the main image to be drawn at power-on. Thereby, while the remaining image data to be resident is transferred to the resident video RAM 235, the player or the person in charge of the hall can check the power-on main image displayed on the third symbol display device 81. it can. Accordingly, the display control device 114 transfers the remaining image data to be resident from the character ROM 234 to the resident video RAM 235 over time while displaying the main image at power-on on the third symbol display device 81. be able to. Further, the player or the like can recognize that some processing is being performed while the power-on main image is displayed on the third symbol display device 81, so that the remaining images to be resident in the resident video RAM 235 are displayed. Until the data is transferred from the character ROM 234 to the resident video RAM 235, it is necessary to wait until the transfer of the image data to the resident video RAM 235 is completed without worrying that the operation has not stopped. Can be.

  Also, in an operation check at a factory or the like at the time of manufacturing, the main image at the time of turning on the power is immediately displayed on the third symbol display device 81, so that the operation of the third symbol display device 81 is started without any problem by turning on the power. Can be immediately confirmed, and the use of the NAND flash memory 234a having a low reading speed as the character ROM 234 can prevent the efficiency of the operation check from deteriorating.

  Further, when the player starts the game while the main image at power-on is displayed on the third symbol display device 81 and a ball is detected at the first entrance ball 64, the power-on fluctuation image area The power-on fluctuation image is drawn using the image data corresponding to the power-on fluctuation image resident at 235b, and the "O" symbol and the "X" symbol are alternately displayed on the third symbol display device 81. Thus, the MPU 231 instructs the image controller 237. Thus, a simple fluctuation effect can be performed using the power-on fluctuation image. Therefore, even when the main image is displayed on the third symbol display device 81 when the power is turned on, the player can surely confirm that the lottery has been performed by the simple variable effect.

  When the main image at the time of power-on is displayed on the third symbol display device 81, the image data corresponding to the power-on fluctuation image is already resident in the power-on fluctuation image area 235b. If a ball is detected in the first entrance ball 64 while the time main image is displayed on the third symbol display device 81, the corresponding variable effect can be immediately displayed on the third symbol display device 81. it can.

  Returning to FIG. 16, the description will be continued. The back image area 235c is an area for storing image data corresponding to the back image displayed on the third symbol display device 81. Here, with reference to FIG. 88, the back image and the range of the back image stored in the back image area 235c among the back images will be described. FIG. 88 is an explanatory diagram for explaining two types of back images and the range of the back images stored in the back image area 235c of the resident video RAM 235 for each back image. FIG. FIG. 88 (b) shows the back surface A corresponding to the "sky stage" and the back surface A corresponding to the "sky stage".

  As shown in FIG. 88, as the back images corresponding to the back surfaces A and B, images that are longer in the horizontal direction than the display area displayed on the third symbol display device 81 are prepared in the character ROM 234. The image controller 237 draws the image such that the rear image is displayed on the third symbol display device 81 while scrolling the image horizontally from left to right.

  The images prepared on each of the back surfaces A and B (hereinafter, referred to as “scroll images”) are configured such that the back images are continuous at the positions a and c. The image between the position c and the position d and the image between the position a and the position a ′ are composed of images corresponding to the horizontal width of the display area, and are images between the position c and the position d. Is displayed on the third symbol display device 81 as a display area, and then the image between the position a and the position a ′ is displayed on the third symbol display device 81 as a display area. The back image is scroll-displayed with a proper connection.

  When the player operates the frame button 22 to change the stage to the “city stage” or the “empty stage”, the MPU 231 changes the initial position of the display area from the first position a to the position a ′ of the corresponding rear image. The image controller 237 is controlled so that the image at the initial position is displayed on the third symbol display device 81. Then, as time passes, the display area is moved from left to right with respect to the scroll image, and the image controller 237 is controlled so that the display area is sequentially displayed on the third symbol display device 81. When the area reaches the image between the position c and the position d, the image controller 237 is controlled so that the display area is displayed again on the third symbol display device 81 as the image from the position a to the position a ′. Therefore, on the third symbol display device 81, the image between the positions a to c can be repeatedly scrolled and displayed with a smooth connection so as to flow toward the left.

  On the other hand, unlike the above-described back surface A and back surface B, the back image (not shown) used for the super background notice is an image that can be scroll-displayed not only in the horizontal direction but also in the vertical direction. Thereby, scroll display in the horizontal direction or the vertical direction is possible. Further, the image used for the super background notice can be scroll-displayed and includes an image that changes with the passage of time. Thus, a display in which the specific image (image of the door) blinks for a predetermined time can be executed.

  Next, in each back image, the range of the back image stored in the back image area 235c will be described. As shown in FIG. 88 (a), the back surface A corresponding to the street stage which is the initial stage has the entire range of the back surface A, that is, all the image data corresponding to the positions a to d are the back surface of the resident video RAM 235. It is stored in the image area 235c. Normally, a game is often performed without changing the stage while the city stage, which is the initial stage, is displayed. Therefore, all the image data of the back A corresponding to the city stage, which is frequently displayed, is displayed in the rear image area. By making the character ROM 234 resident, the number of data accesses to the character ROM 234 can be reduced, and the load on the display control device 114 can be reduced.

  On the other hand, as shown in FIG. 88 (b), the back surface B corresponding to the empty stage stores only a part of the back surface, that is, only the image data corresponding to the image between the position a and the position b in the resident video RAM 235. Is stored in the back image area 235c.

  Here, since the operation of the frame button 22 performed by the player to change the stage is performed at an arbitrary timing based on the intention of the player, even if the frame button 22 is operated at an arbitrary timing. In order to immediately change the rear image, it is ideal that the entire range of image data for all the rear images is resident in the resident video RAM 235. A large capacity RAM must be used, which may lead to an increase in cost.

  On the other hand, in the present pachinko machine 10, the initial position of the rear image displayed first when the stage is changed is fixed in a range from the position a to the position a ', and the position is shifted from the position a including the initial position to the position a'. Since the image during b is stored in the rear image area 235c of the resident video RAM 235, even if the character ROM 234 is configured by the NAND flash memory 234a having a low reading speed, the character ROM 234 can be arbitrarily operated by the player operating the frame button 22. When the stage is changed at the timing of (3), the image data resident in the back image area 235c of the resident video RAM 235 is used to immediately set the initial position of the back B or back C to the third symbol display device 81. Can be displayed on a scrolling display or changing the color tone over time. It is possible. In addition, since only the image data corresponding to the image in the partial range is stored for the rear surface B and the rear surface C, an increase in the storage capacity of the resident video RAM 235 can be suppressed, and an increase in cost can be suppressed.

  After the image at the initial position is displayed, the rear surface B scrolls the range from position a to position b from left to right using the image data resident in the rear image area 235c of the resident video RAM 235. The range from the position a to the position b is set so that the image data corresponding to the images from the position b ′ to the position d can be transferred from the character ROM 234 to the normal RAM 236 during the operation. As a result, the image data from the position b ′ to the position d can be transferred to the normal video RAM 236 while scrolling the range from the position a to the position b, so that the image data stored in the rear image area 235c of the resident video RAM 235 can be After scrolling the range from position a to position b using the image data corresponding to the back image stored in the normal video RAM 236 without delay, the range from position b ′ to position d is scrolled. It can be displayed on the symbol display device 81.

  On the rear surface B, the image data stored in the normal video RAM 236 is stored in a sub-area dedicated to the rear image provided in the image storage area 236a (see FIG. 84) of the normal video RAM 236. Thus, the rear image data stored in the sub-area dedicated to the rear image is not overwritten by other image data, so that the rear image can be reliably displayed.

  On the back surface B, the image data stored in the back image area 235c of the resident video RAM 235 and the image data stored in the normal video RAM 236 correspond to the image corresponding to the image between the position b ′ and the position b. Data is stored redundantly. Then, under the control of the image controller 237 by the MPU 231, the image up to the position “b” is displayed on the third symbol display device 81 using the image data stored in the rear image area 235 c of the resident video RAM 235, and then the normal video By displaying the image from the position b 'on the third symbol display device 81 using the image data stored in the RAM 236, the rear image is scroll-displayed with a smooth connection to the third symbol display device 81. ing.

  Further, when the MPU 231 controls the image controller 237 so that the image between the position c and the position d is displayed as a display area on the third symbol display device 81 using the image data of the normal video RAM 236, The MPU 231 controls the image controller 237 so that the image between the position a and the position a 'is displayed as a display area on the third symbol display device 81 using the image data of the rear image area 235c of the resident video RAM 235. I do. This allows the third symbol display device 81 to repeatedly scroll and display the images between the positions a to c so as to flow leftward.

  Returning to FIG. 84, the description will be continued. The third symbol area 235d is an area where the third symbol used in the variable effect displayed on the third symbol display device 81 is resident. That is, in the third symbol area 235d, the image data corresponding to the above-mentioned main symbol, which is the number of the third symbol “0” to “9”, is resident. Thus, when performing a fluctuation effect on the third symbol display device 81, it is not necessary to read out the image data from the character ROM 234 every time. Therefore, even if the NAND flash memory 234a is used for the character ROM 234, A fluctuating effect can be started quickly. Therefore, after the ball enters the first winning opening 64, the variable effect is not immediately started on the third symbol display device 81 even though the variable effect is started on the first symbol display device 37. The occurrence of such a state can be suppressed.

  Further, in the third symbol area 235d, image data corresponding to the main symbol without numbers “0” to “9” is also resident. These image data are used for a demonstration effect displayed on the third symbol display device 81 when the next variable effect associated with the start winning is not started even if a predetermined time has elapsed after one variable effect has stopped. Can be Thus, when the demonstration effect is displayed on the third symbol display device 81, a main symbol without a number is displayed as the third symbol in the demonstration effect. Therefore, the player can easily recognize that the pachinko machine 10 is in the demonstration state by visually recognizing the main symbol without a number from the display image of the third symbol display device 81.

  The character symbol area 235e is an area for storing image data corresponding to character symbols used in various effects displayed on the third symbol display device 81. In this pachinko machine 10, various characters including "girl" are displayed in accordance with various effects, and data corresponding to these characters is resident in the character design area 235e, thereby controlling display. When changing the character design based on the content of the command received from the audio lamp control device 113, the device 114 does not newly read out the corresponding image data from the character ROM 234, but instead stores the corresponding image data in the character design area 235e of the resident video RAM 235. By reading out the resident image data, the image controller 237 can draw a predetermined image. As a result, it is not necessary to read the corresponding image data from the character ROM 234. Therefore, even if the NAND flash memory 234a having a low reading speed is used as the character ROM 234, the character pattern can be changed immediately.

  The error message image area 235f is an area for storing image data corresponding to an error message displayed when an error occurs in the pachinko machine 10. In the present pachinko machine 10, for example, when the sound lamp control device 113 detects vibration from the output of a vibration sensor (not shown) attached to the back of the game board 13, the sound lamp control device 113 detects the occurrence of the vibration error. The display control device 114 is notified by an error command. Also, when the occurrence of another error is detected by the sound lamp control device 113, the sound lamp control device 113 notifies the display control device 114 of the occurrence of the error together with the error type by an error command. Upon receiving the error command, the display control device 114 is configured to display an error message corresponding to the received error on the third symbol display device 81.

  Here, the error message is required to be displayed almost simultaneously with the occurrence of the error, from the viewpoint of preventing the player from cheating and protecting the player against the error. In the present pachinko machine 10, since image data corresponding to various error messages is resident in the error message image area 235f in advance, the display control device 114 determines the error message in the resident video RAM 235 based on the received error command. By reading out the image data previously resident in the image area 235f, the image controller 237 can immediately draw each error message image. As a result, it is not necessary to sequentially read out the image data corresponding to the error message from the character ROM 234. Therefore, even if the NAND flash memory 234a having a low reading speed is used as the character ROM 234, the error message corresponding to the error message is received. It can be displayed immediately.

  The normal video RAM 236 is used so that data is overwritten and updated at any time, and is provided with at least an image storage area 236a, a first frame buffer 236b, and a second frame buffer 236c.

  The image storage area 236a is an area for storing image data that is not resident in the resident video RAM 235 among image data necessary for drawing an image to be displayed on the third symbol display device 81. The image storage area 236a is divided into a plurality of sub-areas, and the type of image data stored in the sub-area is predetermined for each sub-area.

  The MPU 231 transfers, from the image data that is not resident in the resident video RAM 235, image data necessary for drawing an image thereafter, from the character ROM 234 to the sub area provided in the image storage area 236 a of the normal video RAM 236. , And instructs the image controller 237 to transfer the type of the image data to a predetermined sub-area to be stored. Accordingly, the image controller 237 reads the image data specified by the MPU 231 from the character ROM 234, and transfers the read image data to a specified sub-area of the image storage area 236a via the buffer RAM 237a.

  The transfer instruction of the image data is performed by including the transfer data information in a later-described drawing list in which the MPU 231 instructs the image controller 237 to draw the image. Thus, the MPU 231 can issue an image drawing instruction and an image data transfer instruction only by transmitting the drawing list to the image controller 237, so that the processing load can be reduced.

  The first frame buffer 236b and the second frame buffer 236c are buffers for developing an image to be displayed on the third symbol display device 81. The image controller 237 writes an image for one frame drawn in accordance with an instruction from the MPU 231 into one of the first frame buffer 236b and the second frame buffer 236c, thereby writing the image for one frame into the frame buffer. While the image is being developed, while the image is being developed in one of the frame buffers, the image information for one frame that has been previously developed is read out from the other frame buffer, and the readout signal is sent to the third symbol display device 81 together with the drive signal. By transmitting the image information, the third symbol display device 81 executes a process of displaying the image for one frame.

  As described above, by providing the first frame buffer 236b and the second frame buffer 236c as the frame buffers, the image controller 237 simultaneously develops the image for one frame drawn in one frame buffer while developing the image. The image of one frame that has been developed first is read from the other frame buffer, and the read image of one frame can be displayed on the third symbol display device 81.

  The frame buffer for expanding the image for one frame and the frame buffer for reading the image information for one frame to display the image on the third symbol display device 81 are different from each other. Every 20 milliseconds to be completed, the MPU 231 alternately specifies one of the first frame buffer 236b and the second frame buffer 236c.

  That is, at a certain timing, the first frame buffer 236b is specified as a frame buffer for developing an image of one frame, and the second frame buffer 236c is specified as a frame buffer from which image information of one frame is read. When the drawing process and the display process are executed, the second frame buffer 236c is designated as a frame buffer for developing the image of one frame 20 ms after the completion of the drawing process of the image of one frame, The first frame buffer 236b is designated as the frame buffer from which the image information is read. Thereby, the image information of the image previously developed in the first frame buffer 236b can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the second frame buffer 236c. You.

  Then, after the next 20 milliseconds, the first frame buffer 236b is designated as a frame buffer for developing an image of one frame, and the second frame buffer 236c is designated as a frame buffer from which image information of one frame is read. Is done. As a result, the image information of the image previously developed in the second frame buffer 236c can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the first frame buffer 236b. You. Thereafter, the frame buffer for expanding the image for one frame and the frame buffer from which the image information for one frame is read out are changed to one of the first frame buffer 236b and the second frame buffer 236c every 20 milliseconds. By alternately specifying the images, it is possible to continuously perform the display processing of the image of one frame in units of 20 milliseconds while performing the drawing processing of the image of one frame.

  The work RAM 233 is a memory for storing control programs and fixed value data stored in the character ROM 234, and for temporarily storing work data and flags used when the MPU 231 executes various control programs. It is composed of a DRAM. The work RAM 233 includes a program storage area 233a, a data table storage area 233b, a simple image display flag 233c, a display data table buffer 233d, a transfer data table buffer 233e, a pointer 233f, a drawing list area 233g, a clock counter 233h, and stored image data determination. Flag 233i, drawing buffer flag 233j, winning information storage area 233k, game state storage area 233m, fluctuation history storage area 233n, display effect counter 233o, continuation counter 233p, back image change flag 233q, super background flag 233r, map storage area 233s, a mass setting table storage area 233t, a mass event storage area 233u, a route history storage area 233w, a background addition flag 233x, and the number of times of change in the door At least it has a counter 233y.

  The program storage area 233a is an area for storing a control program executed by the MPU 231. When the system reset is released, the MPU 231 reads out the control program from the character ROM 234, transfers it to the work RAM 233, and stores it in the program storage area 233a. When all the control programs are stored in the program storage area 233a, the MPU 231 thereafter executes various controls using the control programs stored in the program storage area 233a. As described above, since the work RAM 233 is configured by a DRAM, a high-speed read operation is performed. Therefore, even when the control program is stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, high processing performance can be maintained in the display control device 114, and the third symbol display device 81 , It is possible to easily execute diversified and complicated effects.

  The data table storage area 233b includes a display data table that describes display contents to be displayed on the third symbol display device 81 with the passage of time for one effect to be displayed based on a command from the main control device 110, and a display data table. This area stores transfer data information of image data that is not resident in the resident video RAM 235 among image data used in one effect displayed by the table and a transfer data table defining transfer timing.

  These data tables are usually stored as a type of fixed value data in a second program storage area 234a1 provided in the NAND flash memory 234a of the character ROM 234, and according to a boot program executed by the MPU 231 after the system reset is released. These data tables are transferred from character ROM 234 to work RAM 233 and stored in data table storage area 233b. Then, when all the data tables are stored in the data table storage area 233b, the MPU 231 thereafter controls the display of the third symbol display device 81 using the data tables stored in the data table storage area 233b. As described above, since the work RAM 233 is configured by a DRAM, a high-speed read operation is performed. Therefore, even when various data tables are stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, high processing performance can be maintained in the display control device 114. By using 81, diversified and complicated effects can be easily executed.

  Here, details of various data tables will be described. First, one display data table is prepared for each effect mode of each effect displayed on the third symbol display device 81 based on a command from the main control device 110. For example, a variable effect, an opening effect A display data table corresponding to a round effect, an ending effect, and a demonstration effect is prepared.

  The fluctuation effect is an effect started on the third symbol display device 81 when a display fluctuation pattern command is received from the audio lamp control device 113. When the display variation pattern command is received, the display stop type command indicating the variation effect stop type is also received. For example, when the fluctuation effect is started, if the stop type of the fluctuation effect is out, the stop symbol indicating the deviation is finally stopped and displayed, while the stop type of the fluctuation effect is the jackpot A to D. In any case, the stop symbols indicating the respective jackpots are finally stopped and displayed. The player can recognize the jackpot type by visually recognizing the stop symbols in the variable effect, and can easily determine the game value given according to the jackpot type.

  The opening effect is an effect for notifying the player that the pachinko machine 10 will be shifted to the special game state and the specific winning port 65a which is normally closed will be repeatedly opened, and the round effect will be performed in the future. This is an effect for notifying the player of the number of rounds to be started. The ending effect is an effect for notifying the player of the end of the special game state. As described above, the demonstration effect is an effect displayed on the third symbol display device 81 when the next variable effect associated with the start winning is not started even after a predetermined time has elapsed after one variable effect has stopped. In this case, the third symbol is not displayed, and the rear image changes. If the demonstration effect is displayed on the third symbol display device 81, the player or the person related to the hall can recognize that the game is not performed in the pachinko machine 10.

  The data table storage area 233b stores a variable effect, an opening effect, a round effect, an ending effect, a confirmed display effect, and a demonstration effect. Here, the details of the data table storage area 233b will be described with reference to FIG. FIG. 86 is a schematic diagram schematically showing the contents of the data table storage area 233b.

  First, in the data table storage area 233b, a variable effect table storage area corresponding to the variable effect, an opening effect table storage area corresponding to the opening effect, a round effect table storage area corresponding to the round effect, and an ending effect are provided. An ending effect table storage area corresponding to the final display effect, a final display effect table storage area corresponding to the final display effect, and a demonstration effect table storage area corresponding to the demonstration effect are provided.

  Here, in the fluctuating effect table storage area, various fluctuating effect display data tables for executing a normal fluctuating effect, and various stop display data data tables for executing a stop display are provided. Various display data tables for Super Reach A for executing Super Reach A described above are provided. Further, there are provided various display data tables for super reach B for executing the above-described super reach B, and various display data tables for throw display for executing effective effects used in the effect of super reach B. And various display data tables for displaying false throws for performing a false effect, and various display data tables for displaying replacement for performing a replacement effect are provided.

  Further, in other opening effect table storage areas and the like, a plurality of types of display data tables corresponding to the respective effects are provided.

  Next, details of the display data table will be described with reference to FIG. FIG. 89 is a schematic diagram schematically showing an example of the variable display data table among the display data tables. The display data table should be displayed at the time corresponding to an address in which the time (20 milliseconds in the present control example) in which the image of one frame is displayed on the third symbol display device 81 is defined as one unit. The content (drawing content) of an image for one frame is defined in detail.

  In the drawing content, the type of the sprite is defined for each sprite that is a display object constituting an image for one frame, and the display position coordinates, the enlargement ratio, the rotation angle, the translucency, and the like are determined according to the type of the sprite. Drawing information, such as a value, α blending information, color information, and filter designation information, for drawing a sprite on the third symbol display device 81 is defined.

  The sprite type is information for specifying a sprite to be displayed. The display position coordinates are information for specifying the coordinates on the third symbol display device 81 at which the sprite is to be displayed. The enlargement ratio is information for specifying an enlargement ratio for a standard display size preset for the sprite, and the size of the sprite to be displayed is specified according to the enlargement ratio. If the enlargement ratio is larger than 100%, the sprite is displayed in an enlarged scale than the standard size. If the enlargement ratio is smaller than 100%, the sprite is reduced in size from the standard size. Is displayed.

  The rotation angle is information for specifying the rotation angle when the sprite is rotated and displayed. The translucent value is for specifying the transparency of the entire sprite, and the higher the translucent value, the more the image displayed on the back side of the sprite is displayed. The α blending information is information for specifying a known α blending coefficient used when performing a superimposition process with another sprite. The color information is information for specifying a color tone of a sprite to be displayed. The filter designation information is information for designating an image filter to be applied to the designated sprite when drawing the designated sprite.

  In the variation display data table, one back image, nine third symbols (symbol 1, symbol 2,...), And one light image For each sprite, drawing information for each sprite such as an effect expressing insertion of characters and characters used for various effects such as boy images and characters is defined for each address. One or more pieces of information on effects and characters are defined in accordance with the content to be displayed in the frame.

  Here, the display position of the rear image is fixed to the entire screen of the third symbol display device 81, and the magnification, the rotation angle, the translucent value, the α blending information, the color information, and the filter designation information are set with respect to the elapse of time. Since it is fixed, only the rear type, which is information for specifying the type of the rear image, is specified in the variable display data table. This back type indicates whether to display any of the back surfaces A to C corresponding to the stage (one of the “city stage”, “empty stage”, and “island stage”) selected by the player, or Information specifying whether to display a back image different from C (for example, an image corresponding to the super background notice effect) is described. In addition, when specifying to display a rear image different from the rear surfaces A to C, the rear type also includes information for specifying which rear image is to be displayed.

  If it is specified by the back type that any of the backs A to C is to be displayed, the MPU 231 specifies the back image corresponding to the stage specified by the player among the backs A to C as a drawing target. Also, the range of the back image to be displayed for the frame is specified as time passes. On the other hand, when it is specified that a back image different from the back surfaces A to C is to be displayed, the back image to be displayed is specified based on the back type.

  In this control example, a case will be described in which only the back type is defined as the drawing content of the back image in the display data table. Instead, the back type and the range of the May be defined as position information indicating whether or not to be displayed. The position information may be, for example, information indicating an elapsed time from when the rear image in the range corresponding to the initial position is displayed. In this case, the MPU 231 specifies the range of the rear image to be displayed for the frame based on the elapsed time from when the rear image in the range corresponding to the initial position indicated by the position information is displayed.

  Further, the position information may be information indicating an elapsed time from the start of drawing of an image based on the display data table (or display of the third symbol display device 81). In this case, the MPU 231 displays the range of the back image to be displayed for the frame at the stage when the drawing of the image (or the display of the third symbol display device 81) is started based on the display database. It is specified based on the position of the back image and the elapsed time from the start of drawing of the image indicated by the position information (or the display of the third symbol display device 81).

  Further, the position information includes information indicating the elapsed time since the rear image in the range corresponding to the initial position is displayed and drawing of an image based on the display data table according to the rear type (or the third symbol display device 81). May indicate any of the information indicating the elapsed time from the start of the display, or the type information of the position information (for example, the range of the range corresponding to the initial position) together with the back type and the position information. This is information indicating the elapsed time since the back image was displayed, or information indicating the elapsed time since the drawing of the image based on the display database (or the display of the third symbol display device 81) was started. May be defined as the drawing content of the back image. In addition, the position information may not be information indicating the elapsed time, but may be information indicating an address at which the range of the rear image to be displayed is stored.

  In the third symbol (symbol 1, symbol 2,...), Symbol type offset information is described as symbol type information for specifying the third symbol to be displayed. This offset information is information representing the difference between the numbers given to the respective third symbols. Rather than directly specifying the type of the third symbol, the offset information is specified because the display of the third symbol in the variable effect is the stop symbol of the variable effect performed immediately before and the variable effect performed this time. This is because it changes according to the stop symbol, and in the symbol offset information from the start of the fluctuation until a predetermined time has elapsed, the offset information from the stop symbol of the fluctuation effect performed immediately before is described. Thereby, the variable effect is started from the stop symbol in the immediately preceding variable effect.

  On the other hand, after a lapse of a predetermined time from the start of the fluctuation, the offset from the stop symbol set in accordance with the stop type command (display stop type command) received from the main control device 110 via the audio lamp control device 113. Provide information. Thus, the variable effect can be stopped at a stop symbol corresponding to the stop type specified by the main control device 110.

  In addition, since each 3rd symbol is given a unique number, a variation symbol in the immediately preceding variation effect and a stop symbol corresponding to the stop type designated by the main control device 110 are displayed in the 3rd symbol. In addition, the third symbol to be displayed can be easily specified from the offset information by managing the offset information by the difference between the numbers assigned to the third symbols.

  In the symbol offset information, the predetermined time in which the offset information of the stop symbol of the variable effect performed immediately before is switched to the offset information of the stop symbol of the variable effect performed this time, the third symbol fluctuates at high speed. It is set to be the time displayed. While the third symbol is being displayed at a high speed, the third symbol is invisible to the player, and during that time, the stop effect of the variable effect performed immediately before the symbol offset information is displayed. By switching from the offset information to the offset information of the stop symbol of the fluctuation effect performed this time, even if the continuity of the number of the third symbol is interrupted, the player is not made aware of the discontinuity of the continuity of the number. be able to.

  “Start” information indicating the start of the data table is described in “0000H”, which is the start address of the display data table. "End" information indicating the end of the process is described. Then, for each address between the address “0000H” in which the “Start” information is described and the address in which the “End” information is described, the drawing content corresponding to the rendering mode to be defined in the display data table Is described.

  The MPU 231 selects a display data table to be used in accordance with a command (for example, a display variation pattern command) transmitted from the audio lamp control device 113 based on a command or the like from the main control device 110, and selects the selected display. The data table is read from the data table storage area 233b, stored in the display data table buffer 233d, and the pointer 233f is initialized. Then, every time the rendering process for one frame is completed, the pointer 233f is incremented by one, and in the display data table stored in the display data table buffer 233d, based on the rendering content specified by the address indicated by the pointer 233f, The image content to be drawn is specified, and a drawing list (see FIG. 22) described later is created. By transmitting the drawing list to the image controller 237, a drawing instruction for the image is issued. As a result, the contents of the drawing are specified in the order specified by the display data table in accordance with the update of the pointer 233f, so that the image specified by the display data table is displayed on the third symbol display device 81.

  As described above, in the pachinko machine 10, the display control device 114 responds to a command (for example, a display variation pattern command) transmitted from the sound lamp control device 113 based on a command or the like from the main control device 110, and the like. Instead of changing the program to be executed by the MPU 231, the effect image to be displayed on the third symbol display device 81 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 233d. .

  Here, when a program executed by the MPU 231 is started every time the effect image displayed on the third symbol display device 81 is changed, as in a conventional pachinko machine, the effect image is diversified. Since a large load is applied to the processing of starting and executing a complicated and enormous program, the processing capability of the display control device 114 is limited, and there is a possibility that diversification of controllable effect images is limited. there were. On the other hand, in the present pachinko machine 10, the effect image to be displayed on the third symbol display device 81 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 233d. Regardless of the processing capability of the control device 114, various effect images can be displayed on the third symbol display 81.

  In addition, a display data table is prepared corresponding to each rendering mode, a display data table is set according to the rendering mode to be displayed, and a drawing list is created for each frame according to the set data table. This is because, in the pachinko machine 10, the effect to be displayed on the third symbol display device 81 is determined in advance based on the result of the lottery performed based on the winning start. On the other hand, in a game machine other than a game machine such as a pachinko machine, the display content changes on the spot based on the user's operation, so that the display content cannot be predicted. It is not possible to have a display data table corresponding to the presentation mode. In this way, a display data table is prepared corresponding to each rendering mode, a display data table is set according to the rendering mode to be displayed, and a drawing list is created frame by frame according to the set data table. The configuration can be realized for the first time based on the configuration in which the pachinko machine 10 determines an effect mode to be displayed on the third symbol display device 81 in advance based on the result of the lottery performed based on the winning start.

  Next, details of the transfer data table will be described with reference to FIG. FIG. 90 is a schematic diagram schematically illustrating an example of the transfer data table. The transfer data table is prepared corresponding to the display data table prepared for each effect, and as described above, among the sprite image data used in the effect specified in the display data table, the resident The transfer data information for transferring the image data not resident in the video RAM 235 from the character ROM 234 to the image storage area 236a of the normal video RAM 236 and the transfer timing are specified.

  If all the image data of the sprites used in the effects specified in the display data table are stored in the resident video RAM 235, no transfer data table corresponding to the display data table is prepared. Thus, an increase in the capacity of the data table storage area 233b can be suppressed.

  The transfer data table corresponds to an address specified in the display data table, and is transfer data information of image data of a sprite to be transferred at a time indicated by the address (hereinafter, referred to as “transfer target image data”). (Addresses “0001H” and “0097H” in FIG. 90 correspond). Here, the transfer start timing of the transfer target image data is set so that the image data corresponding to the predetermined sprite is stored in the image storage area 236a by the time the drawing of the predetermined sprite is started according to the display data table. In the transfer data table, the transfer data information of the transfer target image data is defined in correspondence with the address corresponding to the transfer start timing.

  On the other hand, if there is no transfer target image data to start transfer at the time indicated by the address specified in the display data table, there is no transfer target image data to start transfer corresponding to that address. Null data is defined (address “0002H” in FIG. 90 corresponds).

  The transfer data information includes the start address (storage source start address) and the end address (storage source end address) of the character ROM 234 in which the transfer target image data is stored, and the start address of the transfer destination (normal video RAM 236). Is included.

  As in the display data table, “Start” information indicating the start of the data table is described in the start address “0000H” of the transfer data table, and the final address of the transfer data table (in the example of FIG. 21, “02F0H”) describes “End” information indicating the end of the data table. Then, for each address between the address “0000H” in which the “Start” information is described and the address in which the “End” information is described, the transfer data information of the transfer target image data to be defined in the transfer data table. Is described.

  When the MPU 231 selects a display data table to be used in accordance with a command (for example, a display variation pattern command) transmitted from the audio ramp control device 113 based on a command or the like from the main control device 110, the display data table If there is a transfer data table corresponding to, the transfer data table is read from the data table storage area 233b and stored in a transfer data table buffer 233e of the work RAM 233 described later. Each time the pointer 233f is updated, the display data table stored in the display data table buffer 233d specifies the drawing content specified by the address indicated by the pointer 233f, and creates a drawing list (see FIG. 91) described later. At the same time, from the transfer data table stored in the transfer data table buffer 233e, the transfer data information of the image data of the predetermined sprite at which the transfer is to be started at that time is acquired, and the transfer data information is added to the created drawing list. to add.

  For example, in the example of FIG. 91, when the pointer 233f becomes “0001H” or “0097H”, the MPU 231 creates the transfer data information specified at the address of the transfer data table based on the display data table. The drawing list is added to the drawing list, and the added drawing list is transmitted to the image controller 237. On the other hand, when the pointer 233f is “0002H”, since null data is defined in the address “0002H” of the transfer data table, it is determined that there is no transfer target image data to start the transfer, and the transfer data table is generated. The drawing list is transmitted to the image controller 237 without adding the transfer data information to the drawing list.

  When the transfer data information is described in the drawing list received from the MPU 231, the image controller 237 transfers the transfer target image data from the character ROM 234 to a predetermined sub-area of the image storage area 236a according to the transfer data information. Execute the processing to be performed.

  Here, as described above, in the transfer data table, the image data corresponding to the predetermined sprite is stored in the image storage area 236a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information of the transfer target image data is specified for a predetermined address, the image data is transferred from the character ROM 234 to the image storage area 236a in accordance with the transfer data information specified in the transfer data table. When a predetermined sprite is drawn in accordance with the display data table, image data that is not resident in the resident video RAM 235 and that is required for drawing the sprite can always be stored in the image storage area 236a. Then, using the image data stored in the image storage area 236a, a predetermined sprite can be drawn based on the display data table.

  Thus, even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, an image necessary for display can be read from the character ROM 234 in advance without delay and transferred to the normal video RAM 236. The corresponding effect can be displayed on the third symbol display device 81 while drawing the image of each sprite specified in the data table. Further, by describing the transfer data table, only the non-resident image data in the resident video RAM 235 can be easily and reliably transferred from the character ROM 234 to the normal video RAM 236.

  In the pachinko machine 10, the display control device 114 displays the display data in response to a command (for example, a display variation pattern command) transmitted from the sound lamp control device 113 based on a command or the like from the main control device 110. When the table is set in the display data table buffer 233d, the transfer data table corresponding to the display data table is set in the transfer data table buffer 233e, so that the image data of the sprite used in the display data table is The data can be reliably transferred from the character ROM 234 to the normal video RAM 236 at a desired timing.

  In the transfer data table, transfer data information is defined so that image data is transferred from the character ROM 234 to the normal video RAM 236 for each image data corresponding to a sprite. Thus, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. By controlling the transfer of image data from the character ROM 234 to the normal video RAM 236 on a sprite basis, the image data transfer can be controlled in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in load on transfer.

  The transfer data table has the same data structure as the display data table, and corresponds to an address specified in the display data table, and transfers transfer target image data to start transfer at the time indicated by the address. Since the data information is defined, before the image data of a predetermined sprite is used based on the display data table set in the display data table buffer 233d, the image data is reliably stored in the normal video RAM 236. Thus, the transfer start timing can be instructed, so that even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, various effect images can be easily displayed on the third symbol display device 81. be able to.

  The simple image display flag 233c is a flag indicating whether or not to display the above-described power-on image (power-on main image and power-on fluctuation image) on the third symbol display device 81. The simple image display flag 233c is set after the image data corresponding to the power-on main image and the power-on fluctuation image is transferred to the power-on main image area 235a or the power-on fluctuation image area 235b of the resident video RAM. Is set to ON in the main processing (see FIG. 110) executed by the MPU 231 (see S1905). Then, at the stage when all the resident target image data is stored in the resident video RAM 235 by the resident image transfer process of the image transfer process, the third symbol display device 81 displays an image other than the power-on image. It is set to off (see S4405 in FIG. 130 (b)).

  This simple image display flag 233c is referred to in the V interrupt processing executed by the MPU 231 each time the V interrupt signal transmitted from the image controller 237 is detected (see S2201 in FIG. 112B), and When the image display flag 233c is on, the simple command determination process (see S2208 in FIG. 112 (b)) and the simple display setting process (see FIG. 112B) so that the power-on image is displayed on the third symbol display device 81. 112 (b) S2209) is executed. On the other hand, when the simple image display flag 233c is off, the command determination is performed so that various images are displayed in accordance with a command transmitted from the audio lamp control device 113 based on a command from the main control device 110 or the like. Processing (see FIGS. 113 to 126) and display setting processing (see FIGS. 127 to 130) are executed.

  The simple image display flag 233c is referred to in the transfer setting process executed by the MPU 231 during the V interrupt process (see S4301 in FIG. 130A), and the simple image display flag 233c is on. Executes the resident image transfer setting process (see FIG. 130 (b)) for transferring the resident target image data from the character ROM 234 to the resident video RAM 235 because there is resident target image data not stored in the resident video RAM 235. If the simple image display flag 233c is off, a normal image transfer setting process (see FIG. 131) for transferring image data necessary for the drawing process from the character ROM 234 to the normal video RAM 236 is executed.

  The display data table buffer 233d stores a display data table corresponding to an effect mode to be displayed on the third symbol display device 81 in accordance with a command or the like transmitted from the sound lamp control device 113 based on a command or the like from the main control device 110. Buffer for The MPU 231 determines an effect mode to be displayed on the third symbol display device 81 based on a command or the like transmitted from the audio lamp control device 113 and stores a display data table corresponding to the effect mode from the data table storage area 233b. Then, the selected display data table is stored in the display data table buffer 233d. Then, the MPU 231 increments the pointer 233f by one, and, based on the drawing content specified by the address indicated by the pointer 233f in the display data table stored in the display data table buffer 233d, increments the image controller 237 for each frame. A drawing list (see FIG. 91) described below, which describes the contents of an image drawing instruction with respect to, is generated. Thereby, the effect corresponding to the display data table stored in the display data table buffer 233d is displayed on the third symbol display device 81.

  The MPU 231 increments the pointer 233f by one and, based on the drawing content specified by the address indicated by the pointer 233f in the display data table stored in the display data table buffer 233d, sends an image to the image controller 237 for each frame. A drawing list described later (see FIG. 91) that describes the contents of the drawing instruction is generated. Thereby, the effect corresponding to the display data table is displayed on the third symbol display device 81.

  The transfer data table buffer 233e stores a transfer data table corresponding to the display data table stored in the display data table buffer 233d in response to a command or the like transmitted from the audio ramp control device 113 based on a command or the like from the main control device 110. Is a buffer for storing. When storing the display data table in the display data table buffer 233d, the MPU 231 selects a transfer data table corresponding to the display data table from the data table storage area 233b, and transfers the selected transfer data table. The data is stored in the data table buffer 233e. When all the image data of the sprite used in the display data table stored in the display data table buffer 233d is stored in the resident video RAM 235, a transfer data table corresponding to the display data table is not prepared. Therefore, the MPU 231 clears the contents by writing Null data indicating that there is no transfer target image data in the transfer data table buffer 233e.

  Then, the MPU 231 adds transfer pointer 233f to the transfer data table stored in the transfer data table buffer 233e, and defines transfer data information of transfer target image data specified by the address indicated by the pointer 233f. If this is the case (that is, if no Null data is described), the transfer data information is stored in a later-described drawing list (see FIG. 91) that describes the contents of an image drawing instruction to the image controller 237 generated for each frame. to add.

  Accordingly, when the transfer data information is described in the drawing list received from the MPU 231, the image controller 237 transfers the transfer target image data from the character ROM 234 to a predetermined sub area of the image storage area 236a according to the transfer data information. Execute the transfer process. Here, as described above, in the transfer data table, the image data corresponding to the predetermined sprite is stored in the image storage area 236a by the time the drawing of the predetermined sprite is started according to the display data table. Transfer data information of transfer target image data is defined for a predetermined address. Therefore, by transferring image data from the character ROM 234 to the image storage area 236a in accordance with the transfer data information specified in the transfer data table, it is necessary to draw a predetermined sprite in accordance with the display data table. The image data that is not resident in the resident video RAM 235 can always be stored in the image storage area 236a.

  Thus, even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, an image necessary for display can be read from the character ROM 234 in advance without delay and transferred to the normal video RAM 236. The corresponding effect can be displayed on the third symbol display device 81 while drawing the image of each sprite specified in the data table. Further, by describing the transfer data table, only the non-resident image data in the resident video RAM 235 can be easily and reliably transferred from the character ROM 234 to the normal video RAM 236.

  The pointer 233f is an address at which the corresponding drawing content or transfer data information of the transfer target image data is to be obtained from the display data table and the transfer data table stored in each of the display data table buffer 233d and the transfer data table buffer 233e. Is to be specified. The MPU 231 temporarily initializes the pointer 233f to 0 at the same time that the display data table is stored in the display data table buffer 233d. Then, the display setting processing of the V interrupt processing executed by the MPU 231 based on the V interrupt signal transmitted every 20 milliseconds when the drawing processing of the image for one frame is completed from the image controller 237 (FIG. 91 (b) ), The pointer update process (see S3005 in FIG. 129) is performed, and the value of the pointer 233f is incremented by one.

  Each time such an update of the pointer 233f is performed, the MPU 231 specifies the drawing content specified by the address indicated by the pointer 233f from the display data table stored in the display data table buffer 233d, (See FIG. 91), transfer data information of image data of a predetermined sprite to start transfer at that time is acquired from the transfer data table stored in the transfer data table buffer 233e, and the transfer data Add information to the created drawing list.

  Thereby, the effect corresponding to the display data table stored in the display data table buffer 233d is displayed on the third symbol display device 81. Therefore, the effect to be displayed on the third symbol display device 81 can be easily changed only by changing the display data table stored in the display data table buffer 233d. Therefore, regardless of the processing capability of the display control device 341, various effects can be displayed.

  Further, when the transfer data table stored in the transfer data table buffer 233e is stored, the sprite is drawn before the drawing of a predetermined sprite is started by the corresponding display data table based on the transfer data table. The image data that is not resident in the resident video RAM 235 used in the drawing of the image can be always stored in the image storage area 236a. Thus, even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, an image necessary for display can be read from the character ROM 234 in advance without delay and transferred to the normal video RAM 236. The corresponding effect can be displayed on the third symbol display device 81 while drawing the image of each sprite specified in the data table. Further, by describing the transfer data table, only the non-resident image data in the resident video RAM 235 can be easily and reliably transferred from the character ROM 234 to the normal video RAM 236.

  The drawing list area 233g is used by an image controller to draw one frame of image generated based on the display data table stored in the display data table buffer 233d and the transfer data table stored in the transfer data table buffer 233e. 237 is an area for storing a drawing list instructed by 237.

  Here, the drawing list will be described in detail with reference to FIG. FIG. 91 is a schematic diagram schematically showing the contents of the drawing list. The drawing list is an instruction table for instructing the image controller 237 to draw an image for one frame. As shown in FIG. 91, a back image used for one frame image, ..., effect (effect 1, effect 2, ...), character (character 1, character 2, ..., reserved ball number design 1, reserved ball number design 2, ..., error) For each sprite such as a pattern, detailed drawing information (detailed information) of the sprite is described. The drawing list also describes transfer data information for causing the image controller 237 to transfer predetermined image data from the character ROM 234 to the normal video RAM 236.

  The detailed drawing information (detailed information) of each sprite includes information indicating the RAM type (resident video RAM 235 or normal video RAM 236) in which the image data of the corresponding sprite (displayed object) is stored. The image controller 237 obtains the image data of the sprite from the memory area specified by the RAM type and the address. The detailed drawing information (detailed information) includes display position coordinates, enlargement ratio, rotation angle, translucent value, α blending information, color information, and filter designation information. A standard image generated from the image data of the sprite read from the video RAM is subjected to a scaling process according to a magnification, a rotation process according to a rotation angle, and a translucent process according to a translucent value. Subject to alpha blending information, perform synthesis processing with other sprites, perform color tone correction processing according to color information, and perform filtering processing according to the method specified by the information according to the filter specification information. Then, an image obtained by performing various processes on the display position indicated by the display position coordinates is drawn. Then, the drawn image is developed by the image controller 237 in either the first frame buffer 236b or the second frame buffer 236c specified by the drawing target buffer flag 233j.

  In the display data table stored in the display data table buffer 233d, the MPU 231 stores the drawing content specified by the address indicated by the pointer 233f and the content of other images to be drawn (for example, Based on the image and a warning image notifying that an error has occurred, detailed drawing information (detailed information) for all sprites used for drawing one frame of image is generated, and the detailed information is output for each sprite. Create a drawing list by rearranging.

  Here, in the detailed information of each sprite, the storage RAM type and the address of the data of the sprite (display object) correspond to the sprite type specified in the display data table and the sprite type specified from other image contents. Generated accordingly. That is, for each sprite, the area of the resident video RAM 235 in which the image data of the sprite is stored, or the sub-area of the image storage area 236a of the normal video RAM 236 is fixed, so that the MPU 231 Thus, the storage RAM type and the address where the image data of the sprite is stored can be immediately specified, and the information can be easily included in the detailed information of the drawing list.

  Further, the MPU 231 defines other information (display position coordinates, enlargement ratio, rotation angle, translucent value, α blending information, color information, and filter designation information) among the detailed information of each sprite in the display data table. Copy the information as it is.

  Further, when generating the drawing list, the MPU 231 sorts the sprites to be arranged on the rear side to the sprites to be arranged on the front side in the image of one frame, and obtains detailed drawing information for each sprite. (Detailed information). That is, in the drawing list, first, detailed information corresponding to the back image is described, and then, the third design (design 1, design 2,...), Effect (effect 1, effect 2,. Detailed information corresponding to each sprite is described in the order of (character 1, character 2,..., Reserved ball number symbol 1, reserved ball number symbol 2,..., Error symbol).

  The image controller 237 executes drawing processing of each sprite in accordance with the order described in the drawing list, and expands the drawn sprite in the frame buffer by overwriting. Therefore, in the image of one frame generated by the drawing list, the sprite drawn first can be arranged at the rearmost side, and the sprite drawn last can be arranged at the frontmost side.

  When the transfer data table stored in the transfer data table stored in the transfer data table buffer 233e includes the transfer data information at the address indicated by the pointer 233f, the MPU 231 stores the transfer data information (the character in which the transfer target image data is stored). The storage source start address and the storage source end address in the ROM 234 and the storage destination start address of the sub area provided in the image storage area 236a where the transfer target image data is to be stored are added to the end of the drawing list. If the drawing list includes the transfer data information, the image controller 237 reads an image from a predetermined area (the area indicated by the storage source start address and the storage source end address) of the character ROM 234 based on the transfer data information. The data is read, and the image data to be transferred is transferred to a predetermined sub-area (storage address) provided in the image storage area 236a of the normal video RAM 236.

  The time counter 233h is a counter that counts the effect time of the effect displayed on the third symbol display device 81 based on the display data table stored in the display data table buffer 233d. The MPU 231 sets time data indicating an effect time of an effect to be displayed based on the display data table in accordance with storing one display data table in the display data table buffer 233d. The time data is a value obtained by dividing the effect time by the image display time for one frame on the third symbol display device 81 (20 milliseconds in the present control example).

  Then, based on the V interrupt signal transmitted from the image controller 237 every 20 milliseconds when the rendering process and the display process of the image for one frame are completed, the V interrupt process executed by the MPU 231 (FIG. 112 (b) Each time the display setting process is performed, the time counter 233h is decremented by one (see S4007 in FIG. 127). As a result, when the value of the time counter 233h becomes 0 or less, the MPU 231 determines that the effect displayed by the display data table stored in the display data table buffer 233d has ended, and performs the operation in accordance with the end of the effect. Perform various processings to be performed.

  The stored image data determination flag 233i indicates that, for all sprites whose corresponding image data is not resident in the resident video RAM 235, the image data corresponding to the sprite is stored in the image storage area 236a of the normal video RAM 236. This is a flag indicating a storage state indicating whether or not there is any.

  The stored image data determination flag 233i is generated by an initialization process (see S1902 in FIG. 110) executed by the MPU 231 in the main process when the power is turned on. The stored image data determination flag 233i generated here is set to “OFF” indicating that the storage states of all sprites are not stored in the image storage area 236a.

  The stored image data determination flag 233i is updated when a transfer instruction of transfer target image data corresponding to one sprite is set in the normal image transfer setting process (see FIG. 131) executed by the MPU 231. Is In this update, the storage state corresponding to one sprite for which the transfer instruction is set is set to “ON” indicating that the corresponding image data is stored in the image storage area 236a. In addition, the image data of the other sprite that is to be stored in the sub area of the same image storage area 236a as the one sprite is always in an unstored state by storing the image data of the one sprite. Therefore, the storage state corresponding to the other sprite is set to “off”.

  The MPU 231 refers to the stored image data discrimination flag 233i when transferring image data of a sprite in which image data is not resident in the resident video RAM 235 from the character ROM 234 to the normal video RAM 236, and transmits the sprite of the transfer target sprite. It is determined whether the image data has already been stored in the image storage area 236a of the normal video RAM 235 (see S4513 in FIG. 131). If the storage state corresponding to the transfer target sprite is “OFF” and the corresponding image data is not stored in the image storage area 236a, a transfer instruction for the image data is set (see S4514 in FIG. 131). The image controller 237 causes the image data to be transferred from the character ROM 234 to a predetermined sub-area of the image storage area 236a. On the other hand, if the storage state corresponding to the sprite to be transferred is “ON”, since the corresponding image data has already been stored in the image storage area 236a, the transfer processing of the image data is stopped. As a result, useless transfer from the character ROM 234 to the normal video RAM 236 can be suppressed, and the processing load on each unit of the display control device 114 and the traffic on the bus line 240 can be reduced. it can.

  The drawing target buffer flag 233j is a frame buffer (hereinafter, referred to as a “drawing target buffer”) that develops an image drawn by the image controller 237 from the two frame buffers (the first frame buffer 236b and the second frame buffer 236c). If the drawing target buffer flag 233j is 0, the first frame buffer 236b is specified as the drawing target buffer, and if it is 1, the second frame buffer 236c is specified. Then, the information of the designated drawing target buffer is transmitted to the image controller 237 together with the drawing list (see S4602 in FIG. 132).

  As a result, the image controller 237 executes a drawing process of expanding the image drawn based on the drawing list on the specified drawing target buffer. Further, the image controller 237 reads out the rendered image information previously developed from a frame buffer different from the rendering target buffer in parallel with the rendering process, and sends the read image information to the third symbol display device 81 together with the drive signal. By transferring the information, a display process for displaying an image on the third symbol display device 81 is executed.

  The drawing target buffer flag 233j is updated at the same time that the drawing target buffer information is transmitted to the image controller 237 together with the drawing list. This updating is performed by inverting the value of the drawing target buffer flag 233j, that is, setting the value to “1” when the value is “0” and setting it to “0” when the value is “1”. Done by Thus, the drawing target buffer is alternately set between the first frame buffer 236b and the second frame buffer 236c every time the drawing list is transmitted. The transmission of the drawing list is performed by the MPU 231 based on the V interrupt signal transmitted from the image controller 237 every 20 milliseconds when the drawing process and the display process of the image for one frame are completed. It is performed every time the drawing process of the process (see FIG. 112B) is executed (see S4602 of FIG. 132).

  That is, at a certain timing, the first frame buffer 236b is specified as a frame buffer for developing an image of one frame, and the second frame buffer 236c is specified as a frame buffer from which image information of one frame is read. When the drawing process and the display process are executed, the second frame buffer 236c is designated as a frame buffer for developing the image of one frame 20 ms after the completion of the drawing process of the image of one frame, The first frame buffer 236b is designated as the frame buffer from which the image information is read. Thereby, the image information of the image previously developed in the first frame buffer 236b can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the second frame buffer 236c. You.

  Then, after the next 20 milliseconds, the first frame buffer 236b is designated as a frame buffer for developing an image of one frame, and the second frame buffer 236c is designated as a frame buffer from which image information of one frame is read. Is done. As a result, the image information of the image previously developed in the second frame buffer 236c can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the first frame buffer 236b. You. Thereafter, the frame buffer for expanding the image for one frame and the frame buffer from which the image information for one frame is read out are changed to one of the first frame buffer 236b and the second frame buffer 236c every 20 milliseconds. By alternately specifying the images, it is possible to continuously perform the display processing of the image of one frame in units of 20 milliseconds while performing the drawing processing of the image of one frame.

  The prize information storage area 233k is an area for storing the prize information received from the audio lamp control device 113, and is used to determine whether or not there is a big hit in the hold at the time of a super background notice or the like.

  In the gaming state storage area 233m, when a variation pattern command for display is received from the audio lamp control device 113, the gaming state is extracted from the received variation pattern command and stored. This gaming state storage area 233m is used in the opening command process (S2902) executed in the jackpot-related command process (FIG. 118) to determine whether or not the started big hit is a continuous big hit. Specifically, if it is determined that the probability is changing or the time is being reduced, it is determined that the jackpot is a continuous jackpot, and otherwise, it is determined that the jackpot is not a continuous jackpot.

  The variation history storage area 233n is an area in which a variation pattern based on a received command is stored in the variation pattern command processing, like the gaming state storage area 233m. The change history storage area 233n is used when setting a mass event in the map setting process (S3001) in the opening command process (FIG. 119) executed at the start of the big hit. More specifically, it will be described later in the description of the mass event setting table storage area 233t.

  The display effect counter 233o is a loop counter of 0 to 198, and is updated in the counter update process (S2207) executed in the V interrupt process (FIG. 112) of the display control device 114. This display effect counter is used to select a background type in the super background effect process (see FIG. 115), to set a mass event in the map setting process (FIG. 120), or to execute a super background SW process (see FIG. 124). Are used to select a background type, or to select a background addition flag to be set to ON in the big hit SW process (see FIG. 125).

  The continuation counter 233p is incremented when it is determined in the map setting process (see FIG. 120) executed at the start of the big hit effect that a continuous big hit has occurred. Based on the value of the continuation counter 233p and the value of the display effect counter 233o, a mass event defined in a mass setting table storage area 233t described later is set. The continuation counter 233p is initialized to 0 when the continuation of the jackpot ends (when the gaming state becomes normal).

The back image change flag 233q is set to ON in the back image change command processing (see FIG. 122) when the back image change command is received from the audio lamp control device 113. When the rear image change flag 233q is set to ON, in the normal image transfer setting process (see FIG. 131),
The super-background flag 233r is set to on when the back-image discrimination flag corresponding to the super-background notice is set to on in the back-image change command (see FIG. 122). By setting the super background flag 233r to ON, it is determined that the super background notice is being rendered. As a result, when a SW-related command is received from the audio lamp control device 113, the super background SW process (S3602) is executed in the SW-related command process (see FIG. 123). The super background SW process is a process based on the operation of the selection switch 270 and the like during the production of the super background notice. This super-background flag 233q is set to off at the end of the super-background announcement effect.

  The map storage area 233s is an area for storing information on maps and mass events set in the big hit effect. The map storage area 233s is an area where the information of the map and the mass event is stored in the process at the time of receiving the ending command, which is the end of the big hit effect, and is read when the continuous big hit is executed. is there. Thereby, when the continuous big hit is executed, the previously set map and mass event can be read out, and the continuous big hit effect can be executed.

  The mass setting table storage area 233t is referred to when a mass event is set in the map setting process (see FIG. 120) executed at the start of the big hit effect. Here, the details of the mass setting table storage area 233t will be described with reference to FIG. FIG. 87A is a schematic diagram schematically showing the contents of the mass setting table storage area 233t.

  In the cell setting table storage area 233t, a normal cell setting table 233t1 and a continuous cell setting table 233t2 are stored.

  The normal mass setting table 233t1 is a table that is referred to for setting a mass event when the first map is read (when the big hit does not continue and there is no passing history of the continuum).

  In the normal cell setting table 233t1, patterns A to C of cell events are defined based on the values of the jackpot type and the display effect counter 233o. Here, the jackpot type is determined using the information in the change history storage area 233n. For example, when the big hit type is “big hit A” and the value of the display effect counter 233o is “10”, “pattern B” is set as the mass event.

  Next, the continuous mass setting table 233t2 is a table that is referred to for setting a mass event when a continuous map is read (when the big hit is continued or when there is a continuation mass passing history). is there.

  Patterns A to E of the mass event are set in the continuous mass setting table 233t2 based on the values of the number of continuations (the value of the continuation counter 233p) and the display effect counter 233o. For example, when the number of continuations (the value of the continuation counter 233p) is “5” and the value of the display effect counter 233o is “10”, “Pattern B” is set as the mass event. In this control example, when the number of continuations is 5 or more, the “pattern D” of the mass event may be set, and when the number of continuations is 10 or more, the “pattern E” of the mass event Is configured to be set. This makes it possible to set a special mass event that is set only when the jackpot continues.

  The mass event storage area 233u is an area for storing the event of the mass selected during the big hit effect. Specifically, when the decision switch 270e is pressed in the big hit SW process (FIG. 125), the event of the determined cell is stored in the cell event storage area by the processing of S3807. The mass event stored in the mass event storage area 233u is referred to in the processing of S3101 in the round number command processing (see FIG. 119) for executing the round effect, and is used for determining the round number display data table. As a result, a round effect corresponding to the event of the determined cell can be executed.

  The route history storage area 233w is an area for storing selected (passed) cells in a jackpot effect. In the route history storage area 233w, information on the selected cell is added when the decision switch 270e is pressed in the big hit SW process (see FIG. 125). Thus, in the map setting process (see FIG. 120), it is possible to determine whether there is a passing history of continuum, whether there is a non-passing cell, and the like.

  The background addition flag 223x is a flag that is set to ON in accordance with the selected mass event in a jackpot effect. By setting the background addition flag 223x to ON, when a back image change command is received, a corresponding additional background can be set.

  The in-door change number counter 223y is an area for counting the number of changes performed during the display of the in-door background in the super background notice stage. The in-door variation counter 223y is set to a predetermined value (20 in this control example) when the in-door background is set, and is decremented by one each time a subsequent variation is executed. When the in-door fluctuation frequency counter 223y becomes 0, the winning information storage area 233k is referred to. If there is a big hit in the hold, the same background in the door is set again with a high probability, and if there is no big hit in the hold, A background other than the background inside the door is set with high probability.

<Regarding Control Process of Main Control Device in First Control Example>
Next, each control process executed by the MPU 201 in the main control device 110 will be described with reference to the flowcharts in FIGS. The processing of the MPU 201 is roughly divided into a start-up processing started upon power-on, a main processing executed after the start-up processing, and a timer started periodically (at intervals of 2 ms in this control example). There are an interrupt process and an NMI interrupt process started by input of a power failure signal SG1 to the NMI terminal. For convenience of explanation, first, a timer interrupt process and an NMI interrupt process will be described, and then a start process will be described. And the main processing will be described.

  FIG. 92 is a flowchart showing a timer interrupt process executed by MPU 201 in main controller 110. The timer interrupt process is a periodic process executed, for example, every 2 milliseconds. In the timer interrupt process, first, a process of reading various winning switches is executed (S101). That is, the state of the various switches connected to the main controller 110 is read, and the state of the switch is determined to store the detection information (winning detection information).

  Next, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are updated (S102). Specifically, the first initial value random number counter CINI1 is incremented by one, and is cleared to 0 when the counter value reaches a maximum value (299 in this control example). Then, the updated value of the first initial value random number counter CINI1 is stored in a corresponding buffer area of the RAM 203. Similarly, the second initial value random number counter CINI2 is incremented by one, and when the counter value reaches a maximum value (239 in this control example), it is cleared to 0, and the updated value of the second initial value random number counter CINI2 is incremented. Is stored in the corresponding buffer area of the RAM 203.

  Further, the first random number counter C1, the first type counter C2, the stop type selection counter C3, and the second random number counter C4 are updated (S103). Specifically, the first random number counter C1, the first type counter C2, the stop type selection counter C3, and the second random number counter C4 are each incremented by one, and their counter values are maximized (in this control example, When they reach 299, 99, 99, 239, respectively, they are cleared to 0, respectively. Then, the updated values of the counters C1 to C4 are stored in the corresponding buffer areas of the RAM 203.

  Next, in addition to the process for displaying on the first symbol display device 37, a special symbol variation process for setting a variation pattern of the third symbol and the like by the third symbol display device 81 is executed (S104). A start winning process is executed in accordance with a win (start winning) in the first winning port 64 (S105). The details of the special symbol change process and the start winning process will be described later with reference to FIGS. 93 to 95.

  After the start winning process, the normal symbol variation process, which is a process for displaying on the second symbol display device 83, is executed (S106), and the through gate passing process accompanying the passing of the ball at the normal entrance 67 is performed. Is executed (S107). The details of the ordinary symbol change process and the through gate passage process will be described later with reference to FIGS. 96 and 97. After the execution of the through gate passage process, the launch control process is executed (S108), and other processes to be executed periodically are executed (S109), and the timer interrupt process is terminated. The firing control process detects that the player is touching the operation handle 51 with the touch sensor 51a, and fires the ball on condition that the stop switch 51b for stopping firing is not operated. This is a process for determining ON / OFF of the data. The main controller 110 instructs the launch controller 112 to launch the ball when the launch of the ball is on.

  Next, with reference to FIG. 93, the special symbol changing process (S104) executed by the MPU 201 in the main control device 110 will be described. FIG. 93 is a flowchart showing the special symbol change process (S104). This special symbol change process (S104) is executed in the timer interrupt process (see FIG. 92), and the special symbol (first symbol) change display performed by the first symbol display device 37 or the third symbol display device This is a process for controlling the variable display of the third symbol performed at 81.

  In this special symbol change process, first, it is determined whether or not the present is a special symbol jackpot (S201). During the special symbol jackpot, the first symbol display device 37 and the third symbol display device 81 display a special symbol jackpot (including a special symbol jackpot game), and the special symbol jackpot. During the predetermined time after the end of the big hit game. If the result of the determination is that the special symbol is in a big hit (S201: Yes), this processing is terminated as it is.

  If it is not during the special symbol jackpot (S201: No), it is determined whether the display mode of the first symbol display device 37 is changing (S202), and the display mode of the first symbol display device 37 is changing. If not (S202: No), the value of the special symbol reserved ball number counter 203c (the number of times of suspension of the variable display in the special symbol) is acquired (S203). Next, it is determined whether or not the value (N) of the special symbol reserved ball number counter 203c is greater than 0 (S204), and if the value (N) of the special symbol reserved ball number counter 203c is 0 (S204: No), this process ends as it is.

  On the other hand, if the value (N) of the special symbol reserved ball number counter 203c is not 0 (S204: Yes), the value (N) of the special symbol reserved ball number counter 203c is subtracted by 1 (S205) and changed by the calculation. A reserved ball number command indicating the value of the special symbol reserved ball number counter 203c is set (S206). The set number-of-spheres command set here is stored in a command transmission ring buffer provided in the RAM 203, and is included in an external output process (S901) of a later-described main process (see FIG. 100) executed by the MPU 201. Are transmitted to the audio lamp control device 113. When receiving the reserved ball number command, the sound ramp control device 113 extracts the value of the special symbol reserved ball number counter 203c from the reserved ball number command, and stores the extracted value in the special symbol reserved ball number counter 223b of the RAM 223. .

  After setting the number-of-retained-balls command by the processing of S206, the data stored in the special symbol-reserved-ball storage area 203a is shifted (S207). In the process of S207, a process of sequentially shifting the data stored in the reserved first area to the reserved fourth area of the special symbol reserved ball storage area 203a to the execution area side is performed. More specifically, the first area in the hold → the execution area, the second area in the hold → the first area in the hold, the third area in the area → the second area in the hold, the fourth area in the area → the third area in the hold, etc. Shift data. After shifting the data, a special symbol variation start process for starting variable display on the first symbol display device 37 is executed (S208). The special symbol change start process will be described later with reference to FIG.

  In the process of S202, if the display mode of the first symbol display device 37 is changing (S202: Yes), it is determined whether or not the change time of the variable display executed on the first symbol display device 37 has elapsed. (S209). The fluctuation time of the fluctuation display executed in the first symbol display device 37 is determined according to the fluctuation pattern selected by the fluctuation type counter CS1 (determined according to the fluctuation pattern command), and the fluctuation time is determined. If has not elapsed (S209: No), the display content of the first symbol display device 37 is updated (S210), and this processing ends.

  On the other hand, in the process of S209, if the fluctuating time of the fluctuating display being executed has elapsed (S209: Yes), a display mode corresponding to the stop symbol of the first symbol display device 37 is set (S211). The setting of the stop symbol is performed in advance by a special symbol change start process (S208) described later with reference to FIG. When the special symbol change start process is executed, a special symbol lottery is performed based on the values of various counters stored in the execution area of the special symbol holding ball storage area 203a. More specifically, it is determined whether or not the special symbol is a big hit according to the value of the first random number counter C1. Is determined from jackpot A to jackpot D.

  In the present control example, when the big hit A occurs, the blue LED is turned on in the first symbol display device 37, and when the big hit B occurs, the red LED is turned on. In the case of a disconnection, the red LED and the green LED are turned on. The display of each LED is turned off when the next change display is started, but may be turned on only for a few seconds after the change stops.

  After the processing of S211 is completed, when the variable display being executed on the first symbol display device 37 is started, the lottery result of the special symbol performed by the special symbol variation start process (the current lottery result) is: It is determined whether it is a special symbol jackpot (S212). If the current lottery result is a special symbol jackpot (S212: Yes), the start of the special symbol jackpot is set (S213), and this processing ends. When the start of the special symbol big hit is set by the process of S213, when the big hit control process (S904) is executed in the main process (see FIG. 100), the process branches to S1001: Yes to open the opening command. Is set. As a result, in the third symbol display device 81, a big hit effect is started. In addition, in the process of S213, the probable changing flag 203e is set to off, or the value of the time reduction counter 203f is set to 0. This is because the state during the jackpot is the same as the initial state.

  In the process of S212, if the result of the current lottery is out of the special symbol (S212: No), it is determined whether or not the value of the counter for hourly working counter 203f is 1 or more (S214). If this is the case (S214: Yes), the value of the time reduction counter 203f is decremented by 1 (S215), and this processing ends. On the other hand, if the value of the counter 203f during time reduction is 0 (S214: No), the process of S215 is skipped, and the present process ends.

  Next, with reference to FIG. 94, the special symbol change start process (S208) executed by the MPU 201 in the main control device 110 will be described. FIG. 94 is a flowchart showing the special symbol change start process (S208). This special symbol change start process (S208) is a process executed in the special symbol change process (S104) of the timer interrupt process (see FIG. 92), and is stored in the execution area of the special symbol holding ball storage area 203a. Based on the values of the various counters performed, a lottery of "special symbol jackpot" or "special symbol departure" is performed (whether or not), and is performed by the first symbol display device 37 and the third symbol display device 81. This is a process for determining an effect pattern of a variable effect (a variable effect pattern).

  In the special symbol change start process, first, each value of the first random number counter C1, the first hit type counter C2, and the stop type selection counter C3 stored in the execution area of the special symbol holding ball storage area 203a is obtained. (S301).

  Next, it is determined whether the probable changing flag 203e of the RAM 203 is on (S302). The probable changing flag 203e is a flag indicating whether or not the pachinko machine 10 is in the special symbol probable state. If the probable changing flag 203e is on, it indicates that the pachinko machine 10 is in the special symbol probable state. If the probable changing flag 203e is off, it indicates that the pachinko machine 10 is in the normal state of the special symbol.

  When the probable changing flag 203e is on (S302: Yes), since the pachinko machine 10 is in the probable changing state of the special symbol, the value of the first random number counter C1 obtained in S301 and the first random number table are obtained. Based on the jackpot determination value for high probability at 202a, a lottery result of whether or not a special symbol jackpot is obtained is acquired (S303). Specifically, the value of the first per-random number counter C1 is compared with one of the thirty high-probability jackpot determination values stored in the first per-random number table 202a. As described above, 30 random numbers “0 to 29” are set as the random numbers that are the big hits of the special symbol at the time of the high probability, and the value of the first random number counter C1 and the random numbers that make these hits When the numerical values match, it is determined that the special symbol is a big hit. When the lottery result of the special symbol is obtained, the process proceeds to S305.

  On the other hand, in the processing of S302, if the probable changing flag 203e is off (S302: No), the value of the first random number counter C1 obtained in the processing of S301 is obtained because the pachinko machine 10 is in the normal state of the special symbol. And the lottery result of whether or not it is a special symbol big hit is acquired based on the big hit determination value for low probability in the first random number table 202a (S304). Specifically, the value of the first random number counter C1 is compared with three large probability determination values for low probability stored in the first random number table 202a. As described above, three random numbers of “0 to 2” are set as the random numbers of the special symbol at the time of the low probability, and the value of the first random number counter C1 and the random number of these random numbers are set. When the numerical values match, it is determined that the special symbol is a big hit. When the lottery result of the special symbol is obtained, the process proceeds to S305.

  Then, it is determined whether the lottery result of the special symbol acquired by the processing of S303 or S304 is a special symbol jackpot (S305), and if it is determined that the special symbol jackpot (S305: Yes), Based on the value of the first hit type counter C2 acquired in the process of S301, the display mode at the time of the big hit is set (S306). More specifically, the value of the first hit type counter C2 obtained in the process of S301 is compared with the random number value stored in the first hit type selection table 202b, and the four types of special symbol big hits (big hits) are compared. Among the A to D), it is determined what the jackpot type is. As described above, if the value of the first hit type counter C2 is in the range of “0 to 24”, it is determined that the hit is big hit A (16 rounds of probability change big hit), and if it is in the range of “25 to 49”, If it is determined to be jackpot B (four round probability variable jackpot), if it is in the range of “50 to 74”, it is determined to be jackpot C (16 rounds short jackpot), if it is in the range of “74 to 99”, It is determined that the jackpot is a jackpot D (a four-round time-saving jackpot) (see FIG. 81 (b)).

  In the process of S306, the display mode of the first symbol display device 37 (the lighting state of the LEDs 37A and 37B) is set according to the determined big hit type (big hits A to D). In order to stop and display the stop symbol corresponding to the big hit type on the third symbol display device 81, the big hit types (big hits A to D) are set as the stop types.

  Next, the fluctuation pattern at the time of the big hit is determined (S307). When the fluctuation pattern is set in the process of S307, the fluctuation time (display time) of the fluctuation effect on the first symbol display device 37 is set, and the third symbol display device 81 stops at the big hit symbol until it stops. The fluctuation time of the symbol is determined. At this time, the value of the variation type counter CS1 stored in the counter buffer of the RAM 203 is checked, and the variation time of the symbol variation such as normal reach and super reach is determined based on the value of the variation type counter CS1. The relationship between the value of the variation type counter CS1 and the variation time is defined in advance by a table or the like.

  For example, as the variation pattern for deviation, “complete deviation”, “departure normal reach”, “departure super reach”, and “departure special reach” are defined. Various types of "hit super reach" and "hit special reach" are specified.

  In the process of S305, when it is determined that the special symbol is out of the way (S305: No), the display mode at the time of being out of place is set (S308). In the process of S308, the display mode of the first symbol display device 37 is set to the display mode corresponding to the deviated symbol, and the value of the stop type selection counter C3 stored in the execution area of the special symbol holding ball storage area 203a is set. Based on this, the type of stop to be displayed on the third symbol display device 81 is set to reach out of front and rear, reach other than back and forth, or completely out of reach.

  Here, if the pachinko machine 10 is in the special symbol probable state, the value of the stop type selection counter C3 acquired in the process of S301 is compared with the random number value stored in the high probability stop type selection table. Then, the stop type is set. Specifically, if the value of the stop type selection counter C3 is in the range of "0 to 89", complete departure is set, and if it is in the range of "90 to 97", reach other than departure is set, and "98" , 99 ”, the reach is set. On the other hand, if the pachinko machine 10 is in the normal state of the special symbol, the stop type is set by comparing the value of the stop type selection counter C3 with the random number value stored in the low probability stop type selection table. I do. Specifically, if the value of the stop type selection counter C3 is in the range of “0 to 79”, complete out is set, and if it is in the range of “80 to 97”, reach other than out of front and back is set, and “98” , 99 ”, the reach is set.

  Next, a variation pattern at the time of departure is determined (S309). Here, the display time of the first symbol display device 37 is set, and the fluctuation time of the third symbol until the third symbol display device 81 stops at the off symbol is determined. At this time, as in the process of S308, the value of the variation type counter CS1 stored in the counter buffer of the RAM 203 is checked, and based on the value of the variation type counter CS1, the variation time of the symbol variation such as normal reach, super reach, etc. Is determined.

  Here, the various types of “winning super reach” and “missing super reach” include “super reach A”, “super reach B”, and other super reach, and are based on the numerical value of the fluctuation type counter CS1. Selected in the processing of S307 or S309. In the present control example, the super reach type (“super reach A”, “super reach B”, etc.) is selected by the MPU 201 of the main control device 110. However, the present invention is not limited to this. May be configured to be selected by the MPU 221. Thereby, the processing load on MPU 201 of main controller 110 can be reduced.

  When the processing of S307 or the processing of S309 is completed, next, a fluctuation pattern command for notifying the display control device 114 of the fluctuation pattern determined in the processing of S307 or S309 is set (S310). Next, a stop type command for notifying the display control device 114 of the stop type set in the processing of S306 or S308 is set (S311). These fluctuation pattern command and stop type command are stored in a command transmission ring buffer provided in the RAM 203, and these commands are transmitted to the sound ramp control device 113 in the processing of S901 of the main processing (see FIG. 100). Is done. The sound lamp control device 113 transmits the stop type command to the display control device 114 as it is. When the processing of S312 ends, the process returns to the special symbol change processing.

  Next, the start winning process (S105) executed by the MPU 201 in the main control device 110 will be described with reference to the flowchart in FIG. FIG. 95 is a flowchart showing the start winning processing (S105). This start winning process (S105) is executed in the timer interrupt process (see FIG. 92), and it is determined whether or not there is a winning (start winning) in the first winning opening 64. This is a process for executing the pre-reading of the lottery result in the special symbol from the holding process of the values indicated by the various random number counters and the values indicated by the held various random number counters.

  When the start winning process is executed, first, it is determined whether or not the ball has won the first winning opening 64 (start winning) (S401). Here, a ball entering the first winning port 64 is detected over three timer interrupt processes. Then, when it is determined that the ball has won the first winning opening 64 (S401: Yes), the value of the special symbol reserved ball number counter 203c (the number N of times of the variable display in the special symbol) is acquired (S402). Then, it is determined whether or not the value (N) of the special symbol reserved ball number counter 203c is less than the upper limit value (4 in the present control example) (S403).

  Then, there is no winning in the first winning opening 64 (S401: No), or even if there is a winning in the first winning opening 64, the value (N) of the special symbol reserved ball number counter 203c must be less than 4. If (S403: No), this process ends. On the other hand, if there is a winning in the first winning opening 64 (S401: Yes) and the value (N) of the special symbol reserved ball number counter 203c is less than 4 (S403: Yes), the special symbol reserved ball number counter is set. The value (N) of 203c is incremented by 1 (S404). Then, a reserved ball number command indicating the value of the special symbol reserved ball number counter 203c changed by the calculation is set (S405).

  The set number-of-spheres command set here is stored in a command transmission ring buffer provided in the RAM 203, and is included in an external output process (S901) of a later-described main process (see FIG. 100) executed by the MPU 201. Are transmitted to the audio lamp control device 113. When receiving the reserved ball number command, the sound ramp control device 113 extracts the value of the special symbol reserved ball number counter 203c from the reserved ball number command, and stores the extracted value in the special symbol reserved ball number counter 223b of the RAM 223. .

  After setting the pending ball number command in the processing of S405, the values of the first random number counter C1, first collision type counter C2, and stop type selection counter C3 updated in S103 of the timer interrupt processing are stored in the RAM 203. Is stored in the first one of the free reserved areas (the reserved first area to the reserved fourth area) of the special symbol reserved ball storage area 203a (S406). In the process of S406, the value of the special symbol reserved ball counter 203c is referred to, and if the value is 0, the reserved first area is set as the first area. Similarly, if the value is 1, the reserved second area is set as the first area, if the value is 2, the reserved third area is set as the initial area, and if the value is 3, the reserved fourth area is set as the initial area.

  Next, on the basis of the various counter values stored in the process of S406, the success or failure of the lottery in the special symbol (whether or not a big hit), its stop type (in the case of a big hit, a big hit type), and its fluctuation pattern are predicted. (S407).

  If the success or failure of the lottery in the special symbol, the stop type (big hit type in the case of a big hit), and the fluctuation pattern are predicted by the processing of S407, next, the predicted success or failure of the lottery, the predicted stop type, A winning information command including the predicted fluctuation pattern is set (S408).

  The winning information command set here is stored in a command transmission ring buffer provided in the RAM 203, and is executed in an external output process (S901) of a main process (see FIG. 100) described later executed by the MPU 201. It is transmitted to the sound lamp control device 113. Upon receiving the winning information command, the sound lamp control device 113 extracts a winning / wrong, a stop type, and a fluctuation pattern from the winning information command, and stores the information as winning information in the winning information storage area 223a.

  Next, it is determined whether or not the game state is a jackpot (S409). In the processing of S409, when it is determined that the gaming state is the probability change big hit (S409: Yes), the prefetching certainty change flag 203g provided in the RAM 203 is set to ON (S410), and this processing ends. On the other hand, when it is determined that the gaming state is not the jackpot (S409: No), the process proceeds to S411.

  In the process of S411, it is determined whether or not the gaming state is a time savings jackpot (S411). If it is determined that the gaming state is a time savings jackpot (S411: Yes), the prefetch certainty provided in the RAM 203 is being changed. The flag 203g is set to off (S412), and this process ends. On the other hand, in the process of S411, when it is determined that the gaming state is not the time saving big hit (S411: No), the process of S412 is skipped and the process ends.

  Next, with reference to the flowchart of FIG. 96, the ordinary symbol variation process (S106) executed by the MPU 201 in the main control device 110 will be described. FIG. 96 is a flowchart showing the ordinary symbol change processing (S106). The normal symbol change process (S106) is executed in the timer interrupt process (see FIG. 92), and the second symbol change display performed by the second symbol display device 83 or the electric control attached to the second winning opening 640 is performed. This is a process for controlling the opening time of the accessory 640a and the like.

  In the normal symbol variation process, first, it is determined whether or not the present is hitting a normal symbol (second symbol) (S501). As the winning of the normal symbol (the second symbol), during the display indicating the hit on the second symbol display device 83, and the opening / closing control of the electric accessory 640a attached to the second winning opening 640 is performed. In the middle of being included. If the result of the determination is that a normal symbol (second symbol) is being hit (S501: Yes), the present process ends.

  On the other hand, if the normal symbol (second symbol) is not being hit (S501: No), it is determined whether or not the display mode of the second symbol display device 83 is changing (S502), and the second symbol display device is determined. If the display mode of 83 is not fluctuating (S502: No), the value of the ordinary symbol reserved ball number counter 203d (the number M of suspended display of the ordinary symbol in the ordinary symbol) is acquired (S503). Next, it is determined whether or not the value (M) of the ordinary symbol retaining ball number counter 203d is greater than 0 (S504). If the value (M) of the ordinary symbol retaining ball number counter 203d is 0 (S504: S504). No), this process ends as it is. On the other hand, if the value (M) of the ordinary symbol retaining ball number counter 203d is not 0 (S504: Yes), the value (M) of the ordinary symbol retaining ball number counter 203d is decremented by 1 (S505).

  Next, the data stored in the ordinary symbol holding ball storage area 203b is shifted (S506). In the process of S506, a process of sequentially shifting the data stored in the reserved first area to the reserved fourth area of the ordinary symbol reserved ball storage area 203b to the execution area side is performed. More specifically, the first area in the hold → the execution area, the second area in the hold → the first area in the hold, the third area in the area → the second area in the hold, the fourth area in the area → the third area in the hold, etc. Shift data. After the data is shifted, the value of the second random number counter C4 stored in the execution area of the ordinary symbol holding sphere storage area 203b is obtained (S507).

  Next, it is determined whether or not the value of the during-hours counter 203f of the RAM 203 is 1 or more (S508). The time reduction counter 203f is a counter that indicates whether or not the pachinko machine 10 is in the normal symbol time reduction state. If the value of the counter 203f during time reduction is 0, it indicates that the pachinko machine 10 is in a normal state of a normal symbol.

  When the value of the time reduction counter 203f is 1 or more (S508: Yes), it is determined whether or not the present is in a special symbol jackpot (S509). During the special symbol jackpot, the first symbol display device 37 and the third symbol display device 81 display a special symbol jackpot (including a special symbol jackpot game), and the special symbol jackpot. During the predetermined time after the end of the big hit game. If the result of the determination is that the special symbol is in a big hit (S509: Yes), the process proceeds to S511. In the present control example, during the special symbol big hit, it is configured such that the lottery of the ordinary symbol is hard to win.

  During the special symbol jackpot (that is, during the special game state), the player hits the ball in an attempt to win the specific winning opening 65a. , And the ball is in a state where it easily enters. Here, in the present control example, the electric accessory 640a attached to the second winning opening 640 is not opened during the special symbol big hit (that is, during the special game state). Accordingly, it is possible to suppress as much as possible a ball trying to win the specific winning opening 65a from entering the second winning opening 640.

  In addition, even if the ball is suppressed from entering the second winning opening 640 during the special symbol jackpot, the ball enters the first winning opening 64. As a result, in most cases, while the pachinko machine 10 is in the special game state, the number of reserved balls for the first winning port 64 becomes maximum (four times).

  In the process of S509, if it is not during the special symbol jackpot (S509: No), since the pachinko machine 10 is not in the special symbol jackpot and the pachinko machine 10 is in the normal symbol time saving state, it is acquired in the process of S507. Based on the value of the second random number counter C4 thus obtained and the second random number table for high probability, a lottery result of whether or not a normal symbol has been won is obtained (S510). Specifically, the value of the second random number counter C4 is compared with the random number value stored in the second random number table for high probability. As described above, if the value of the second hit type counter C4 is in the range of “5 to 204”, it is determined that the hit is a normal symbol, and if it is in the range of “0 to 4,205 to 239”, It is determined that the symbol is out of the ordinary pattern (see FIG. 81 (d)).

  In the process of S508, if the value of the during-hours-saving counter 203f is 0 (S508: No), the process proceeds to S511. In the process of S511, since the pachinko machine 10 is in the special symbol jackpot or the pachinko machine 10 is in the normal state of the normal symbol, the value of the second random number counter C4 obtained in the process of S507 and the low Based on the second random number table for probabilities, a lottery result is obtained as to whether or not a normal symbol has been won (S511). Specifically, the value of the second random number counter C4 is compared with the random number value stored in the second random number table for low probability. As described above, if the value of the second hit type counter C4 is in the range of “5 to 28”, it is determined that the hit is a normal symbol, and if the value is in the range of “0 to 4, 29 to 239”, It is determined that the symbol is out of the ordinary pattern (see FIG. 81 (d)).

  Next, it is determined whether the lottery result of the ordinary symbol acquired by the processing of S510 or S511 is a hit of the ordinary symbol (S512), and when it is determined that it is a hit of the ordinary symbol (S512: Yes). Then, the display mode of the hit is set (S513). In the process of S513, after the variable display on the second symbol display device 83 is completed, the symbol “O” is set to be lit and displayed as a stop symbol (second symbol).

  Then, it is determined whether or not the value of the time reduction counter 203f is 1 or more (S514). If the value of the time reduction counter 203f is 1 or more (S514: Yes), the special symbol is hit at the moment. It is determined whether or not it is (S515). If the result of the determination is that the special symbol is being hit (S515: Yes), the process proceeds to S517. In the present control example, during the special symbol big hit, in order to suppress the ball from entering the second winning opening 640 as much as possible, even if the normal symbol hits, similarly to the case where the normal symbol comes off. , The number of times and the opening time of the electric accessory 640a are set.

  In the process of S515, if the special symbol is not in the special jackpot (S515: No), the pachinko machine 10 is not in the special symbol jackpot and the pachinko machine 10 is in the normal symbol time saving state, so the second winning opening 640 Is set to one second, and the number of times of opening is set to two (S516), and the process proceeds to S519. In the process of S514, if the value of the time reduction counter 203f is 0 (S514: No), the process proceeds to S517. In the processing of S517, since the pachinko machine 10 is in the special symbol jackpot or the pachinko machine 10 is in the normal state of the normal symbol, the open period of the electric accessory 640a attached to the second winning opening 640 is set to 0. In addition to the setting of 2 seconds, the number of times of release is set to 1 (S517), and the process proceeds to S519.

  In the process of S512, when it is determined that the symbol is out of the ordinary pattern (S512: No), the display mode at the time of the out of pattern is set (S518). In the process of S518, after the variable display on the second symbol display device 83 is completed, a setting is made so that a symbol “x” is lit as a stopped symbol (second symbol). When the setting of the display mode at the time of departure is completed, the process proceeds to S519.

  In the processing of S519, it is determined whether the value of the time reduction counter 203f is 1 or more (S519). If the value of the time reduction counter 203f is 1 or more (S519: Yes), the fluctuation in the second symbol display device 83 is performed. The change time of the display is set to 3 seconds (S520), and the process ends. On the other hand, if the value of the counter 203f during time saving is 0 (S519: No), the fluctuation time of the fluctuation display on the second symbol display device 83 is set to 30 seconds (S521), and this processing ends. Thus, except during the special symbol jackpot, when the normal symbol has a high probability, the fluctuation display time is very short, "30 seconds → 3 seconds", compared to when the normal symbol has a low probability, and further, Since the release period of the second winning port 640 is very long, that is, “0.2 seconds × 1 time → 1 second × 2 times”, the ball can easily enter the second winning port 640.

  In the process of S502, if the display mode of the second symbol display device 83 is changing (S502: Yes), it is determined whether or not the change time of the variable display executed in the second symbol display device 83 has elapsed. (S522). Here, the fluctuation time is a time set beforehand by the processing of S520 or the processing of S521 before the fluctuation display is started on the second symbol display device 83.

  In the processing of S522, if the fluctuation time has not elapsed (S522: No), this processing ends. On the other hand, in the process of S522, if the variation time of the variation display being executed has elapsed (S522: Yes), the stop display of the second symbol display device 83 is set (S523). In the process of S523, the lottery of the ordinary symbol is a hit, and if the display mode is set by the process of S513, the symbol “○” as the second symbol is stopped and displayed on the second symbol display device 83 (lighting). Display). On the other hand, if the lottery of the ordinary symbol is lost and the display mode is set by the processing of S518, the “X” symbol as the second symbol is stopped (lit) on the second symbol display device 83. Is set to When the stop display is set by the process of S523, when the second symbol display updating process (see S907) of the main process (see FIG. 100) is executed next, the variable display on the second symbol display device 83 is changed. After finishing, the stopped symbol (the second symbol) is stopped (lit) on the second symbol display device 83 in the display mode set in the process of S513 or the process of S518.

  Next, when the variation display being executed on the second symbol display device 83 is started, whether the lottery result of the ordinary symbol performed by the ordinary symbol variation process (the current lottery result) is a hit of the ordinary symbol or not. Is determined (S524). If the current lottery result is a normal symbol hit (S524: Yes), the opening / closing control of the electric accessory 640a attached to the second winning opening 640 is set (S525), and this processing is ended. When the opening / closing control start of the electric accessory 640a is set by the process of S525, when the electric accessory opening / closing process (see S905) of the main process (see FIG. 100) is executed next, the electric accessory 640a is opened. The opening / closing control is started, and the opening / closing control of the electric accessory 640a is continued until the opening time and the number of times of opening set in the processing of S516 or S517 are completed. On the other hand, in the process of S524, if the current lottery result is out of the ordinary symbol (S524: No), the process of S525 is skipped, and the present process ends.

  Next, a through gate passage process (S107) executed by the MPU 201 in the main control device 110 will be described with reference to the flowchart in FIG. FIG. 97 is a flowchart showing this through gate passage processing (S107). This through gate passage processing (S107) is executed in the timer interruption processing (see FIG. 92), and it is determined whether or not a ball has passed through the normal entrance 67, and if a ball has passed, the first pass is performed. This is a process for acquiring and suspending the value indicated by the random number counter C4 per two.

  In the through gate passage process, first, it is determined whether or not the ball has passed the normal entrance 67 (S601). Here, the passage of a ball at the normal entrance 67 is detected over three timer interrupt processes. Then, when it is determined that the ball has passed the normal entrance 67 (S601: Yes), the value of the normal symbol holding ball number counter 203d (the number of times M of the variable display in the normal symbol is held) is acquired (S602). Then, it is determined whether or not the value (M) of the normal symbol reserved ball number counter 203d is less than the upper limit value (4 in this control example) (S603).

  Whether the ball has not passed through the normal entrance 67 (S601: No), or even if the ball has passed through the normal entrance 67, the value (M) of the ordinary symbol holding ball counter 203d is less than 4 If not (S603: No), this processing ends. On the other hand, if the ball passes through the normal entrance 67 (S601: Yes) and the value (M) of the ordinary symbol retaining ball number counter 203d is less than 4 (S603: Yes), the ordinary symbol retaining ball number counter The value (M) of 203d is incremented by 1 (S604). Then, the value of the second random number counter C4 updated in S103 of the above-described timer interrupt processing is stored in the first one of the free holding areas (first holding area to fourth holding area) of the ordinary symbol holding ball storage area 203b of the RAM 203. (S605), and the process ends. In the process of S605, the value of the normal symbol holding ball counter 203d is referred to, and if the value is 0, the holding first area is set as the first area. Similarly, if the value is 1, the reserved second area is set as the first area, if the value is 2, the reserved third area is set as the initial area, and if the value is 3, the reserved fourth area is set as the initial area.

  FIG. 98 is a flowchart showing the NMI interrupt processing executed by the MPU 201 in the main control device 110. The NMI interrupt process is a process executed by the MPU 201 of the main control device 110 when the power of the pachinko machine 10 is shut down due to a power failure or the like. By this NMI interrupt processing, the power-off occurrence information is stored in the RAM 203. That is, when the power of the pachinko machine 10 is cut off due to the occurrence of a power failure or the like, the power failure signal SG1 is output from the power failure monitoring circuit 252 to the NMI terminal of the MPU 201 in the main control device 110. Then, the MPU 201 interrupts the control being executed, starts the NMI interrupt process, stores the power-off occurrence information in the RAM 203 as the setting of the power-off occurrence information, and ends the NMI interrupt process (S701). I do.

  Note that the above-described NMI interrupt processing is executed in the same manner by the payout and departure control device 111, and the power-off occurrence information is stored in the RAM 213 by the NMI interrupt processing. That is, when the power of the pachinko machine 10 is cut off due to the occurrence of a power failure or the like, the power failure signal SG1 is output from the power failure monitoring circuit 252 to the NMI terminal of the MPU 211 in the payout control device 111, and the MPU 211 interrupts the control being executed. Thus, the NMI interrupt process is started.

  Next, with reference to FIG. 99, a description will be given of a start-up process executed by the MPU 201 in the main control device 110 when the main control device 110 is powered on. FIG. 99 is a flowchart showing the start-up process. This start-up process is started by a reset when the power is turned on. In the start-up process, first, an initial setting process accompanying power-on is executed (S801). For example, a predetermined value is set in the stack pointer. Next, a wait process (one second in this control example) is executed in order to wait until the sub-side control devices (peripheral control devices such as the voice lamp control device 113 and the payout control device 111) become operable. (S802). Then, access to the RAM 203 is permitted (S803).

  Thereafter, it is determined whether or not the RAM erase switch 122 (see FIG. 3) provided on the power supply 115 is turned on (S804). If it is turned on (S804: Yes), the process proceeds to S810. On the other hand, if the RAM erasure switch 122 is not turned on (S804: No), it is further determined whether or not power-off occurrence information is stored in the RAM 203 (S805). Since there is a possibility that the processing at the time of the previous power shutdown may not have been completed normally, the processing also shifts to S810 in this case.

  If the power-off occurrence information is stored in the RAM 203 (S805: Yes), the RAM determination value is calculated (S806). If the calculated RAM determination value is not normal (S807: No), that is, the calculated RAM If the determination value does not match the RAM determination value stored when the power is turned off, the backed-up data has been destroyed, and the process also shifts to S810 in such a case. The RAM determination value is, for example, a checksum value at the work area address of the RAM 203, as described later in the processing of S914 of the main processing (see FIG. 100). Instead of the RAM determination value, the validity of the backup may be determined based on whether or not the keyword written in a predetermined area of the RAM 203 is correctly stored.

  In the process of S810, a payout initialization command is transmitted to initialize the payout control device 111 serving as the sub-side control device (peripheral control device) (S810). Upon receiving the payout initialization command, the payout control device 111 clears an area (work area) other than the stack area of the RAM 213, sets an initial value, and enters a state where the payout control of the game ball can be started. After transmitting the pay-out initialization command, main controller 110 executes an initialization process of RAM 203 (S811, S812).

  As described above, in the pachinko machine 10, when the RAM data is initialized when the power is turned on, for example, when the hall is opened, the power is turned on while pressing the RAM erase switch 122. Therefore, if the RAM erasure switch 122 is pressed at the time of the start-up processing, the RAM initialization processing (S811, S812) is executed. Similarly, the initialization process of the RAM 203 (S811 and S812) is executed also when the power-off occurrence information is not set or when a backup abnormality is confirmed by the RAM determination value (checksum value or the like). . In the initialization processing of the RAM (S811, S812), the used area of the RAM 203 is cleared to 0 (S811), and thereafter, the initial value of the RAM 203 is set (S812). After the execution of the initialization process of the RAM 203, the process proceeds to S813.

  On the other hand, if the RAM erasure switch 122 is not turned on (S804: No), power-off occurrence information is stored (S805: Yes), and if the RAM determination value (checksum value, etc.) is normal (S804). S807: Yes), the power-off information is cleared while the data backed up in the RAM 203 is held (S808). Next, a payout return command at the time of power restoration for returning the sub-side control device (peripheral control device) to the gaming state at the time of driving power cutoff is transmitted (S809), and the process proceeds to S813. When the payout control device 111 receives the payout return command, the payout control device 111 is ready to start the payout control of the game balls while holding the data stored in the RAM 213.

  In the process of S813, the effect permission command is transmitted to the sound lamp control device 113, and the sound lamp control device 113 and the display control device 114 are permitted to execute various effects. Next, an interrupt is permitted (S814), and the process proceeds to a main process described later.

  Next, a main process executed by the MPU 201 in the main control device 110 after the above-described startup process will be described with reference to FIG. FIG. 100 is a flowchart showing the main processing. In this main processing, main processing of the game is executed. As an outline, each process of S901 to S907 is executed as a periodic process with a period of 4 ms, and the counter updating process of S910 and S911 is executed in the remaining time.

  In the main process, first, during execution of the timer interrupt process (see FIG. 92), output data such as commands stored in a command transmission ring buffer provided in the RAM 203 is transmitted to each of the sub-side control devices (peripheral devices). An external output process to be transmitted to the control device is executed (S901). Specifically, the presence / absence of winning detection information detected in the switch reading process in S101 in the timer interrupt process (see FIG. 92) is determined. Send a prize ball command. In addition, the CPU transmits the number-of-remaining-balls command set in the special symbol change process (see FIG. 93) and the start winning process (see FIG. 95) to the sound lamp control device 113. Further, the winning information command set in the starting winning process (see FIG. 95) is transmitted to the sound lamp control device 113. Further, by this external output processing, a variation pattern command, a stop type command, and the like necessary for the variation display of the third symbol by the third symbol display device 81 are transmitted to the sound lamp control device 113. Further, the opening command, the number of rounds command, and the ending command set in the jackpot control process (see FIG. 101) are transmitted to the sound lamp control device 113. In addition, when launching a ball, a ball launch signal is transmitted to the launch control device 112.

  Next, the value of the variation type counter CS1 is updated (S902). Specifically, the variation type counter CS1 is incremented by one, and is cleared to zero when the counter value reaches a maximum value (198 in this control example). Then, the updated value of the variation type counter CS1 is stored in a corresponding buffer area of the RAM 203.

  When the variation type counter CS1 is updated, the winning ball counting signal and the abnormal payout signal received from the payout control device 111 are read (S903). A jackpot control process for opening or closing the specific winning port (large opening port) 65a of the winning device 65 is executed (S904). In the jackpot control process, the specific winning port 65a is opened in each round of the jackpot state, and it is determined whether the maximum opening time of the specific winning port 65a has elapsed or the specified number of balls have been won in the specific winning port 65a. When any one of these conditions is satisfied, the specific winning opening 65a is closed. The opening and closing of the specific winning opening 65a is repeatedly executed a predetermined number of rounds. In the present control example, the jackpot control process (S904) is executed in the main process, but may be executed in the timer interrupt process.

  Next, an electric accessory opening / closing process for controlling opening / closing of the electric accessory 640a associated with the second winning opening 640 is executed (S905). In the electric auditors product opening / closing process, the opening / closing control of the electric auditors accessory 640a is started when the opening / closing control start of the electric auditors accessory 640a is set by the process of S525 of the normal symbol variation process (see FIG. 96). The opening / closing control of the electric accessory 640a is continued until the opening time and the number of times of opening set in the processing of S516 or the processing of S517 in the normal symbol variation processing are ended.

  Next, a first symbol display update process for updating the display of the first symbol display device 37 is executed (S906). In the first symbol display updating process, when a variation pattern is set by the process of S307 or the process of S309 of the special symbol variation start process (see FIG. 94), the variation display according to the variation pattern is performed by the first symbol display. Beginning at device 37. In this control example, of the LEDs 37A and 37B of the first symbol display device 37, for example, if the currently lit LED is red until the fluctuation time elapses after the fluctuation starts, the red LED Is turned off and the green LED is turned on. If the green LED is turned on, the green LED is turned off and the blue LED is turned on. If the blue LED is turned on, the blue LED is turned on. Is turned off and the red LED is turned on.

  The main processing is executed every 4 milliseconds. However, if the lighting color of the LED is changed each time the main processing is executed, the player cannot confirm the change in the lighting color of the LED. Therefore, a counter (not shown) is counted by one each time the main process is executed so that the player can confirm the change of the lighting color of the LED. Change the lighting color of. That is, the lighting color of the LED is changed every 0.4 seconds. The value of the counter is reset to 0 when the lighting color of the LED is changed.

  In the first symbol display updating process, when the variation time corresponding to the variation pattern set by the process of S307 or the process of S309 of the special symbol variation start process (see FIG. 94) ends, the first symbol display device is activated. The variable display executed in 37 is ended, and the stopped symbol (first symbol) is displayed in the first symbol display in the display mode set by the process of S306 or the process of S308 of the special symbol variation start process (see FIG. 94). A stop display (lighting display) is displayed on the device 37.

  Next, a second symbol display update process for updating the display of the second symbol display device 83 is executed (S907). In the second symbol display updating process, when the variation time of the second symbol is set by the process of S520 or the process of S521 of the ordinary symbol variation process (see FIG. 96), the variation display is started on the second symbol display device 83. I do. As a result, the second symbol display device 83 performs a variable display in which the symbol “O” and the symbol “X” as the second symbol are alternately turned on. In the second symbol display updating process, when the stop display of the second symbol display device 83 is set by the process of S523 of the ordinary symbol variation process (see FIG. 96), the process is executed by the second symbol display device 83. Is stopped, and the stopped symbol (second symbol) is stopped and displayed on the second symbol display device 83 in the display mode set by the process of S513 or the process of S518 of the normal symbol variation process (see FIG. 96). Lights up).

  Thereafter, it is determined whether or not power-off occurrence information is stored in the RAM 203 (S908). If power-off occurrence information is not stored in the RAM 203 (S908: No), the power failure monitoring circuit 252 sends a power failure signal. SG1 is not output, and the power is not cut off. Therefore, in such a case, it is determined whether or not the next main processing execution timing has been reached, that is, whether or not a predetermined time (4 ms in this control example) has elapsed from the start of the current main processing (S909). If the predetermined time has already passed (S909: Yes), the process proceeds to S901, and the above-described processes after S901 are repeatedly executed.

  On the other hand, if the predetermined time has not yet elapsed from the start of the main processing this time (S909: No), during the remaining time until the predetermined time, that is, the remaining time until the next main processing execution timing is reached, The first initial value random number counter CINI1, the second initial value random number counter CINI2, and the variation type counter CS1 are repeatedly updated (S910, S911).

  First, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are updated (S910). Specifically, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are incremented by one, and cleared to 0 when the counter value reaches the maximum value (299, 239 in this control example). . Then, the updated values of the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are stored in the corresponding buffer areas of the RAM 203, respectively. Next, the variation type counter CS1 is updated by the same method as the process of S902 (S911).

  Here, since the execution time of each processing of S901 to S907 changes according to the state of the game, the remaining time until the execution timing of the next main processing is not constant but fluctuates. Therefore, by repeatedly executing the updating of the first initial value random number counter CINI1 and the second initial value random number counter CINI2 using the remaining time, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 (that is, , The initial value of the first random number counter C1 and the initial value of the second random number counter C4), and similarly, the fluctuation type counter CS1 can be updated at random.

  In addition, in the process of S908, if the power-off occurrence information is stored in the RAM 203 (S908: Yes), the power is shut off due to the occurrence of the power failure or the power-off, and the power failure monitoring circuit 252 outputs the power failure signal SG1. As a result, since the NMI interrupt processing of FIG. 98 has been executed, the processing at the time of power shutdown after S912 is executed. First, the occurrence of each interrupt process is prohibited (S912), and a power-off command indicating that the power is turned off is sent to another control device (a peripheral control device such as the payout control device 111 or the sound lamp control device 113). (S913). Then, the RAM determination value is calculated, the value is stored (S914), access to the RAM 203 is prohibited (S915), and the infinite loop is continued until the power is completely shut off and the process cannot be executed. Here, the RAM determination value is, for example, a checksum value in a stack area and a work area of the RAM 203 to be backed up.

  Note that the process of S908 is performed at the end of a series of processes corresponding to game state changes performed in S901 to S907, or at the end of one cycle of the processes of S910 and S911 performed within the remaining time. It is running. Therefore, in the main processing of the main control device 110, the power-off occurrence information is checked at the timing when each setting is completed. Therefore, when returning from the power-off state, the processing is performed after the startup processing is completed. The processing can be started from the processing of S901. That is, the process can be started from the process of S901, as in the case where the process is initialized in the startup process. Therefore, in the process at the time of power-off, even if the contents of each register used by the MPU 201 are not saved to the stack area or the value of the stack pointer is not saved, the stack When the pointer is set to a predetermined value (initial value), the processing can be started from the processing of S901. Therefore, the control load on main controller 110 can be reduced, and accurate control can be performed without erroneous operation or runaway of main controller 110.

  Next, the jackpot control process (S904) executed by the MPU 201 in the main control device 110 will be described with reference to the flowchart in FIG. FIG. 101 is a flowchart showing the jackpot control process (S904). This jackpot control process (S904) is executed in the main process (see FIG. 100), and when the pachinko machine 10 is in the special symbol jackpot state, execution of various effects according to the jackpot and a specific winning opening ( This is a process for opening or closing the large opening port 65a.

  In the jackpot control process, first, it is determined whether a special symbol jackpot is started (S1001). Specifically, the process of S213 of the special symbol variation process (see FIG. 93) is executed, and if the start of the special symbol big hit is set, it is determined that the special symbol big hit is started. In the process of S1001, if a special symbol jackpot is started (S1001: Yes), an opening command is set (S1002), and the process ends.

  The opening command set here is stored in a command transmission ring buffer provided in the RAM 203, and is used in the external output processing (S901) of the main processing (see FIG. 100) executed by the MPU 201, in the sound ramp control. It is transmitted to the device 113. Upon receiving the opening command, the sound lamp control device 113 transmits a display opening command to the display control device 114. When a display opening command is received by the display control device 114, an opening effect is started in the third symbol display device 81.

  On the other hand, if the special symbol jackpot has not been started in the processing of S1001 (S1001: No), it is determined whether or not the special symbol jackpot is in progress (S1003). During the special symbol jackpot, the first symbol display device 37 and the third symbol display device 81 display a special symbol jackpot (including a special symbol jackpot game), and the special symbol jackpot. During the predetermined time after the end of the big hit game. In the processing of S1003, if it is not during the special symbol big hit (S1003: No), this processing is ended as it is.

  On the other hand, in the process of S1003, if the special symbol is in a big hit (1003: Yes), it is determined whether it is the start timing of a new round (S1004). If it is the start timing of a new round (S1004: Yes), the special winning opening (large opening) 65a is opened (S1005), and a round number command indicating the number of newly started rounds is set (S1006). After setting the number-of-rounds command, the process ends. The round number command set here is stored in a command transmission ring buffer provided in the RAM 203, and is used as an audio lamp in the external output processing (S901) of the main processing (see FIG. 100) executed by the MPU 201. It is transmitted to the control device 113. When receiving the round number command, the sound ramp control device 113 extracts the round number from the round number command. Then, a display round number command corresponding to the extracted round number is transmitted to the display control device 114. When the display control device 114 receives the display round number command, the third symbol display device 81 starts a new round effect.

  On the other hand, in the process of S1004, if it is not the start timing of a new round (S1004: No), it is determined whether the closing condition of the specific winning opening (large opening) 65a is satisfied (S1007). Specifically, when a predetermined time (for example, 30 seconds) has elapsed after opening the specific winning opening (large opening) 65a, or when a predetermined number of balls have been released after opening the specific winning opening (large opening) 65a. When winning (for example, 10), it is determined that the closing condition is satisfied.

  In the processing of S1007, when the closing condition of the specific winning opening (large opening) 65a is satisfied (S1007: Yes), the specific winning opening (large opening) 65a is closed (S1008), and this processing ends. I do. On the other hand, when the closing condition of the specific winning opening (large opening) 65a is not satisfied (S1007: No), it is determined whether it is the timing to start the ending effect (S1009). Specifically, when the special game state (all 16 or 4 rounds) in which a larger amount of prize balls are paid out than usual is completed, it is determined that it is time to start the ending effect.

  In the processing of S1009, if it is the ending effect start timing (S1009: Yes), the ending command is set (S1010). The ending command set here is stored in a ring buffer for command transmission provided in the RAM 203, and is used in the external output processing (S901) of the main processing (see FIG. 100) executed by the MPU 201 to control the sound ramp control. It is transmitted to the device 113. Upon receiving the ending command, the sound ramp control device 113 selects the display mode of the ending effect based on the winning information stored in the winning information storage area 223a of the RAM 223. Then, a display ending command corresponding to the display mode of the selected ending effect is transmitted to the display control device 114. When the display ending command is received by the display control device 114, an ending effect is started in the third symbol display device 81. Next, it is determined whether or not the current jackpot is the jackpot A or the jackpot B (S1011). If the jackpot A or the jackpot B is determined (S1011: Yes), the high probability of the special symbol after the end of the jackpot A or the jackpot B is determined. In order to shift to the state, the probable changing flag 203e is set to ON (S1012), and the process shifts to S1015.

  In the process of S1011, when it is determined that the current jackpot is not the jackpot A or the jackpot (that is, the jackpot C or the jackpot D), after the jackpot C or the jackpot D ends, the normal symbol is shifted to the time saving state. Then, the probable changing flag 203e is set to off (S1013), the value of the time reduction counter 203f is set to 100 (S1014), and the process proceeds to S1015. In the processing of S1015 executed after the processing of S1013 or S1014, the end of the jackpot is set, and this processing ends.

  On the other hand, if it is not the ending start timing in the process of S1009 (S1009: No), the process ends. By the jackpot control process (see FIG. 101), various settings relating to the jackpot can be performed.

<Regarding the control processing of the audio lamp control device in the first control example>
Next, each control process executed by the MPU 221 in the audio lamp control device 113 will be described with reference to FIGS. The processes of the MPU 221 are roughly classified into a start-up process started upon power-on and a main process executed after the start-up process.

  First, with reference to FIG. 102, a start-up process executed by the MPU 221 in the audio lamp control device 113 will be described. FIG. 102 is a flowchart showing the start-up processing. This startup process is started when the power is turned on.

  When the start-up process is executed, first, an initial setting process accompanying power-on is executed (S1101). Specifically, a predetermined value is set in the stack pointer. Thereafter, depending on whether or not the power-off processing flag is turned on, the current start-up processing is performed during the execution of the power-off processing in S1217 due to a momentary voltage drop (a momentary power failure, so-called “momentary power failure”). It is determined whether or not it has been started (S1102). As will be described later with reference to FIG. 103, upon receiving the power-off command from main controller 110 (see S1214 in FIG. 103), sound lamp control device 113 executes the power-off process in S1217. The power-off processing flag is turned on before the power-off processing is performed, and the power-off processing flag is turned off after the power-off processing ends. Therefore, whether or not the power-off processing of S1217 is being performed can be determined based on the state of the power-off processing flag.

  If the power-off processing flag is off (S1102: No), the current startup processing is started after the power is completely cut off, or after a momentary power failure occurs, and the power-off processing in S1217 is performed. It is started after the execution of the process is completed, or started only by resetting the MPU 221 of the sound lamp control device 113 due to noise or the like (without receiving a power-off command from the main control device 110). is there. Therefore, in these cases, it is confirmed whether the data in the RAM 223 has been destroyed (S1103).

  Confirmation of data destruction of the RAM 223 is performed as follows. That is, data as a keyword of “55AAh” is written in a specific area of the RAM 223 by the process of S1106. Therefore, the data stored in the specific area is checked, and if the data is “55AAh”, the data is not destroyed in the RAM 223. Conversely, if the data is not “55AAh”, the data is destroyed in the RAM 223. If the data destruction of the RAM 223 is confirmed (S1103: Yes), the process proceeds to S1104 and the initialization of the RAM 223 is started. On the other hand, if data destruction of the RAM 223 is not confirmed (S1103: No), the process proceeds to S1108.

  If the current startup process is started after the power supply is completely shut off, the keyword “55AAh” is not stored in the specific area of the RAM 223 (the storage in the RAM 223 is lost due to the power cutoff). ), It is determined that the data in the RAM 223 has been destroyed (S1103: Yes), and the flow shifts to S1104. On the other hand, this startup process is started after an instantaneous power failure occurs and after the execution of the power-off process in S1217 is completed, or is reset only to the MPU 221 of the sound lamp control device 113 due to noise or the like. Is started, the keyword of "55AAh" is stored in the specific area of the RAM 223, so that the data of the RAM 223 is determined to be normal (S1103: No), and the process proceeds to S1108.

  If the power-off processing flag is on (S1102: Yes), this startup processing is performed after a momentary power failure occurs, and during the execution of the power-off processing in S1217, the audio lamp control device 113 Of the MPU 221 has been reset. In such a case, since the power-off process is being performed, the storage state of the RAM 223 is not always correct. Therefore, in such a case, the control cannot be continued, and the process shifts to S1104 to start initialization of the RAM 223.

  In the process of S1104, the storage area of the entire range of the RAM 223 is checked (S1104). As a checking method, first, "0FFh" is written for each byte, and it is read for each byte to check whether it is "0FFh". If "0FFh", it is determined that it is normal. Such writing and checking for each byte is performed in the order of “55h”, “0AAh”, and “00h” after “0FFh”. By this read / write check of the RAM 223, all storage areas of the RAM 223 are cleared to zero.

  If the read / write check is determined to be normal for all the storage areas of the RAM 223 (S1105: Yes), the keyword “55AAh” is written to the specific area of the RAM 223, and the RAM destruction check data is set (S1106). By confirming the keyword “55AAh” written in the specific area, it is checked whether or not data is destroyed in the RAM 223. On the other hand, if an abnormality of the read / write check is detected in any of the storage areas of the RAM 223 (S1105: No), the abnormality of the RAM 223 is notified (S1107), and an infinite loop is performed until the power is cut off. The abnormality of the RAM 223 is notified by the display lamp 34. Note that the sound output device 226 may output a sound to notify the abnormality of the RAM 223, or may transmit an error command to the display control device 114 to display an error message on the third symbol display device 81. It may be.

  In the process of S1108, it is determined whether or not the power-off flag is turned on (S1108). The power-off flag is turned on when the power-off process is performed in S1217 (see S1216 in FIG. 103). In other words, since the power-off flag is turned on before the power-off process in S1217 is executed, the process starting at S1108 with the power-off flag turned on is the instantaneous start-up process. This is a case where the process is started after the occurrence of the power failure and in a state where the execution of the power-off process in S1217 is completed. Therefore, in such a case (S1108: Yes), the work area of the RAM is cleared to initialize each process of the audio ramp control device 113 (S1109), and the initial value of the RAM 223 is set (S1110). The permission is set (S1111), and the process proceeds to the main processing. Note that the work area of the RAM 223 is an area other than an area for storing commands and the like received from the main control device 110.

  On the other hand, the reason why the process of step S1108 is reached with the power-off flag turned off is that the start-up process of this time is started after the power is completely cut off, for example, and the process of step S1108 is performed via the process from step S1104 to step S1106. This is the case where the processing has been reached or the MPU 221 of the sound lamp control device 113 has been reset only (without receiving a power-off command from the main control device 110) due to noise or the like and started. Therefore, in such a case (S1108: No), the process skips S1109, which is the process of clearing the work area of the RAM 223, shifts the process to S1110, sets the initial value of the RAM 223 (S1110), and sets the interrupt permission. Then (S1111), and shifts to the main processing.

  The reason why the clearing process of S1109 is skipped is that when the process from S1104 to the process of S1108 is performed via the process of S1106, all the storage areas of the RAM 223 have already been cleared by the process of S1104. When the MPU 221 of the sound lamp control device 113 is reset only due to noise or the like and the start-up process is started, the data in the work area of the RAM 223 is stored without being cleared, thereby saving the sound lamp control device 113. Can be continued.

  Next, a main process executed by the MPU 221 in the audio ramp control device 113 after the startup process of the audio ramp control device 113 will be described with reference to FIG. FIG. 103 is a flowchart showing this main processing. When the main processing is executed, first, it is determined whether or not 1 ms or more has elapsed since the main processing was started or since the previous processing of S1201 was executed (S1201). If not (S1201: No), the process proceeds to S1212 without performing the processes of S1202 to S1311. In the processing of S1201, it is determined whether or not 1 ms has elapsed. The processing in S1202 to S1311 is mainly for display (production), and it is not necessary to edit in a short cycle (within 1 msec). , S1212, and the variable display setting process of S1213 are preferably executed in a short cycle. By executing the processing of S1212 in a short cycle, it is possible to prevent omission of a command transmitted from the main control device 110, and by executing the processing of S1213 in a short cycle, a command received by the command determination processing can be prevented. Based on the above, it is possible to make settings relating to the fluctuation effect without delay.

  If 1 ms or more has elapsed in the process of S1201 (S1201: Yes), first, various commands for the display control device 114 set by the processes of S1203 to S1213 are transmitted to the display control device 114 (S1202). ). Next, the setting of the lighting mode of the display lamp 34 and the output of each lamp are set so as to be the lighting mode of the lamp edited in the process of S1208 described later (S1203), and thereafter, the power-on notification process is executed (S1204). The power-on notification processing is to perform notification for notifying that the power has been turned on for a predetermined time (for example, 30 seconds) when the power is turned on, and the notification is performed by the audio output device 226 or the lamp display device 227. Be done. Further, a command may be transmitted to the display control device 114 to notify that power has been supplied on the screen of the third symbol display device 81. If the power is not turned on, the process proceeds to S1205 without performing notification by the power-on notification process.

  In the process of S1205, a customer waiting effect process is executed, and thereafter, a held number display update process is executed (S1206). In the customer waiting effect process, when the pachinko machine 10 has not been played by the player for a predetermined period of time, a setting for switching the display of the third symbol display device 81 to the title screen is performed, and the setting is used as a command for display control. Sent to device 114. In the reserved number display update process, a process of lighting a reserved lamp (not shown) according to the value of the special symbol reserved ball number counter 223b is performed.

  Thereafter, the SW input monitoring and effect processing is executed (S1207). In this SW input monitoring / production process, the input of whether or not the frame button 22 or the selection switch 270 operated by the player has been pressed to enhance the production effect is monitored, and the input of the frame button 22 or the like is confirmed. This is a process for setting to perform an effect corresponding to the case. In this process, when an operation by the player such as the frame button 22 is detected, a SW-related command based on the switch operated on the display control device 114 is set. The details of the SW input monitoring and effect processing will be described later with reference to FIG.

  When the SW input monitoring / production process is completed, a lamp editing process is executed (S1208), and then a sound editing / output process is executed (S1209). In the lamp editing process, the lighting patterns of the illumination units 29 to 33 are set so as to correspond to the display performed by the third symbol display device 81. In the sound editing / output processing, the output pattern of the sound output device 226 is set so as to correspond to the display performed by the third symbol display device 81, and the sound is output from the sound output device 226 according to the setting.

  After the processing of S1209, a liquid crystal effect execution management processing is executed (S1210). In the liquid crystal effect execution management processing, a time synchronized with the time required for the fluctuation display performed by the third symbol display device 81 is set based on the fluctuation pattern command transmitted from the main controller 110. The lamp editing process of S1208 is executed based on the time set in the liquid crystal effect execution monitoring process. Note that the sound editing / output processing in S1209 is also executed at a time synchronized with the time required for the variable display performed by the third symbol display device 81.

  When the processing in S1210 ends, the effect counter 223i is updated (S1211). The effect counter updated here is used for selection of an effect when the frame button 22 is pressed in the super reach B described above. In the present control example, the effect counter 223i is updated in the main process. However, the present invention is not limited to this, and the update may be performed by providing an interrupt process.

  After the processing of S1211 is completed, a command determination processing for performing processing according to the command received from main controller 110 is executed (S1212). Details of this command determination processing will be described later with reference to FIG. Then, after the command determination processing, the variable display setting processing is executed (S1213). In the variation display setting process, a variation pattern command for display is generated and set based on the variation pattern command received from the main controller 110 in order to cause the third symbol display device 81 to execute the variation effect. As a result, the command is transmitted to the display control device 114. The details of the variable display setting process will be described later with reference to FIG.

  When the processing in S1213 is completed, it is determined whether or not the power-off occurrence information is stored in the work RAM 233 (S1214). The power-off information is stored when a power-off command is received from main controller 110. In the processing of S1214, when it is determined that the information of the occurrence of the power-off is stored (S1214: Yes), both the power-off flag and the power-off processing flag are turned on (S1216), and the power-off processing is executed. (S1217). After the execution of the power-off processing, the power-off processing-in-progress flag is turned off (S1218), and thereafter, the processing is in an infinite loop. In the power-off process, the occurrence of the interrupt process is prohibited, and each output port is turned off to turn off the output from the audio output device 226 and the lamp display device 227. Further, the storage of the information of the occurrence of the power interruption is also deleted.

  On the other hand, if power-off occurrence information is not stored in the process of S1214 (S1214: No), it is determined whether or not the RAM 223 is destroyed based on the keyword stored in the RAM 223 (S1215), and the RAM 223 is destroyed. If not (S1215: No), the process returns to S1201, and the main process is repeatedly executed. On the other hand, if the RAM 223 has been destroyed (S1215: Yes), the processing is executed in an infinite loop to stop the execution of the subsequent processing. Here, if it is determined that the RAM is destroyed and an infinite loop is performed, the main processing is not executed, and thereafter the display by the third symbol display device 81 does not change. Therefore, since the player can know that the abnormality has occurred, the player can call a store clerk of the hall or the like and request the pachinko machine 10 to be repaired. Further, when it is confirmed that the RAM 223 is destroyed, the sound output device 226 or the lamp display device 227 may be used to notify the RAM breakdown.

  Next, the command determination process (S1212) executed by the MPU 221 in the audio lamp control device 113 will be described with reference to FIG. FIG. 104 is a flowchart showing this command determination processing (S1212). This command determination process (S1212) is executed in the main process (see FIG. 103) executed by the MPU 221 in the audio lamp control device 113, and determines the command received from the main control device 110 as described above. .

  In the command determination process, first, among the unprocessed commands, the first command received from the main control device 110 is read from the command storage area provided in the RAM 223, analyzed, and the variation pattern command is received from the main control device 110. It is determined whether or not it has been performed (S1301). When a variation pattern command is received (S1301: Yes), the variation start flag 223c provided in the RAM 223 is turned on (S1302), and a variation pattern selection for extracting a variation pattern type from the received variation pattern command is performed. The process is executed (S1303), and the process returns to the main process. The variation pattern type extracted here is stored in the RAM 223, and is referred to when a later-described variation display setting process (see FIG. 105) is executed. It is used to set a display variation pattern command for notifying the display controller 114 of the start of the variation effect and the variation pattern type.

  On the other hand, if the fluctuation pattern command has not been received (S1301: No), it is then determined whether a stop type command has been received from the main control device 110 (S1304). If the stop type command is received (S1304: Yes), the stop type selection flag 223d of the RAM 223 is set to ON (S1305), and the stop type is extracted from the received stop type command (S1306). Return to processing. The stop type extracted here is stored in the RAM 223 and is referred to when a later-described variable display setting process (see FIG. 105) is executed. Then, it is used to set a display stop type command for notifying the display control device 114 of the stop type of the variable effect.

  On the other hand, if the stop type command has not been received (S1304: No), then it is determined whether or not a pending ball count command has been received from the main controller 110 (S1307). Then, when the reserved ball number command is received (S1307: Yes), the value included in the received reserved ball number command, that is, the value of the special symbol reserved ball number counter 203c of the main control device 110 (special symbol) Is extracted and stored in the special symbol reserved ball number counter 223b of the voice lamp control device 113 (S1308). In the process of S1308, a display reserved ball count command for notifying the display control device 114 of the updated value of the special symbol reserved ball count counter 223b is set. After the end of the process in S1308, the process returns to the main process.

  Here, the reserved ball number command is transmitted from the main control device 110 when the ball wins (starts winning) in the first winning opening 64 or when a special symbol is drawn, so that the starting winning is determined. Every time it is detected or every time a special symbol lottery is performed, the value of the special symbol retaining ball number counter 223b of the voice lamp control device 113 is changed by the processing of S1308 to the special symbol retaining ball number counter 203c of the main control device 110. Can be adjusted to the value of Therefore, even if the value of the special symbol reserved ball number counter 223b of the audio lamp control device 113 deviates from the value of the special symbol reserved ball number counter 203c of the main control device 110 due to the influence of noise, etc. At the time of symbol lottery, the value of the special symbol reserved ball number counter 223b of the audio lamp control device 113 can be corrected to match the value of the special symbol reserved ball number counter 203c of the main control device 110. When the process of S1408 is executed, a display reserved ball count command for notifying the display control device 114 of the updated value of the special symbol reserved ball count counter 223b is set. As a result, in the display control device 114, the number-of-reserved-balls symbol corresponding to the number of retained balls is displayed on the third symbol display device 81.

  In the processing of S1307, when the command of the number of reserved balls is not received (S1307: No), it is determined whether or not the winning command is received from the main control device 110 (S1309). When the opening command is received (S1309: Yes), winning information is extracted from the received command, stored in the winning information storage area 223a (S1310), and a display winning command based on the winning information is set. (S1311), and returns to the main processing. The display winning command set here is stored in the command transmission ring buffer provided in the RAM 223, and is displayed in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the control device 114. When the display control device 114 receives the display winning command, the third symbol display device 81 stores the winning information in the winning information storage area 233k.

  In the processing of S1309, if the command of the number of pending balls has not been received (S1309: No), then it is determined whether or not an opening command has been received from main controller 110 (S1312). Then, when the opening command is received (S1312: Yes), a display opening command for causing the third symbol display device 81 to execute an opening effect is set (S1313), and the process returns to the main processing. The display opening command set here is stored in the command transmission ring buffer provided in the RAM 223, and is displayed in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the control device 114. Upon receiving the display opening command, the display control device 114 starts an opening effect on the third symbol display device 81.

  On the other hand, if the opening command has not been received in the process of S1312 (S1312: No), then it is determined whether or not a round number command has been received from the main controller 110 (S1314). When the round number command is received (S1314: Yes), the number of rounds is extracted from the received round number command (S1315), and a display round number command corresponding to the extracted round number is set (S1315). S1316), and terminates the process. The display round number command set here is stored in a command transmission ring buffer provided in the RAM 223, and is included in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the display control device 114. When the display control device 114 receives the display round number command, the third symbol display device 81 starts a new round effect.

  On the other hand, in the processing of S1314, if the round number command has not been received (S1314: No), then it is determined whether or not an ending command has been received from main controller 110, and if the ending command has been received (S1317: Yes), an ending command for display is set (S1318), and this processing ends. The display ending command set here is stored in the command transmission ring buffer provided in the RAM 223, and is displayed in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the control device 114. When receiving the display ending command, the display control device 114 starts an ending effect in the third symbol display device 81.

  On the other hand, if the ending command has not been received in the process of S1317 (S1317: No), it is determined whether or not another command has been received, and the process corresponding to the received command is executed (S1319). ), And return to the main processing. For example, if the other command is a command used by the sound lamp control device 113, a process corresponding to the command is performed, the processing result is stored in the RAM 223, and if the command is a command used by the display control device 114, the command is displayed. The command is set to be transmitted to the device 114.

  By this processing, a command for performing various settings for the display control device 114 can be set based on the command output from the main control device 110.

  Next, the variable display setting process (S1213) executed by the MPU 221 in the audio lamp control device 113 will be described with reference to FIG. FIG. 105 is a flowchart showing the variable display setting process (S1213). This variable display setting process (S1213) is executed in the main process (see FIG. 103) executed by the MPU 221 in the audio lamp control device 113. In order to execute a variable effect on the third symbol display device 81, A display variation pattern command is generated and set based on the variation pattern command received from main controller 110.

  In the variation display setting process, first, it is determined whether or not a variation start flag 223c provided in the RAM 223 is turned on (S1401). If it is determined that the variation start flag 223c is not on (that is, it is off) (S1401: No), it means that the variation pattern command has not been received from the main control device 110, and the process proceeds to S1406. Transition. On the other hand, when it is determined that the change start flag 223c is on (S1401: Yes), the change start flag 223c is turned off (S1402), and then, in the process of S1303 of the command determination process (see FIG. 104), the change pattern is set. The variation pattern type in the variation effect extracted from the command is obtained from the RAM 223 (S1403).

  Then, a display variation pattern command for notifying the display control device 114 is generated based on the acquired variation pattern type, and the command is set to be transmitted to the display control device 114 (S1404). The display control device 114 receives the display variation pattern command, so that the third symbol display device 81 performs the variation display of the third symbol in the variation pattern indicated by the display variation pattern command. The display control of the variable effect is started.

  Next, a selected SW valid period is set based on the high-speed fluctuation period (S1405). Based on the selected SW valid period set here, in the SW input monitoring / producing process (see FIG. 106) to be described later, the super background operation process for performing the switch operation process at the time of the super background notice is executed. Become.

  After finishing the process of S1405, it is determined whether or not the variation pattern is a SW effect (S1406). In the process of S1406, when it is determined that the variation pattern is the SW effect (that is, super reach A or super reach B), the frame SW valid period 223f and the replacement timing 223g are set based on the variation pattern. , To S1408. On the other hand, if it is determined in the processing of S1406 that the fluctuation pattern is not the SW effect (that is, super reach A or super reach B), the process of S1407 is skipped, and the process proceeds to S1408.

  In the process of S1408, a process of sequentially shifting the data stored in the first to fourth areas of the winning information storage area 223a to the execution area side is performed (S1408). More specifically, the data in each area is shifted in the order of first area → execution area, second area → first area, third area → second area, fourth area → third area, and so on. After shifting the data, the flow shifts to the process of S1409.

  In the processing of S1409, it is determined whether or not the stop type selection flag 223d provided in the RAM 233 is ON (S1409). If it is determined that the stop type selection flag 223d is not on (that is, it is off) (S1409: No), the stop type command has not been received from the main control device 110, so that the variable display is performed. The setting process ends, and the process returns to the main process. On the other hand, when it is determined that the stop type selection flag 223d is on (S1409: Yes), the stop type selection flag 223d is turned off (S1410), and then, in the process of S1306 of the command determination process (see FIG. 104), The stop type in the fluctuation effect extracted from the stop type command is acquired from the RAM 223 (S1411).

  Next, a display stop type command for notifying the display control device 114 is generated based on the stop type specified by the stop type command from the main control device 110, and the command is transmitted to the display control device 114. (S1412), and the process ends. The display control device 114 receives the stop type command for display, so that the stop symbol corresponding to the stop type indicated by the stop type command for display is stopped and displayed on the third symbol display device 81. The stop display of the fluctuation effect is controlled.

  Here, the SW input monitoring and effect processing (S1207) executed by the MPU 221 in the audio lamp control device 113 will be described with reference to FIG. FIG. 105 is a flowchart showing the SW input monitoring and effect processing (S1207). This SW input monitoring and effect processing (S1207) is executed in the main process (see FIG. 103) executed by the MPU 221 in the audio lamp control device 113, and causes the effect based on the operation of the frame button 22 and the like. For this purpose, a display command based on the operated switch is generated and set.

  In the SW input monitoring / effect processing (S1207), first, it is determined whether or not the selected SW is valid (S1501). As described above, whether or not the selected SW is valid is set based on the high-speed fluctuation period in the processing of S1405 of the fluctuation display setting processing (see FIG. 105).

  In the processing of S1501, if it is determined that the selected SW is valid (S1501: Yes), the operation processing at the time of the super background, which is the operation processing when the super background notice is executed, is performed (S1502). To end.

  Here, the super-background operation process (S1502) will be described with reference to FIG. FIG. 105 is a flowchart showing the super background operation process (S1502). The super-background operation process (S1502) is executed in the SW input monitoring / producing process (see FIG. 106) executed by the MPU 221 in the audio lamp control device 113, and switches such as the selection switch 270 in the super-background notice This is a process of generating and setting a display command based on the operated switch in order to execute an effect based on the operation.

  In the super background operation process (S1502), first, it is determined whether or not the frame button 22 has been pressed (S1601). If it is determined in step S1601 that the frame button 22 has been pressed (S1601: Yes), a background image change command is set (S1602), and the process ends. By receiving the background image change command, the display control device 114 changes the background image (such as a super background notice image or a normal background image).

  On the other hand, if it is determined in step S1601 that the frame button 22 has not been pressed (S1601: No), it is determined whether or not the enter switch 270e has been pressed (S1603). If it is determined in step S1603 that the determination switch 270e has been pressed (S1603: Yes), a display determination SW pressing command is set (S1604), and the process ends. The display control device 114 changes the background image to the special background by receiving the display determination SW command while the specific image of the super background notice is being displayed.

  On the other hand, if it is determined in the processing of S1603 that the determination switch 270e has not been pressed (S1603: No), it is determined whether any of the selection switches 270a to 270d has been pressed (S1605). If it is determined in step S1605 that any of the selection switches 270a to 270d has been pressed (S1605: Yes), a display selection SW pressing command is set based on the pressed selection switch (270a to 270d). (S1606), this process ends. When the display control device 114 receives the display selection SW command during the display of the super background notice, the scroll direction of the super background notice is changed based on the operated selection switch.

  Returning to FIG. 106, the description will be continued. In the process of S1501, if it is determined that the current period is not the selected SW valid period (S1501: No), it is determined whether the current period is the frame SW valid period (S1503). In the process of S1503, if it is determined that the current time is not the frame SW validity period (S1503: No), a jackpot operation process, which is an operation process in a case where the jackpot effect is being executed, is performed (S1504), and the process ends. .

  Here, the jackpot operation process (S1504) will be described with reference to FIG. FIG. 108 is a flowchart showing the jackpot operation process (S1504). This jackpot operation process (S1504) is executed in the SW input monitoring and effect process (see FIG. 106) executed by the MPU 221 in the audio lamp control device 113, and the switch operation of the selection switch 270 and the like during the jackpot effect This is a process for generating and setting a display command based on an operated switch in order to execute an effect based on the switch.

  In the big hit operation process (S1504), first, it is determined whether or not the enter switch 270e is pressed (S1701). If it is determined in the processing of S1701 that the determination switch 270e has been pressed (S1701: Yes), a display determination SW pressing command is set (S1704), and this processing ends. When the display control device 114 receives this display determination SW pressing command at the time of selecting an event cell in the jackpot effect, the event cell is determined, and an effect corresponding to the cell is executed.

  On the other hand, if it is determined in the processing of S1701 that the determination switch 270e has not been pressed (S1701: No), it is determined whether any of the selection switches 270a to 270d has been pressed (S1703). If it is determined in the processing of S1703 that any of the selection switches 270a to 270d has been pressed (S1703: Yes), a display selection SW pressing command is set based on the pressed selection switch (270a to 270d). (S1704), this process ends. The display control device 114 receives the display selection SW command at the time of selecting the event mass in the big hit effect, and changes the selected event mass based on the operated selection switch.

  Returning to FIG. 106, the description will be continued. If it is determined in the process of S1503 that the current time is the frame SW valid period (S1503: Yes), the value of the frame SW valid period 223f is subtracted by 1 (S1505), and it is determined whether or not the super reach A is changing. (S1506). If it is determined in step S1506 that the super reach A is changing (S1506: Yes), it is determined whether the frame button 22 has been pressed (S1507).

  If it is determined in step S1507 that the frame button 22 has been pressed (S1508), a display valid pressing command is set (S1508), and the process ends. On the other hand, if it is determined in step S1507 that the frame button 22 has not been pressed (S1507: No), the process of step S1508 is skipped, and the process ends. When the display control device 114 receives the display effective press command set in the processing of S1508, the stop display (for example, FIG. 70 (b), FIG. 71 (a)) is performed in the effect of Super Reach A. .

  On the other hand, if it is determined in step S1506 that it is not Super Reach A (S1506: No), it is determined whether it is Super Reach B (S1509). If it is determined in step S1509 that the current mode is not Super Reach B (S1509: No), there is no process based on the switch operation, and thus the process ends.

  If it is determined in step S1509 that the game is Super Reach B (S1509: Yes), a super reach B operation process for executing a process based on a switch operation during the production of Super Reach B is executed ( S1510), this process ends.

  Here, the super reach B operation process (S1510) will be described with reference to FIG. FIG. 109 is a flowchart showing the super reach B operation process (S1510). The super reach B operation process (S1510) is executed in the SW input monitoring and effect process (see FIG. 106) executed by the MPU 221 in the audio lamp control device 113, and the operation of the frame button 22 in the super reach B This is a process of generating and setting a display command in order to execute an effect (for example, FIG. 77 (b)) based on.

  In the super reach B operation process (S1510), first, it is determined whether or not the frame SW valid period is greater than 0 (S1801). In the process of S1801, if it is determined that the frame SW valid period is greater than 0 (S1801: Yes), the process proceeds to S1803. On the other hand, if it is determined in the processing of S1801 that the frame SW validity period is not greater than 0 (that is, it is 0) (S1801: No), it is the timing to end the production of the super reach B, so the replacement is performed. The flag is turned off (S1802), and the process proceeds to S1803.

  In the processing of S1803 executed after the processing of S1801 or S1802, it is determined whether or not the frame button 22 has been pressed (S1803). In the processing of S1803, if it is determined that the frame button 22 has not been pressed (S1803: No), this processing ends.

  On the other hand, if it is determined in the processing of S1803 that the frame button 22 has been pressed (S1803: Yes), the value of the effect counter 223i is obtained (S1804), and the data of the winning information storage area 223a is obtained (S1805). The process moves to S1806.

  In the processing of S1806, it is determined whether or not the changing winning information is a big hit (S1806). In the processing of S1806, when it is determined that the winning information in the change is a big hit (S1806: Yes), then, it is determined whether or not the value of the effect counter 223i acquired in the processing of S1804 is 0 to 100. (S1807).

  In the process of S1807, when it is determined that the value of the effect counter 223i is 0 to 100, it is determined whether or not the remaining number of effective presses is 1 and the period is not the stop enabled period (S1808). In the process of S1808, if it is determined that the remaining number of effective presses is 1 and the period is not the stoppable period (S1808: Yes), a display valid press command is set (S1809), and the process proceeds to S1811. . On the other hand, when it is determined that the value of the effect counter 223i is not 0 to 100 (that is, 101 to 198) in the process of S1807, the remaining valid number of times is not 1 in the process of S1808, or the stoppage is possible. If it is determined (S1808: No), a fake display command for display is set (S1809), and the process moves to S1811.

  In the process of S1811 executed after the process of S1809 or S1810, the replacement timing is updated based on the number of remaining valid presses and the remaining frame SW valid period. Specifically, the super reach B is provided with a replacement timing. After the replacement timing, it is assumed that the number of remaining effective presses is large (that is, the number of presses of the frame button 22 is insufficient during the remaining frame SW valid period) despite the short remaining frame SW valid period. It is determined, and the effect indicating the jackpot is replaced in advance. As described above, by setting the replacement timing based on the remaining frame SW valid period and the number of remaining valid presses, it is possible to set an effect indicating a jackpot in advance, and to perform processing when the remaining frame SW valid period has elapsed. The load can be reduced.

  When the processing in S1811 is completed, it is determined whether or not the replacement flag 223h is off (S1812). In the process of S1812, when it is determined that the replacement flag 223h is not off (S1812: No), the display replacement command for replacing the effect indicating the jackpot has already been set, and thus the present process is performed as it is. To end.

  On the other hand, in the process of S1812, when it is determined that the replacement flag 223h is off (S1812: Yes), it is determined whether the replacement timing has elapsed (S1813). In the process of S1813, when it is determined that the replacement timing has not passed (S1813: No), the process is terminated because there is no need to perform replacement yet. In the process of S1813, if it is determined that the replacement timing has elapsed (S1813: Yes), a display replacement command for replacing an effect indicating a jackpot is set (S1814), and the replacement flag 223h is set. It is set to ON (S1815), and this processing ends.

  On the other hand, in the processing of S1806, when it is determined that the winning information that is changing is not a big hit (S1806: No), it is then determined whether or not the effect counter 223i is 0 to 50 (S1816). In the processing of S1816, when it is determined that the effect counter 223i is 0 to 50 (S1816: Yes), a display effective pressing command is set (S1817), and this processing ends. In the processing of S1816, when it is determined that the effect counter 223i is not 0 to 50 (that is, 51 to 198) (S1816: No), a false display press command for display is set (S1818), and this processing ends. I do.

<Control processing of display control device in first control example>
Next, each control executed by the MPU 231 of the display control device 114 will be described with reference to FIGS. The processing of the MPU 231 is roughly classified into a main processing that is repeatedly executed after the power is turned on, a command interruption processing that is executed when a command is received from the sound lamp control device 113, and a one-frame processing performed by the image controller 237. There is a V interrupt process that is executed when the MPU 231 detects a V interrupt signal transmitted every 20 milliseconds when the image rendering process is completed. The MPU 231 normally executes a main process, and executes a command interrupt process or a V interrupt process in accordance with reception of a command or detection of a V interrupt signal. If the command reception and the V interrupt signal detection are performed simultaneously, the command reception processing is executed with priority. As a result, it is possible to quickly reflect the content of the command received from the audio lamp control device 113 and execute the V interrupt processing.

  First, the main processing executed by the MPU 231 in the display control device 114 will be described with reference to FIG. FIG. 110 is a flowchart showing this main processing. The main process executes an initialization process when the power is turned on.

  The activation of the main processing is specifically performed according to the following flow. When the power is supplied to the display control device 114 from the power supply circuit 115 and the system reset is released, the MPU 231 sets the instruction pointer 231a provided in the MPU 231 to “0000H” by the hardware configuration, and , An address “0000H” indicated by the instruction pointer 231a is specified for the bus line 240. When the ROM controller 234b of the character ROM 234 detects that the address designated to the bus line 240 is “0000H”, the ROM controller 234b sets the boot program stored in the first program storage area 234d1 of the NOR ROM 234d in the buffer RAM 234c. And outputs the corresponding data (instruction code) to the MPU 231. Then, the MPU 231 starts the main processing by fetching the instruction code received from the character ROM 234 and starting execution of processing corresponding to the fetched instruction.

  Here, if all boot programs to be processed first by the MPU 231 after the system reset is released are stored in the NAND flash memory 234a, the character ROM 234 indicates that the address specified for the bus line 240 is "0000H". Upon detection, one page of data including data (instruction code) corresponding to the address "0000H" must be read from the NAND flash memory 234a and set in the buffer RAM 234c. Because of the nature of the NAND flash memory 234a, a great deal of time is required from the reading to the setting in the buffer RAM 234c. Therefore, the MPU 231 specifies the address “0000H” and then receives the instruction code corresponding to the address “0000H” Will consume a lot of waiting time. Therefore, since the time required to start the MPU 231 becomes longer, there is a problem that the control of the third symbol display device 81 in the display control device 114 may not be started immediately.

  On the other hand, as in the present control example, a predetermined number of instructions from the first to be processed by the MPU 231 after the system reset is released from the boot program are stored in the NOR ROM 234d, so that the NOR ROM can operate at high speed. Since the memory is a memory from which data can be read, when the address “0000H” is designated from the MPU 231 via the bus line 240 after the system reset is released, the character ROM 234 is immediately stored in the first program storage area 234d1 of the NOR type ROM 234d. The stored boot program can be set in the buffer RAM 234c, and the corresponding data (instruction code) can be output to the MPU 231. Therefore, since the MPU 231 can receive the instruction code corresponding to the address “0000H” in a short time after specifying the address “0000H”, the MPU 231 can start the main processing in a short time. Therefore, even if the control program is stored in the character ROM 234 composed of the NAND flash memory 234a having a low reading speed, the control of the third symbol display device 81 in the display control device 114 can be started immediately.

  When the main process is executed as described above, first, a boot process executed by a boot program is executed (S1901), and the display control device 114 is set to execute various controls on the third symbol display device 81. Start

  Here, the boot process (S1901) will be described with reference to FIG. FIG. 111 is a flowchart illustrating the boot process (S1901) executed in the main process in the MPU 231 of the display control device 114.

  As described above, in the present control example, the control program and the fixed value data executed by the MPU 231 are not stored in a dedicated program ROM provided in the conventional game machine but stored in the third symbol display device 81. The image data to be displayed is stored in a character ROM 234 provided for storing the data. Since the character ROM 234 is constituted by the NAND flash memory 234a having a small area and a large capacity, not only image data but also a control program and the like can be sufficiently stored. There is no need to provide a dedicated program ROM for storing programs and the like. Therefore, the number of components in the display control device 114 can be reduced, the manufacturing cost can be reduced, and an increase in the failure rate due to an increase in the number of components can be suppressed.

  On the other hand, since the reading speed of the NAND flash memory is particularly low when performing random access, the MPU 231 directly reads and processes the control program and fixed value data stored in the NAND flash memory 234a. Even if a high-performance processor is used, the processing performance of the display control device 114 may be degraded. Therefore, in this boot processing, the control program and the fixed value data stored in the second program storage area 234a1 of the NAND flash memory 234a are stored in the program storage area 233a and the data table provided in the work RAM 233 constituted by the DRAM. The process of transferring and storing the data to the storage area 233b is executed.

  Specifically, first, based on the hardware operation of the MPU 231 and the character ROM 234 described above, after the system reset is released, the second program is read out from the first program storage area 234d1 of the NOR ROM 234d and set in the buffer RAM 234c according to the boot program. Of the control programs stored in the two program storage area 234a1, a predetermined amount is transferred to the program storage area 233a (S2001). The predetermined amount of control program transferred here includes the remaining boot programs not stored in the first program storage area 234d1.

  Then, the instruction pointer 231a is set to the first predetermined address of the program storage area 233a, that is, the start address of the remaining boot program stored in the program storage area 233a (S2002). As a result, the MPU 231 starts executing the remaining boot program included in the control program transferred and stored in the program storage area 233a by the process of S2001.

  Also, by setting the instruction pointer 231a to a predetermined address of the program storage area 233a by the processing of S2002, the MPU 231 executes various processing while reading out the control program stored in the program storage area 233a of the work RAM 233. become. That is, the MPU 231 does not read out the control program from the NAND flash memory 234a having the second program storage area 234a1 and fetch the instruction, but reads out the control program transferred to the work RAM 233 having the program storage area 233a and fetches the instruction. Then, various processes are executed. As described above, since the work RAM 233 is configured by a DRAM, a high-speed read operation is performed. Therefore, even when the control program is stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, the MPU 231 can fetch an instruction at high speed and execute a process for the instruction.

  When the instruction pointer 231a is set by the processing of S2002, the instruction pointer 231a is subsequently stored in the second program storage area 234a1 of the NAND flash memory 234a according to the remaining boot program started to be executed by the set instruction pointer 231a. The remaining control programs and fixed value data of the control programs which have not been transferred to the program storage area 233a are transferred to the program storage area 233a or the data table storage area 233b by a predetermined amount (S2003). Specifically, the control program and some fixed data are stored in the program storage area 233a of the work RAM 233, and the various data tables (display data table, transfer data table) among the fixed value data are stored in the data table. The data is transferred to the storage area 233b.

  Then, after executing other processes necessary for the boot process (S2004), the instruction pointer 231a is executed at the second predetermined address of the program storage area 233a, that is, after the end of the boot process (see S1901 in FIG. 110). By setting the start address of the program corresponding to the power-up initialization process (see S1902 in FIG. 110) (S1905), the execution of the boot program is completed, and the boot process is completed.

  By executing the boot process (see S1901 in FIG. 110) in this manner, the control program and fixed value data stored in the second program storage area 234a1 of the NAND flash memory 234a are all configured by the DRAM. The data is transferred to and stored in the program storage area 233a and the data table storage area 233b of the work RAM 233. Then, at the end of the boot process, the instruction pointer 231a is set to the above-mentioned second predetermined address, and thereafter, the MPU 231 reads the control program transferred to the program storage area 233a without referring to the NAND flash memory 234a. And execute various processes.

  Therefore, even when the control program is stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, the control program and the fixed value data are stored in the program storage area 233a of the work RAM 233 after the system reset is released. By transferring the data to the data table storage area 233b, the MPU 231 can read out a control program and fixed value data from a work RAM constituted by a DRAM having a high readout speed and perform various controls. High processing performance can be maintained, and diversified and complicated effects can be easily executed using the auxiliary effect unit.

  On the other hand, the entire boot program is not stored in the NOR ROM 234d, but a predetermined number of instructions from the first to be processed by the MPU 231 after the system reset is released are stored. The remaining boot programs are stored in the NAND flash memory 234a. Even if the control program is stored in the second program storage area 234a1, the control program stored in the second program storage area 234a1 can be reliably transferred to the program storage area 233a. Therefore, the character ROM 234 can start the MPU 231 in a short time only by adding the NOR-type ROM 234d having a very small capacity. Can be.

  In the boot process shown in FIG. 111, the predetermined amount of control program transferred to the program storage area 233a by the process of S2001 includes all the remaining boot programs not stored in the first program storage area 234d1. Although not limited to this, the predetermined amount of control program transferred to the program storage area 233a by the process of S2001 is a boot program that executes a boot process to be processed following the process of S2002. May be part of The boot program transferred here transfers the control program including all the remaining boot programs by a predetermined amount to the program storage area 233a, and furthermore, the start address of the boot program stored in the program storage area 233a is designated by the instruction pointer. 231a may be executed. Then, the processes of S2003 to S2005 may be executed by all remaining boot programs stored in the program storage area 233a.

  The boot program transferred by the process of S2001 transfers a part of the remaining boot program to the program storage area 233a by a predetermined amount, and subsequently, the start of the boot program stored in the program storage area 233a. Processing for setting an address in the instruction pointer 231a may be executed. The part of the boot program stored in the program storage area 233a by this process further transfers a part of the remaining boot program to the program storage area 233a by a predetermined amount. The processing for setting the start address of the stored boot program in the instruction pointer 231a may be executed. Then, a part of the remaining boot program is transferred to the program storage area 233a by a predetermined amount, and subsequently, the process of setting the start address of the boot program stored in the program storage area 233a in the instruction pointer 231a is performed in S1901. After repeating the processing a plurality of times including the processing of S1902, the processing of S2003 to S2005 may be executed.

  Accordingly, even if the program size of the boot program is large and the remaining boot programs not stored in the first program storage area 234d1 cannot be transferred to the program storage area 233a at one time, the MPU 231 is already stored in the program storage area 233a. By using the boot program, the data can be transferred to the program storage area 233a by a predetermined amount.

  Further, in the present control example, a case has been described in which a part of the boot program executed by the MPU 231 at the time of system reset release is first stored in the first program storage area 234d1, but all the boot programs are stored in the first program storage area 234d1. It may be stored in one program storage area 234d1. In this case, when starting the boot process, the MPU 231 may execute the processes of S2003 to S2005 without performing the processes of S2001 and S2002. As a result, the process of transferring the boot program to the program storage area 233a becomes unnecessary, and the number of times of transferring the program to the character ROM 234 or the program storage area 233a is reduced, so that the processing time of the boot process can be reduced. Therefore, the control of the auxiliary effect section in the MPU 231 which can be performed after the boot process can be started more quickly.

  Here, the description returns to FIG. When the boot process is completed, an initialization process is executed in accordance with the control program transferred to and stored in the program storage area 233a of the work RAM 233 (S1902). Specifically, the value of the stack pointer is set in the MPU 231, and various settings for the register group in the MPU 231 and the I / O device are performed. Further, processing for clearing the storage of the work RAM 233, the resident video RAM 235, and the normal video RAM 236 is performed. Further, various flags are provided in the work RAM 233, and an initial value is set for each flag. Note that “off” or “0” is set as an initial value of each flag, unless otherwise specified.

  Further, in the initial setting process, after performing the initial setting of the image controller 237, the image controller 237 draws an image so that an image of a specific color is displayed on the entire screen on the third symbol display device 81. And execution of display processing. Thus, immediately after the power is turned on, first, an image of a specific color is displayed on the entire screen of the third symbol display device 81. Here, the color of the image displayed on the entire screen of the third symbol display device 81 immediately after the power is turned on is set to be different depending on the model of the pachinko machine. Thus, in an operation check at a factory or the like at the time of manufacturing, the pachinko machine 10 can check whether or not an image of a color corresponding to the model is displayed on the third symbol display device 81 immediately after the power is turned on. It is possible to easily and immediately determine whether or not the activation can be started normally.

  Next, a transfer instruction is transmitted to the image controller 237 to transfer the image data corresponding to the power-on main image to the power-on main image area 235a of the resident video RAM 235 (S1903). The transfer instruction includes the start address and the end address of the character ROM 234 storing the image data corresponding to the main image at power-on, the information of the transfer destination (here, the resident video RAM 235), and the transfer destination. The image data corresponding to the power-on main image is transferred from the character ROM 234 to the resident video RAM 235 by the image controller 237 in accordance with the transfer instruction. The image is transferred to the image area 235a.

  Then, when all the transfer of the image data indicated by the transfer instruction is completed, the image controller 237 transmits a transfer end signal indicating the transfer end to the MPU 231. By receiving this transfer end signal, the MPU 231 can grasp that the transfer of the image data specified by the transfer instruction has been completed. When the image controller 237 completes the transfer of the image data indicated by the transfer instruction, the image controller 237 stores the transfer end information indicating the transfer end in a register provided inside the image controller 237 or a partial area of the built-in memory. You may write it. Then, the MPU 231 reads out the information of the register or a partial area of the built-in memory at any time, detects the writing of the transfer end information by the image controller 237, and thereby grasps that the transfer of the image data specified by the transfer instruction has been completed. You may do so.

  The image data transferred to the main image area 235a when the power is turned on is held so as not to be overwritten until the power is turned off. When the transfer of the image data corresponding to the power-on main image to the power-on main image area 235a is completed based on the transfer instruction transmitted to the image controller 237 in the processing of S1903, the power-on fluctuation image Is transmitted to the image controller so that the image data corresponding to the image data is transferred to the power-on fluctuation image area 235b of the resident video RAM 235 (S1904). The transfer instruction includes the start address of the character ROM 234 storing the image data corresponding to the power-on fluctuation image, the data size of the image data, the transfer destination information (here, the resident video RAM 235). And the start address of the power-on fluctuation image area 235b, which is the transfer destination. The image controller responds to the transfer instruction and transfers the image data corresponding to the power-on fluctuation image from the character ROM 234 to the resident video RAM 235. The data is transferred to the power-on fluctuation image area 235b. The image data transferred to the power-on fluctuation image area 235b is held so as not to be overwritten until the power is turned off.

  When the transfer of the image data corresponding to the power-on fluctuation image to the power-on fluctuation image area 235b is completed based on the transmission instruction transmitted to the image controller 237 in the processing of S1904, the simple image display flag 233c Is turned on (SS1905). As a result, while the simple image display flag 233c is on, all image data to be resident in the resident video RAM 235 is transferred from the character ROM 234 to the resident video RAM 235 in a transfer setting process (see FIG. 130A) described later. A resident image transfer setting process for instructing the image controller 237 to perform the transfer is executed (see S4302 in FIG. 130A).

  Also, the simple image display flag 233c indicates that all image data to be resident in the resident video RAM 235 is transferred from the character ROM 234 to the resident video RAM 235 based on the transfer instruction to the image controller 237 by this resident image transfer setting process. It is kept on until it ends. Thereby, in the meantime, in the V interrupt processing (see FIG. 112B), the simple command determination processing (FIG. 112B) is performed so that the power-on image (power-on main image or power-on fluctuation image) is drawn. 112 (b) of S2208) and simple display setting processing (see S2209 of FIG. 112 (b)).

  As described above, since the pachinko machine 10 uses the NAND flash memory 234a as the character ROM 234, all the image data to be stored in the resident video RAM 235 is It takes a lot of time to transfer from the character ROM 234 to the resident video RAM 235. Therefore, as in the main process, after the power is turned on, first, the power-on main image and the power-on fluctuation image are transferred from the character ROM 234 to the resident video RAM 235, and the power-on main image is stored in the third video. By displaying on the symbol display device 81, while the remaining image data to be resident is transferred to the resident video RAM 235, the player or the person in charge of the hall operates at the time of turning on the power displayed on the third symbol display device 81. You can check the main image. Therefore, the display control device 114 transfers the remaining image data to be resident from the character ROM 234 to the resident video RAM 235 over time while displaying the main image at power-on on the third symbol display device 114. be able to. On the other hand, since the player or the like can recognize that some initialization processing is being performed while the main image is displayed on the third symbol display device 81 at the time of power-on, the player is resident in the remaining resident video RAM 235. Until the image data to be transferred from the character ROM 234 to the resident video RAM 235, it is possible to wait until the initialization is completed without worrying that the operation has not stopped.

  Also, in an operation check at a factory or the like at the time of manufacturing, the main image at power-on is immediately displayed on the third symbol display device 81, so that the operation of the third symbol display device 81 is started without any problem by turning on the power. Can be immediately confirmed, and the use of the NAND flash memory 234a having a low reading speed as the character ROM 234 can prevent the efficiency of the operation check from deteriorating.

  In the display control device 114 of the pachinko machine 10, since the power-on fluctuation image is transferred from the character ROM 234 to the resident video RAM 235 together with the power-on main image after the power is turned on, the power-on main image is displayed in the third symbol. When the player starts the game while being displayed on the display device 81, there is a ball (start winning) in the first winning opening 64 or the second winning opening 640, and the start instruction of the variable effect is issued by the main control device. In the case where the command is received from the voice lamp controller 113 via the sound lamp control device 113, that is, when the display variation pattern command is received, the power-on variation image is immediately displayed during the variation effect period, and a simple variation effect is performed. be able to. Therefore, even when the main image is displayed on the third symbol display device 81 when the power is turned on, the player can surely confirm that the lottery has been performed by the simple variable effect.

  As described above, while the remaining image data to be resident is being transferred from the character ROM 234 to the resident video RAM 235, the main image is displayed on the third symbol display device 81 when the power is turned on. Is constituted by the NAND flash memory 234a having a low readout speed, so that it takes time to transfer the data, so that after power-on, the time during which the main image is displayed at power-on also becomes longer. However, in the pachinko machine 10, a simple fluctuation effect can be performed using the power-on fluctuation image transferred to the resident video RAM 235 after the power is turned on. Immediately after, for example, while the main image is being displayed at the time of power-on, the player can play the game with peace of mind.

  After the processing of S1905, interruption permission is set (S1906), and thereafter, the main processing executes an infinite loop processing until the power is turned off. Thus, after the interruption permission is set by the processing of S1906, the command interruption processing and the V interruption processing are executed in accordance with the reception of the command and the detection of the V interruption signal.

  Next, a command interruption process executed by the MPU 231 of the display control device 114 will be described with reference to FIG. FIG. 112A is a flowchart showing the command interruption processing. As described above, when a command is received from the audio lamp control device 113, the MPU 231 executes a command interruption process.

  In this command interruption processing, the received command data is extracted, the extracted command data is sequentially stored in a command buffer area provided in the work RAM 233 (S2101), and the process is terminated. Various commands stored in the command buffer area by the command interrupt processing are read out by a command determination processing or a simple command determination processing of a V interrupt processing described later, and processing according to the command is performed.

  Next, with reference to FIG. 112 (b), the V interrupt processing executed by the MPU 231 of the display control device 114 will be described. FIG. 112B is a flowchart showing the V interrupt processing. In this V interrupt processing, various processing corresponding to the command stored in the command buffer area by the command interrupt processing is executed, and an image to be displayed on the third symbol display device 81 is specified, and then the drawing of the image is performed. By creating a list (see FIG. 91) and transmitting the drawing list to the image controller 237, the image controller 237 is instructed to execute drawing processing and display processing of the image.

  As described above, the execution of the V interrupt processing is started when a V interrupt signal from the image controller 237 is detected. This V interrupt signal is a signal that is generated every 20 milliseconds in the image controller 237 when the drawing processing of the image for one frame is completed, and is transmitted to the MPU 231. Therefore, by executing the V interrupt processing in synchronization with the V interrupt signal, a drawing instruction is issued to the image controller 237 every 20 milliseconds when the drawing processing of the image for one frame is completed. become. Therefore, the image controller 237 does not receive a drawing instruction of the next image at a stage where the image drawing processing or the display processing is not completed, so that the image controller 237 starts drawing a new image during drawing of the image, It is possible to prevent an image from being developed in a frame buffer in which image information being displayed is stored in accordance with a new drawing instruction.

  Here, first, an outline of the flow of the V interrupt processing will be described, and then details of each processing will be described with reference to other drawings. In this V interrupt processing, as shown in FIG. 112 (b), first, it is determined whether or not the simple image display flag 233c is on (S2201), and the simple image display flag 233c is not on, that is, If it is off (S2201: No), it means that the transfer of all image data to be resident in the resident video RAM 235 has been completed. A command determination process (S2202) is performed to cause the display device 81 to display, and then a display setting process (S2203) is performed.

  In the command determination process (S2202), the contents of the command from the audio ramp control device 113 stored in the command buffer area by the command interruption process are analyzed, and the process corresponding to the command is executed. When the display variation pattern command is stored, the demo display data table or the variation display data table corresponding to the variation pattern type is set in the display data table buffer 233d, and the transfer data corresponding to the set display data table is set. The table is set in the transfer data table buffer 233e.

  In this command determination processing, all commands stored in the command buffer area at that time are analyzed and the processing is executed. This is because the command determination processing is performed at intervals of 20 milliseconds during which the V interrupt processing is executed, and thus there is a high possibility that a plurality of commands are stored in the command buffer area during the 20 milliseconds. is there. In particular, when the start of the fluctuation effect is determined in the main control device 110, there is a high possibility that the display fluctuation pattern command, the display stop type command, and the like are simultaneously stored in the command buffer area. Therefore, by analyzing and executing these commands at once, the mode of the variable effect and the type of stop selected by the main control device 110 and the sound lamp control device 113 are quickly grasped, and the effect image according to the mode is obtained. The drawing of the image can be controlled so as to be displayed on the third symbol display device 81. The details of the command determination processing will be described later with reference to FIGS.

  In the display setting process (S2203), an image for one frame to be displayed next in the third symbol display device 81 based on the contents of the display data table set in the display data table buffer 233d by the command determination process (S2202) and the like. Specify the contents of In addition, an effect mode to be displayed on the third symbol display device 81 is determined in accordance with a processing situation or the like, and a display data table corresponding to the determined effect mode is set in the display data table buffer 233d. The details of the display setting process will be described later with reference to FIGS. 127 to 129.

  After the display setting process is executed, a task process is executed (S2204). In this task process, the image is formed based on the contents of the image for the next one frame to be displayed on the third symbol display device 81 specified by the display setting process (S2203) or the simple display setting process (S2209). The type of sprite (display object) to be specified is specified, and various parameters required for drawing, such as a display coordinate position, an enlargement ratio, and a rotation angle, are determined for each sprite.

  Next, a transfer setting process is executed (S2205). In this transfer setting process, while the simple image display flag 233c is ON, the image controller 237 transfers the image data to be resident in the resident video RAM 235 from the character ROM 234 to a predetermined area of the resident video RAM 235. Set instructions. While the simple image display flag 233c is off, predetermined image data is sent from the character ROM 234 to the image controller 237 based on the transfer data information of the transfer data table set in the transfer data table buffer 233e. In addition to setting a transfer instruction to transfer to a predetermined sub area of the image storage area 236 a of the video RAM 236, the image controller 237 also receives a continuous notice command or a rear image change command from the sound lamp control device 113. A transfer instruction is set to transfer the image data of the continuous preview image used in the preview effect and the image data of the rear image after the change from the character ROM 234 to a predetermined sub area of the image storage area 236a of the normal video RAM 236. The details of the transfer setting process will be described later with reference to FIGS. 130 and 131.

  Next, a drawing process is executed (S2206). In this drawing processing, the type of various sprites constituting one frame determined in the task processing (S2204), the parameters necessary for drawing each sprite, and the transfer instruction set in the transfer setting processing (S2205) are used. The drawing list shown in FIG. 91 is generated, and the drawing list is transmitted to the image controller 237 together with the drawing target buffer information. Thus, the image controller 237 executes the image drawing processing according to the drawing list. The details of the drawing process will be described later with reference to FIG.

  Next, a counter update process (S2207) is executed. The details of the counter updating process will be described later with reference to FIG. Then, the V interrupt processing ends. As a counter updated by the process of S2207, for example, there is a stop symbol counter (not shown) for determining a stop symbol. The value of the stopped symbol counter is stored in the work RAM 233, and is updated each time the V interrupt processing is executed. Then, in the command determination processing, when the reception of the display stop type command is detected, the stop type indicated by the display stop type command (big hit A, big hit B, reach out of front / rear, reach other than front / back out, reach out) is displayed. The corresponding stop type table and the stop type counter are compared, and the stop symbol after the variable effect displayed on the third symbol display device 81 is finally set.

  On the other hand, if it is determined in the process of S2201 that the simple image display flag 233c is ON (S2201: Yes), it means that transfer of all image data to be resident in the resident video RAM 235 has not been completed. Therefore, in order to display the power-on image on the third symbol display device 81, the simple command determination process (S2208) is executed, then the simple display setting process (S2209) is executed, and the process proceeds to S2204.

  Next, details of the above-described command determination processing (S2202), which is one processing of the V interrupt processing executed by the MPU 231 of the display control device 114, will be described with reference to FIGS. First, FIG. 113 is a flowchart showing this command determination processing.

  In this command determination process, as shown in FIG. 113, first, it is determined whether there is an unprocessed new command in the command buffer area (S2301). If there is no unprocessed new command (S2301: No), The command determination process ends, and the process returns to the V interrupt process. On the other hand, if there is an unprocessed new command (S2301: Yes), a new command flag for notifying the display setting process (S2203) that the new command has been processed in the ON state is set to ON (S2302). For all unprocessed commands stored in the buffer area, the types of the commands are analyzed (S2303).

  First, it is determined whether or not there is a display variation pattern command among the unprocessed commands (S2304). If there is a display variation pattern command (S2304: Yes), the variation pattern command processing is executed. (S2305), and returns to the process of S2301.

  Here, the details of the variation pattern command processing (S2305) will be described with reference to FIG. FIG. 114A is a flowchart showing the variation pattern command processing. This variation pattern command processing executes processing corresponding to the display variation pattern command received from the audio lamp control device 114.

  In the variation pattern command processing, first, the data in the game state storage area is updated based on the received command (S2401). Next, the received variation pattern is stored in the variation history storage area (S2402), a variation display data table corresponding to the variation effect pattern indicated by the display variation pattern command is determined, and the determined variation display data table is stored in the data. The data is read from the fluctuating effect table storage area of the table storage area 233b (see FIG. 17) and set in the display data table buffer 233d (S2403).

  Here, since the determination of the start of the fluctuation in the main controller 110 is always made at least several seconds apart, no more than two display fluctuation pattern commands are received within 20 milliseconds. When executing, it is impossible that two or more display variation pattern commands are stored in the command buffer area. However, part of the command changes due to the influence of noise or the like, and another command is incorrectly displayed. It may be interpreted as a fluctuation pattern command. In the process of S2403, when it is determined that two or more display variation pattern commands are stored in the command buffer area in preparation for such a case, the variation display data table corresponding to the variation pattern with the shortest variation time. Is set in the display data table buffer 233d.

  If a fluctuation display data table corresponding to a fluctuation pattern having a long fluctuation time is set in the display data table buffer 233d, a fluctuation effect having a fluctuation time shorter than the set display data table actually occurs in the main control device. When instructed by 110, the next display variation pattern command is received from main controller 110 while the variation effect according to the set variation display data table is being displayed on third symbol display device 81. As a result, another variable display is suddenly started, and there is a possibility that the player may feel uncomfortable.

  On the other hand, by setting the fluctuation display data table corresponding to the fluctuation pattern with the shortest fluctuation time in the display data table buffer 233d as in the present control example, the fluctuation data longer than the set display data table is actually set. Even when the fluctuation effect having a time is instructed by the main controller 110, as described later, after the fluctuation effect according to the display data table buffer 233d is completed, the main controller 110 returns to the next display. Until the pattern command is received, the display of the third symbol display device 81 is controlled by the display setting process so that the demonstration effect is displayed. You can keep watching the fluctuations of the three symbols.

  Next, a transfer data table corresponding to the display data table set in S2403 is determined, read from the data table storage area 233b, and set in the transfer data table buffer 233e (S2404). Then, among the data table determination flags provided for each variation display data table corresponding to each variation pattern, the data table determination flag corresponding to the variation display data table set in the process of S2403 is turned on, and other variation table data is set. The data table determination flag corresponding to the display data table is set to off (S2405). In the display setting process, by referring to the data table determination flag set in the process of S2405, it is easy to determine which variation pattern the variation display data table set in the display data table buffer 233d corresponds to. You can judge.

  Next, based on the fluctuation time of the fluctuation pattern corresponding to the fluctuation display data table set in the display data table buffer 233d by the processing of S2403, time data representing the fluctuation time is set in the time counter 233h (S2406), and the pointer is set. 233f is initialized to 0 (S2407). Then, both the demonstration display flag and the confirmed display flag are set to OFF (S2408), the super background effect processing is executed (S2409), and the process returns to the command determination processing.

  By executing the variation pattern command processing, in the display setting processing, while updating the pointer 233f initialized by the processing of S2407, the display data table buffer 233d set in the display data table buffer 233d by the processing of S2403 is updated. , Extract the drawing content specified at the address indicated by the pointer 233f, specify the content of the image for one frame to be displayed next in the third symbol display device 81, and at the same time, execute the transfer data table buffer 233e by the process of S2404. The transfer data information specified at the address indicated by the pointer 233f is extracted from the transfer data table set in the variable ROM display data table, and the sprite image data required in the set variable display data table is previously stored in the character ROM 234 from the normal video R. To be transferred to the image storage area 236a of M236, to control the image controller 237.

  In the display setting process, the time of the variation effect specified in the variation display data table is measured using the time counter 233h in which the time data is set by the process of S2406, and when the variation effect in the variation display data table ends. When it is determined, the setting of the stop display is controlled so that the stop symbol corresponding to the display stop type command from the main control device 110 is displayed on the third symbol display device 81.

  Here, the super-background effect process (S2409) will be described with reference to FIG. FIG. 115 is a flowchart showing the super background effect processing (S2409). In the super-background effect process (S2409), when the background in the door in the super-background notice is displayed, whether to end the background in the door according to the number of times of the variable display performed during the display of the background in the door. This is a process for determining whether to continue.

  In the super-background effect processing, first, it is determined whether or not the in-door variation counter 233y is greater than 0 (S2601). In the process of S2601, if it is determined that the in-door change number counter 233y is 0 (S2601: No), the process is terminated as it is because the in-door background is not being displayed.

  On the other hand, in the process of S2601, when it is determined that the in-door variation number counter 233y is greater than 0 (S2601: Yes), the in-door variation number counter 233y is decremented by 1 (S2602), and the in-door variation number counter 223y is determined. It is determined whether the value is 0 (S2603).

  In the process of S2603, if it is determined that the in-door variation number counter 223y is not 0 (S2603: No), this process ends because it is not the end timing of the in-door background. On the other hand, in the process of S2603, when it is determined that the in-door change frequency counter 223y is 0 (S2603: Yes), the data of the winning information storage area 233k is obtained (S2604), and the value of the display effect counter 233o is obtained. Then (S2605), and shifts to the processing of S2606.

  In the processing of S2606, it is determined from the data in the winning information storage area 233k acquired in the processing of S2604 whether or not there is a jackpot in the hold (S2606). If it is determined in the processing of S2606 that there is a jackpot in the hold (S2606: Yes), it is then determined whether or not the value of the display effect counter 233o obtained in the processing of S2605 is 0 to 150 ( S2607).

  In the process of S2607, when it is determined that the value of the display effect counter 233o is 0 to 150, the same rear image determination flag as the currently displayed background inside the door is set to ON (S2608), and the process proceeds to S2612. Move on to processing. On the other hand, in the process of S2607, when it is determined that the value of the display effect counter 233o is not 0 to 150 (that is, 151 to 198) (S2607: No), a door different from the currently displayed background in the door is displayed. The back image determination flag corresponding to the inner background is set to ON (S2609), and the flow shifts to the process of S2612.

  On the other hand, if it is determined in the process of S2606 that there is no big hit in the hold (S2606: No), then it is determined whether or not the display effect counter 233o is 0 to 30 (S2610). In the process of S2610, when it is determined that the display effect counter 233o is 0 to 30, the back image determination flag corresponding to the in-door background different from the currently displayed in-door background is set to ON (S2611). , To S2612. On the other hand, in the process of S2610, when it is determined that the value of the display effect counter 233o is not 0 to 30 (that is, 31 to 198) (S2611: No), the rear image corresponding to the background other than the background in the door The determination flag is set to ON (S2613), and the flow shifts to the process of S2614.

    In the process of S2612 executed after S2608, S2609 or S2611, the in-door variation counter 223y is set to 20, and the process proceeds to S2614.

  In the processing of S2614 executed after S2612 or S2613, the back image change flag 233q is set to ON (S2614), and this processing ends.

  Returning to FIG. 113, the description will be continued. In the process of S2304, if it is determined that there is no display variation pattern command (S2304: No), then it is determined whether or not there is a display stop type command among unprocessed commands (S2306). If there is a display variation type command (S2306: Yes), stop type command processing is executed (S2307), and the process returns to S2201.

  Here, the details of the stop type command processing (S2307) will be described with reference to FIG. 114 (b). FIG. 114B is a flowchart showing the stop type command processing. The stop type command process executes a process corresponding to the display variation type command received from the audio lamp control device 114.

  In the stop type command processing, first, a stop type table corresponding to the stop type information (any one of the jackpot A, the jackpot B, the front-rear reach, the reach other than the front-rear miss, and the complete miss) indicated by the display stop type command is determined. (S2501), the stop type table is compared with the value of the stop type counter updated each time the V interrupt processing (see FIG. 42 (b)) is executed, and displayed on the third symbol display device 81. The stop symbol after the variable effect is finally set (S2502).

  Then, among the stop symbol determination flags provided for each stop symbol, the stop symbol determination flag corresponding to the stop symbol set by the process of S2502 is turned on, and the stop symbol determination flag corresponding to the other stop symbols is turned off. Is set to (S2503), and this processing ends.

  Here, as described above, in the variation display data table, after a lapse of a predetermined time from the start of the variation based on the data table, as the type information for specifying the third symbol to be displayed on the third symbol display device 81. , Offset information (symbol offset information) from the stop symbol set by the processing of S2502. In the above-described task process (S2204), after a predetermined time has elapsed from the start of the fluctuation, the stop symbol set by the process of S2502 is specified from the stop symbol determination flag set in S2503, and the specified stop is specified. The third symbol to be actually displayed is specified by adding the symbol offset information acquired by the display setting process to the symbol. Then, the address at which the image data corresponding to the specified third symbol is stored is specified. The image data corresponding to the third symbol is stored in the third symbol area 235d of the resident video RAM 235 as described above.

  Note that the start of the change is always determined at least several seconds in the main control device 110, so that no more than two display stop type commands are received within 20 milliseconds. In this case, it is impossible that two or more display stop type commands are stored in the command buffer area, but some of the commands change due to the influence of noise or the like, and another command is erroneously stopped for display. It may be interpreted as a type command. In the process of S2501, if it is determined that two or more display stop type commands are stored in the command buffer area in preparation for such a case, it is assumed that the stop type is completely out of order and the stop type is determined. Determine the table. Thereby, a stop symbol corresponding to complete departure is set by the processing of S2502.

  If a stop symbol corresponding to the "special symbol jackpot" is set, the third symbol display device 81 displays the "special symbol" even if it is actually "missing the special symbol". The stop symbol corresponding to the "big hit" is displayed, and the player mistakes the pachinko machine 10 for the "special symbol big hit", which may reduce the reliability of the pachinko machine 10. On the other hand, as in the present control example, the stop symbol corresponding to the complete departure is set, and in fact, if the "special symbol jackpot" is reached, the departure stop of the complete departure is displayed on the third symbol display device 81. Even if a symbol is displayed, the pachinko machine 10 becomes a “special symbol jackpot”, and thus the player can be pleased.

  Returning to FIG. 113, the description will be continued. In the process of S2306, if it is determined that there is no stop type command for display (S2306: No), then a reach-related command process is executed among unprocessed commands (S2309), and the process returns to S2301. .

  Here, the details of the reach-related command processing (S2309) will be described with reference to FIG. FIG. 116 is a flowchart showing the reach-related command processing (S2309). The reach-related command processing (S2309) executes processing corresponding to the reach-related command received from the audio ramp control device 114.

  In the reach-related command processing (S2309), first, it is determined whether or not the changing effect is super reach A (S2701). If it is determined that the effect is super reach A (S2701: Yes), the effective press is performed. It is determined whether there is a command (S2702).

  If it is determined in step S2702 that there is a valid press command, the stop display table is set in the display data table buffer 233d (S2703), and the process ends. Here, the processing of S2703 is executed based on the pressing of the frame button 22 during the super reach A effect. By setting the stop display table in the display data table buffer 233d, a stop display (see FIG. 70 (b)) is displayed in the super-reach A effect.

  On the other hand, in the process of S2701, when it is determined that the effect during the change is not the super reach A (that is, the super reach B) (S2701: No), the display super reach B process is executed (S2704). Then, the present process ends.

  Here, the display super reach B process (S2704) will be described in detail with reference to FIG. FIG. 117 is a flowchart showing the display super reach B process (S2704). This display super reach B process (S2704) is executed in the command determination process (see FIG. 43) executed by the MPU 231 of the display control device 114, and switches such as the selection switch 270 during the super reach B effect. This is a process for performing a process based on the operation.

  In the display super reach B process, first, it is determined whether or not there is a valid press command (S2801). In the process of S2801, when it is determined that there is a valid press command (S2801: Yes), it is determined whether or not the symbol is a big hit (that is, whether or not the next valid effect will be a big hit) (S2802). .

  In the process of S2802, when it is determined that the symbol is a big hit (that is, a big hit in the next effective effect) (S2802: No), the stop display table is set in the display data table buffer 233d (S2803). This processing ends. On the other hand, in the process of S2802, when it is determined that the symbol is not a big hit (that is, no big hit in the next effective effect) (S2802: No), the throwing display table is set in the display table buffer (S2804), The process ends.

  On the other hand, in the process of S2801, if it is determined that there is no valid command (S2801: No), it is determined that there is a false press command (S2805). If it is determined in the processing of S2805 that there is a false press command (S2805: Yes), the false throw display table is set in the display data table buffer 233d, and this processing ends.

  In the process of S2805, when it is determined that there is no false press command (S2805: No), it is next determined whether or not there is a replacement command (S2807). In the process of S2807, if it is determined that there is a replacement command (S2807: Yes), the replacement table is set in the display data table buffer 233d (S2808), and this process ends.

  On the other hand, if it is determined in the processing of S2807 that there is no replacement command (S2807), there is no processing based on the switch operation during the production of Super Reach B, so this processing ends as it is.

  Returning to FIG. 113, the description will be continued. In the process of S2308, when it is determined that there is no reach-related command (S2308: No), it is determined whether there is a jackpot-related command (S2810). In the process of S2810, when it is determined that there is a jackpot-related command (S2810: Yes), the jackpot-related command process is executed (S2811), and the process returns to S2301.

  Here, the details of the jackpot-related command processing (S2811) will be described with reference to FIG. FIG. 118 is a flowchart showing the jackpot-related command processing (S2811). The jackpot-related command processing (S2811) executes processing corresponding to the display command related to the jackpot effect received from the audio lamp control device 114.

  In the jackpot-related command processing, first, it is determined whether or not there is a display opening command (S2901). If it is determined in step S2901 that there is an opening command for display, an opening command process is executed (S2902), and the flow advances to step S2903. On the other hand, when it is determined that there is no opening command for display, the process of S2902 is skipped, and the process proceeds to S2903.

  Here, the opening command processing (S2902) will be described in detail with reference to FIG. FIG. 118A is a flowchart showing the opening command processing. The opening command process executes a process corresponding to the display opening command received from the audio lamp control device 114.

  In the opening command process, first, a map setting process for setting a map to be displayed in the big hit effect is executed (S3001). Details of the map setting process (S3001) will be described later with reference to FIG. When the processing of S3001 is completed, the opening display data table is read from the opening effect table storage area (see FIG. 17) of the data table storage area 233b, and is set in the display data table buffer 233d (S3002). Next, a transfer data table corresponding to the display data table set in the processing of S3002 is determined, read from the data table storage area 233b, and set in the transfer data table buffer 233e (S3003).

  Then, based on the opening display data table set in the display data table buffer 233d by the processing of S3002, time data representing the effect time is set in the time counter 233h (S3004), and the pointer 233f is initialized to 0 (S3004). S3005). Then, both the demonstration display flag and the confirmed display flag are set to OFF (S3006), the opening command processing is completed, and the processing returns to the command determination processing.

  By executing this opening command processing, in the display setting processing, while updating the pointer 233f initialized by the processing of S3005, the display data table set in the display data table buffer 233d by the processing of S3002 is updated. The drawing contents specified at the address indicated by the pointer 233f are extracted, and the contents of the image for one frame to be displayed next in the third symbol display device 81 are specified. The transfer data information specified at the address indicated by the pointer 233f is extracted from the set transfer data table, and the sprite image data required in the set opening display data table is stored in advance in the character ROM 234. As will be transferred to the image storage area 236a of the normal video RAM 236, and controls the image controller 237.

  When the opening command processing is executed, the opening transfer data table is set in the transfer data table buffer 233e. As a result, while the opening effect is being performed on the third symbol display device 81, image data necessary for the round effect and the ending effect can be transferred from the character ROM 234 to the normal video RAM 236. As described above, since the pachinko machine 10 uses the NAND flash memory 234a as the character ROM 234, it produces a big hit effect (opening effect, round effect, ending effect) due to its slow reading speed. It takes a lot of time for the image data to be used to be transferred from the character ROM 234 to the normal video RAM 236.

  Since the display round number command indicating the newly started round number is transmitted from the sound lamp control device 113 at the timing when the opening effect in the third symbol display device 81 is completed, the first round is indicated. If the image data necessary for the round effect is transferred from the character ROM 234 to the normal video RAM 236 after receiving the display round number command, a lot of waiting time is required from the end of the opening effect to the start of the round effect. There is a possibility that time will be generated, and the player will feel uneasy as to whether or not the operation has stopped, or give a sense of incongruity.

  In addition, since the display ending command for instructing the start of the ending effect is transmitted from the audio lamp control device 113 at the timing when all the round effects on the third symbol display device 81 (16 rounds) are completed, If the image data necessary for the ending effect is transferred from the character ROM 234 to the normal video RAM 236 after receiving the display ending command, a long waiting time is required between the end of the round effect and the start of the ending effect. This may cause the player to feel uneasy as to whether or not the operation has stopped, or to give the player a sense of discomfort.

  Therefore, in the present control example, when the opening command for display is received, the transfer of the data necessary for the round effect and the ending effect is started from there, and until the fluctuation display of the big hit is completed on the third symbol display device 81. , And the transfer of the data necessary for the round effect and the ending effect is controlled to end. Thus, when the opening effect is completed on the third symbol display device 81, the round effect can be immediately started on the third symbol display device 81, and all of the round effects on the third symbol display device 81 (16 rounds). ) When the game is over, the ending effect can be immediately started on the third symbol display device 81, so that the player does not have anxiety as to whether or not the operation is stopped, and does not give a sense of discomfort. Therefore, the player can be relieved.

  As described above, in the present control example, when the stop type information indicated by the display stop type command is determined to be the jackpot stop type, transfer of image data used in the opening effect is started from there. The control is performed so that the transfer of the image data used in the opening effect is completed by the end of the variable effect that becomes a big hit in the third symbol display device 81. With this, when the variable effect that becomes a big hit on the third symbol display device 81 ends, the opening effect can be immediately started on the third symbol display device 81, and the player is concerned that the operation is not stopped. And it doesn't make you feel uncomfortable. Therefore, the player can be relieved.

  Here, the map setting process (S3001) will be described in detail with reference to FIG. FIG. 120 is a flowchart showing the map setting process (S3001). The map setting process (S3001) is executed in the jackpot-related command process (see FIG. 118) executed by the MPU 231 of the display control device 114, and is a process for setting a map displayed in the jackpot effect.

  In the map setting process, first, the data of the game state storage area 233m is acquired (S3301), and it is determined whether the acquired game state is in the process of probable change or reduction in time (S3302). In the process of S3302, when it is determined that the gaming state is in the process of changing probability or working hours (S3302: Yes), the continuation counter 223p is incremented by 1 (S3303), and the data of the previous map is read from the map storage area 233s. (S3304), a mass event is selected and set from the continuous mass setting table 233t2 based on the value of the continuous counter 233p and the value of the display effect counter (S3305), and the process ends.

  On the other hand, in the process of S3302, when it is determined that the gaming state is not in the probability change or the time reduction (S3302: No), it is determined whether or not there is a continuity passage history by referring to the route history storage area 233w. (S3306).

  In the process of S3306, when it is determined that there is no continuous history passing history (S3306: Yes), since there is no map to continue, the first map is read (S3307), and the big hit variation pattern and the value of the display effect counter 233o are read. Based on this, a mass event is selected and set from the normal mass setting table 233t1 (S3308), and the process ends.

  On the other hand, if it is determined in the process of S3306 that there is a continuum passing history (S3306: No), it is determined whether or not there is a non-passing cell (S3309). In the process of S3309, when it is determined that there is a non-passed cell (S3309: Yes), the previous map and the event cell are read from the map storage area 233s to perform the effect continuously from the previous map (S3310). ), The restart point is set to the continuum of the route having the unpassed cell closest to the start (S3311), and this processing ends.

  In the process of S3309, when it is determined that there is no unpassed cell (S3309: No), a map different from the previous map is read from the map storage area 233s to move to a new map (S3312), and the big hit variation pattern is displayed. A mass event is selected and set from the normal mass setting table 233t1 based on the value of the effect counter 233o (S3313), and the process ends.

  Returning to FIG. 118, the description will be continued. In the processing of S2901, if it is determined that there is no display opening command (S2901: No), then it is determined whether or not there is a display round number command among unprocessed commands (S2903). If there is a round number command for use (S2903: Yes), round number command processing is executed (S2904), and this processing ends.

  Here, the details of the round number command processing (S2904) will be described with reference to FIG. 119 (b). FIG. 119 (b) is a flowchart showing the round number command processing. This round number command process executes a process corresponding to the display round number command received from the audio lamp control device 114.

  In the round number command processing, first, the round number display data table is determined based on the round number indicated by the display round number command and the data in the mass event storage area 233u, and the determined round number display data table is stored in the data table. It is read from the round effect table storage area of the storage area 233b (see FIG. 86) and set in the display data table buffer 233d (S3101). Next, the contents are cleared by writing Null data in the transfer data table buffer 233e (S3102).

  Then, based on the round number display data table set in the display data table buffer 233d by the process of S3101, time data representing the effect time is set in the time counter 233h (S3103), and the pointer 233f is initialized to 0. (S3104). Then, both the demonstration display flag and the confirmed display flag are set to off (S3105), the round number command processing is ended, and the processing returns to the command determination processing.

  Here, the description returns to FIG. In the process of S2903, if it is determined that there is no display round number command (S2903: No), then it is determined whether or not an unprocessed command includes a display ending command (S2905). If there is an ending command for use (S2905: Yes), ending command processing is executed (S2906), and this processing ends. On the other hand, in the process of S2905, if there is no ending command for display (S2905: No), the process of S2906 is skipped, and this process ends.

  Here, the ending command processing (S2906) will be described in detail with reference to FIG. FIG. 121 is a flowchart showing the ending command processing. This ending command processing is to execute processing corresponding to the display ending command received from the audio lamp control device 114.

  In the ending command process, first, it is determined whether or not there is a big hit in the hold in the data of the winning information storage area 233k (S3401). If it is determined in the process of S3401 that there is a jackpot in the hold (S3401: Yes), the mass event is updated based on the information of the jackpot hold and the display effect counter 233o (S3402), and the process of S3403 is performed. Move to. In the process of S3402, for example, when there is a jackpot in the hold, a square two squares ahead of the current location square (that is, a square that can be reached by generating two jackpots) is set as a special square (FIG. 74 ( b)). By setting the two squares as the special squares, the player expects at least two more jackpots to continue the game.

  Next, an ending display data table corresponding to the display mode of the ending effect indicated by the display ending command is determined (S3403), and the determined ending display data table is stored in the ending effect table storage area of the data table storage area 233b (FIG. 86, and is set in the display data table buffer 233d (S3404). Next, the contents are cleared by writing Null data in the transfer data table buffer 233e (S3405). Then, based on the ending display data table set in the display data table buffer 233d by the processing of S3401, time data representing the presentation time is set in the time counter 233h (S3406), and the pointer 233f is initialized to 0 (S3406). S3407). Then, both the demonstration display flag and the confirmed display flag are set to OFF (S3408), the ending command process is completed, and the process returns to the command determination process.

  By executing the ending command processing, the ending effect can be displayed on the third symbol display device 81 when the special symbol big hit ends, so that the player recognizes that the big hit has ended. Can be done.

  Returning to the description of FIG. 113, the description is continued. In the processing of S2310, if it is determined that there is no ending command for display (S2310: No), then it is determined whether or not there is a back image change command among the unprocessed commands (S2312). If there is a change command (S2312: Yes), a back image change command process is executed (S2313), and the process returns to S2301.

  Here, the details of the back image change command processing (S2313) will be described with reference to FIG. FIG. 122 is a flowchart showing the back image change command processing. The rear image change command process executes a process corresponding to the rear image change command received from the audio lamp control device 114.

  In the rear image change command process, first, a rear image change flag for notifying the normal image transfer setting process (see FIG. 131) of the change of the rear image due to the reception of the rear image change command in the ON state is set to ON (see FIG. 131). S3501). Then, based on the current background image and the background addition flag 223x, a back image type (back A to C, super back notice, background in door, etc.) is selected, and a back image discrimination flag corresponding to the selected back image type. Is turned on, the back image discrimination flags corresponding to the other back image types are set to off (S3503), and the process shifts to S3504.

  In the process of S3504, it is determined whether or not the selected back image type is the super background notice (S3504). If it is determined in the processing of S3504 that it is a super background notice, the super background flag 233r is set to ON (S3505), and this processing ends. On the other hand, if it is determined in step S3504 that the notice is not the super background notice, the process in step S3505 is skipped, and the process ends. By turning on the super background flag 233r in the process of S3505, the super background SW process (S3602) that performs the process based on the switch operation during the super background in the SW related command process (see FIG. 123) described later. Can be performed.

  In the normal image transfer setting process, upon detecting that the rear image change flag set in the process of S3501 is turned on, the rear image type after the change is identified from the rear image determination flag set in the process of S3502. . If the specified rear image type is the rear surface B or the rear surface C, as described above, a part of the image data corresponding to those rear images is resident in the rear image area 235c of the resident video RAM 235. Since the image data corresponding to the rear image in the predetermined range is not transferred, a transfer instruction is set to the image controller 237 so as to transfer the image data corresponding to the rear image from the character ROM 234 to the predetermined sub-area of the image storage area 236a of the normal video RAM 236.

  Also, in the task processing (S2204), when it is specified that any one of the back A to C, the super back notice, the background in the door, and the like is displayed according to the back type of the back image specified in the display data table. , The type of the rear image to be displayed at that time is specified from the rear image determination flag set by the processing of S3502, and the range of the rear image to be displayed is specified in accordance with the elapse of time. The RAM type (resident video RAM 235 or normal video RAM 236) storing the image data corresponding to the range and the address of the RAM are specified.

  Since the player does not continuously operate the frame button 22 for less than 20 milliseconds, the player does not receive two or more rear image change commands within 20 milliseconds. In this case, there should be no case where two or more back image change commands are stored in the command buffer area, but some of the commands change due to the influence of noise or the like, and another command erroneously changes the back image. It may be interpreted as a command. In the process of S3502, when it is determined that two or more rear image commands are stored in the command buffer area, the rear image type indicated by the previously received rear image command may be selected, or the rear image type received later may be selected. The back image type indicated by the back image command may be selected. Alternatively, one arbitrary back image change command may be extracted, and the back image type indicated by the command may be selected. Since the change of the back image does not directly affect the game value of the pachinko machine 10, it is preferable to appropriately set the change according to the characteristics and operability of the pachinko machine 10.

  Here, the description returns to FIG. In the process of S2312, when it is determined that there is no rear image change command (S2312: No), it is then determined whether there is a SW-related command among the unprocessed commands (S2314). In the process of S2314, when it is determined that there is a SW-related command (S2314: Yes), a SW-related command process is executed (S2315), and the process returns to S2301.

  Here, the details of the SW-related command processing (S2315) will be described with reference to FIG. FIG. 123 is a flowchart showing the SW-related command processing (S2315). The SW-related command processing (S2315) executes processing corresponding to a command based on a switch operation received from the audio lamp control device 114.

  In the SW-related command processing, first, it is determined whether or not the super background flag 233r is on (S3601). If it is determined in the processing of S3601 that the super background flag 233r is ON (S3601: Yes), the super background notice is being displayed, and the super background middle SW that performs processing based on the switch operation during the super background is displayed. The processing is executed (S3602), and this processing ends.

  Here, with reference to FIG. 124, details of the super background middle SW process (S3602) will be described. FIG. 124 is a flowchart showing the super background middle SW process (S3602). The super background middle SW process (S3602) is a process for executing an effect based on the operation of the selection switch 270 or the like while the super background notice is being displayed.

  In the super background middle SW process, first, it is determined whether or not the decision switch 270e is pressed (S3701). In the process of S3701, when it is determined that the determination switch 270e is pressed (S3701: Yes), the display data of the currently displayed background image is obtained (S3702), and it is determined whether or not the display is capable of shifting. (S3703). Here, the display indicating that transition is possible indicates a case where the specific image is displayed in the rear image, and a case where the image of the door is blinking in the present control example (see FIG. 67).

  In the process of S3703, when it is determined that the display is not during the transferable display (S3703: No), the process ends as it is. On the other hand, if not (S3703: Yes), the value of the in-door change frequency counter 223y is set to 20 (S3704), the data of the winning information storage area 233k is obtained (S3705), and the value of the display effect counter 233o is obtained. Is acquired (S3706), and the process proceeds to S3707.

  In the processing of S3707, it is determined whether or not there is a big hit in the hold in the data of the winning information storage area 233k acquired in the processing of S3705 (S3707). If it is determined that there is a big hit in the hold (S3707) : Yes), then, it is determined whether or not the value of the display effect counter 233o acquired by the process of S3706 is 0 to 100 (S3708).

  In the process of S3708, when it is determined that the display effect counter 233o is 0 to 100 (S3708: Yes), the rear image determination flag corresponding to the high expectation inside door background is set to ON (S3709), The process shifts to S3714. On the other hand, when it is determined that the display effect counter 233o is not 0 to 100 (that is, 101 to 198) (S3708: No), the rear image determination flag corresponding to the low expectation inside the door is set to ON. Then, the flow shifts to the processing of S3714.

  On the other hand, if it is determined in the process of S3707 that there is no big hit in the hold (S3707: No), then it is determined whether the value of the display effect counter 233o is 0 to 30 (S3711).

  In the process of S3711, when it is determined that the display effect counter 233o is 0 to 30 (S3711: Yes), the rear image determination flag corresponding to the high expectation inside door background is set to ON (S3712). The process shifts to S3714. On the other hand, when it is determined that the display effect counter 233o is not 0 to 30 (that is, 31 to 198) (S3711: No), the rear image determination flag corresponding to the low expectation inside the door is set to ON. Then, the flow shifts to the processing of S3714.

  In the processing of S3714 executed after S3709, S3710, S3712 or S3713, the back image change flag 233q is set to ON (S3714), and this processing ends. By setting the back image change flag 233q to ON in the processing of S3714, the back image of the background in the door set in any of S3709, S3710, S3712 or S3713 can be displayed.

  Note that the back image data is set in the normal image transfer setting process (see FIG. 131) by the back image change flag 233q set to ON in the process of S3714, and the back image is changed. The timing at which the data of the rear image is set may be synchronized with the timing at which the next variable display is started, or may be synchronized with the timing at which the currently executed variable display ends. good. As a method of synchronizing with each of the above-mentioned timings, a method of adjusting the timing of setting the back image change flag 233q to on in the processing of S3714, or a method of setting the back image data in the normal image transfer setting processing (see FIG. 131). For example, a method of adjusting the timing to be performed is exemplified. Specifically, in the process of S3714, a time difference from the synchronization timing is calculated, and after the calculated time elapses, the rear image change flag 233q is set to ON to adjust the timing at which the rear image is changed. be able to.

  Here, by the processing of S3707, S3708, and S3709, the ratio of setting the high expectation inside-door background is different depending on whether there is a jackpot in the hold. In other words, the display content of the background in the door for the player is one of the information for predicting the possibility that there is a big hit in the hold. Thereby, the player who wants to know this information plays the game while paying attention to the display of the specific image, which is the timing at which the background inside the door can be displayed. As a result, the interest of the player can be improved.

  On the other hand, if it is determined in the processing of S3701 that the determination switch 270e has not been pressed (S3701: No), then it is determined whether any of the selection switches (up switch 270a to left switch 270d) has been pressed. It is determined (S3715).

  In the process of S3715, if it is determined that any of the selection switches (up switch 270a to left switch 270d) has been pressed (S3715: Yes), it is determined based on the pressed selection switch (up switch 270a to left switch 270d). Then, the display coordinates are reset (S3716), and this process ends. If not (S3715: No), the process ends.

  Here, the scroll display of the back image is executed based on the set display coordinates. More specifically, display coordinates for displaying the rear image are stored in chronological order, and the rear images corresponding to the display coordinates are displayed in the order in which they are stored. For example, if the display coordinates are stored so as to increase only in the horizontal direction, the rear image is scroll-displayed in the horizontal direction (to the right of the third symbol display device 81).

  In the process of S3716, for example, the display coordinates set to increase only in the horizontal direction are fixed at the current value in the horizontal direction based on the depression of the upper switch 270a, and the display direction is increased in the vertical direction. Reset the display coordinates as follows. Thus, the rear image scrolled horizontally (to the right of the third symbol display device 81) can be changed so as to be scrolled vertically (toward the third symbol display device 81).

  As a result, it is possible to give the player a feeling as if he or she is searching within the back image of the super background notice displayed on the third symbol display device 81 by his / her own operation. Can be improved. Further, the background image of the super background notice includes a specific image (an image of the door in the present control example) necessary for displaying the in-door background as described above. Thereby, the player who wants to display the in-door background performs a search in the back image of the super-background notice with more interest in order to find the specific image, so that the interest of the player can be improved.

  Returning to FIG. 123, the description will be continued. If it is determined in the processing of S3601 that the super background flag 233r is not turned on (S3601: No), then it is determined whether or not a jackpot effect is being produced (S3603). If it is determined in the processing of S3603 that a jackpot effect is being produced (S3603: Yes), a jackpot medium SW process is executed (S3604), and this process ends. Otherwise (S3603: No), the process of S3604 is skipped, and the process ends.

  Here, with reference to FIG. 125, details of the big hit SW process (S3604) will be described. FIG. 125 is a flowchart showing the big hit SW process. The big hit SW process executes a process corresponding to a display command based on the operation of the selection switch 270 and the like received from the audio lamp control device 114 during the big hit effect.

  In the big hit SW process, first, it is determined whether or not it is a SW valid period within a round (S3801). If it is determined in the processing of S3801 that the current period is not the SW valid period within the round (S3801: No), the processing is terminated as it is not the timing to perform the effect based on the switch operation.

  On the other hand, if it is determined in the processing of S3801 that the current period is the SW valid period within the round (S3801: Yes), it is then determined whether any of the selection switches (up switch 270a to left switch 270d) has been pressed. (S3802).

  In the process of S3802, if it is determined that any of the selection switches (up switch 270a to left switch 270d) has been pressed (S3802: Yes), it is determined whether the selection is normal (S3803). Specifically, when the movable direction in the map of the jackpot effect is down or right (see FIG. 72A), the case where the down switch 270c or the left switch 270d is pressed is a normal selection. Is determined.

  If it is determined in the processing of S3803 that the selection is normal (S3803: Yes), the pointer 233f is set so that the display moves by one cell in the selection direction (S3804), and the flow shifts to the processing of S3805.

  On the other hand, if it is determined in step S3803 that the selection is not normal (S3803: No), the process skips step S3804 and shifts to step S3805.

  In the process of S3805, it is determined whether or not the decision switch 270e has been pressed (S3805). In the process of S3805, when it is determined that the determination switch 270e is pressed (S3805: Yes), it is determined whether a determinable cell is selected (S3806). Specifically, when the same cell as the previous cell is selected, it is determined that no determinable cell is selected.

  In the process of S3806, if it is determined that a determinable cell is not selected (S3806: No), the process ends as it is. On the other hand, if not (S3806: Yes), the event of the determined cell is stored in the cell event storage area 233u (S3807), and the determined cell is added to the route history storage area (S3808), and the process proceeds to S3809. Transition.

  By the processing of S3807, a round effect by the round number command processing (see FIG. 119 (b)) can be executed based on the mass event stored in the mass event storage area 233u. Also, in the process of S3808, based on the route history stored in the route history storage area 233w, the above-described map setting process (see FIG. 120) determines whether there is a non-passing cell (whether a new map is displayed or not). Discrimination) becomes possible.

  In the processing of S3809 executed after the processing of S3808, it is determined whether or not the determined mass event is background addition (S3809). In the processing of S3809, when it is determined that the mass event is background addition (S3809: Yes), the background addition flag 233x is set on based on the display effect counter 233o (S3810). Specifically, when the display effect counter 233o is 0 to 100, the background addition flag 233x is set to ON. The present invention is not limited to this. A plurality of backgrounds to be added (for example, additional background A, additional background B) are prepared, and when the display effect counter 233o is 0 to 50, the background addition flag 233x for adding the additional background A is turned on. When the display effect counter 233o is 51 to 100, the background addition flag 233x for adding the additional background B may be set to ON.

  On the other hand, if it is determined in the process of S3809 that the event is not a background addition (S3809: No), the process ends.

  Here, the description returns to FIG. In the process of S2314, if it is determined that there is no SW-related command (S2314: No), then, it is determined whether or not there is a winning command for display among unprocessed commands (S2216). In the process of S2216, if there is a winning command for display (S2216: Yes), winning information based on the received command is stored in the winning information storage area 233k (S2317), and the process returns to S2301.

  The winning information stored in the winning information storage area 233k by the processing of S2317 is used for selecting a display effect in the above-described super background effect process (see FIG. 115).

  On the other hand, if it is determined in the processing of S2316 that there is no winning command for display (S2316: No), it is then determined whether or not there is an error command among the unprocessed commands (S2318). If there is (S2318: Yes), an error command process is executed (S2319), and the process returns to S2301.

  Here, the error command processing (S2319) will be described in detail with reference to FIG. FIG. 126 is a flowchart showing the error command processing. This error command process executes a process corresponding to the error command received from the audio lamp control device 114.

  In the error command processing, first, an error occurrence flag indicating that an error has occurred in the ON state is set to ON (S3901). Then, among the error determination flags provided for each error type, the error determination flag corresponding to the error type indicated by the error command is turned on, and the other error determination flags are set to off (S3902). The process ends, and returns to the command determination process.

  In the display setting process, when the occurrence of an error is detected based on the error occurrence flag set in the process of S3901, the type of error that occurred based on the error determination flag set in the process of S3902 is determined, and the corresponding error type is determined. The processing is executed so that the warning image to be displayed is displayed on the third symbol display device 81.

  If it is determined that two or more error commands are stored in the command buffer area, in step S3902, error determination flags corresponding to all error types indicated by the respective error commands are set to ON. As a result, warning images corresponding to all error types are displayed on the third symbol display device 81, so that a player or a person related to the hall can correctly grasp the occurrence state of the error.

  Here, the description returns to FIG. If it is determined in the processing of S2318 that there is no error command (S2318: No), then processing corresponding to other unprocessed commands is executed (S2320), and the processing returns to S2301.

  In the processing of S2301 executed again after the processing of each command is executed, it is determined again whether or not there is an unprocessed new command in the command buffer area, and if there is an unprocessed new command (S2301: Yes) ), And execute the processing of S2302 to S2320 again. Until there is no unprocessed new command in the command buffer area, the processing of S2301 to S2320 is repeatedly executed. If it is determined in the processing of S2301 that there is no unprocessed new command in the command buffer area, this command determination is performed. The process ends.

  Note that the simple command determination process (S2209) executed when the simple image display flag 233c is ON in the V interrupt process (see FIG. 112B) is similar to the command determination process. However, in the simple command determination process, only the commands necessary for displaying the image at power-on, that is, the display variation pattern command and the display stop type command are extracted from the unprocessed commands stored in the command buffer area. Extraction and execution of variation pattern command processing (see FIG. 114 (a)) and stop type command processing (see FIG. 114 (b)), which are processing corresponding to each command, are performed. Then, a process for discarding the command without executing the process corresponding to the command is performed.

  Here, in the fluctuation pattern command processing (see FIG. 114A) executed in this case, in the processing of S2402, the display data table buffer corresponding to the display of the power-on fluctuation image is stored in the display data table buffer 233d. The image data of the power-on main image and the power-on fluctuation image which are set and necessary in that case are stored in the power-on main image area 235a and the power-on fluctuation image area 235b of the resident video RAM 235. Therefore, in the process of S2302, a process of writing Null data in the transfer data table buffer 233b and clearing the contents is performed.

  Next, the details of the above-described display setting process (S2203), which is one process of the V interrupt process executed by the MPU 231 of the display control device 114, will be described with reference to FIGS. 127 to 129. FIG. 127 is a flowchart showing this display setting process.

  In this display setting process, as shown in FIG. 127, it is determined whether or not the new command flag is on (S4001), and if the new command flag is not on, that is, off (S4001: No), In the previously executed command determination process, it is determined that the new command has not been processed, and the process of S4002 to S4004 is skipped, and the process proceeds to S4005. On the other hand, if the new command flag is on (S4001: Yes), it is determined that the new command has been processed in the previously executed command determination processing, the new command flag is set to off (S4002), and then S4003 to S4004. The processing corresponding to the new command is executed.

  In the process of S4003, it is determined whether or not the error occurrence flag is on (S4003). If the error occurrence flag is on (S4003: Yes), a warning image setting process is executed (S4004).

  Here, the warning image setting process will be described in detail with reference to FIG. FIG. 128 is a flowchart showing the warning image setting process. This process is a process for developing image data for displaying a warning image corresponding to an error that has occurred on the third symbol display device 81. First, referring to the error determination flag, all error determinations for which ON is set are set. The warning image data for displaying the error warning image corresponding to the flag on the third symbol display device 81 is developed (S4101).

  In the task processing (S2204), based on the expanded warning image data, the type of the sprite (display object) constituting the warning image is specified, and the display coordinate position, enlargement ratio, rotation angle, and the like are specified for each sprite. Determine various parameters required for drawing.

  Then, in the warning image setting process, after the process of S4101, the error occurrence flag is set to off (S4102), and the process returns to the display setting process.

  Here, the description returns to FIG. 127. After the warning image setting process (S4004) or in the process of S4003, if it is determined that the error occurrence flag is not on, that is, it is off (S4003: No), the process proceeds to S4005.

  In S4005, a pointer update process is performed (S4005). Here, the details of the pointer update processing will be described with reference to FIG. FIG. 129 is a flowchart showing the pointer update processing. This pointer updating process acquires the corresponding drawing content or transfer data information of the transfer target image data from the display data table and the transfer data table stored in the display data table buffer 233d and the transfer data table buffer 233e, respectively. This is a process of updating the pointer 233f specifying the address to be set.

  In this pointer update process, first, 1 is added to the pointer 233f (S4201). That is, the pointer 233f is updated in principle such that it is incremented by one each time the V interrupt processing is executed. As described above, in the various data tables, the start information is described at the address “0000H”, and the entity of each data is defined after the address “0001H”. When the value of the pointer 233f is initialized to 0 in accordance with being stored in the data table buffer 233d, the value is updated to 1 by this pointer update processing. Substantial data can be read from the data table.

  After the value of the pointer 233f is updated by the processing of S4201, next, in the display data table set in the display data table buffer 233d, it is determined whether or not the data at the address indicated by the updated pointer 233f is End information. Is determined (S4202). As a result, if it is End information (S4202: Yes), it means that the pointer 233f has been updated past the address where the actual data is described in the display data table set in the display data table buffer 233d.

  Therefore, it is determined whether or not the display data table stored in the display data table buffer 233d is a demo display data table (S4203). If the display data table is a demo display data table (S4203: Yes), the display data table buffer is determined. The time data corresponding to the presentation time of the demonstration display data table set in 233d is set in the time counter 233h (S4204), the pointer 233f is set to 1 and initialized (S4205), and the present processing is terminated and the display is completed. Return to the setting process. Thus, in the display setting process, the rendering contents can be developed in order from the top of the demonstration display data table, so that the third symbol display device 81 can repeatedly display the demonstration effect.

  On the other hand, if it is determined in the process of S4203 that the display data table stored in the display data table buffer 233d is not the demonstration display data table (S4203: No), the value of the pointer 233f is decremented by 1 (S4206). ), End this processing, and return to the display setting processing. Thereby, in the display setting process, when a display data table other than the demonstration display data table, for example, a variable display data table is set in the display data table buffer 233d, the previous address of the end information is described. Since the drawing content is always developed, the third symbol display device 81 can display the last image defined by the display data table in a stopped state. On the other hand, in the process of S4202, if the data of the address indicated by the updated pointer 233f is not End information (S4202: No), the process ends, and the process returns to the display setting process.

  Here, returning to FIG. 127, the description will be continued. After the pointer updating process, the drawing content of the address indicated by the pointer 233f updated by the pointer updating process is developed from the display data table set in the display data table buffer 233d (S4006). In the task process (S2204), the type of sprite (display object) constituting the image is specified based on the drawing content expanded in the process of S4006 together with the previously expanded warning image and the like. Various parameters required for drawing, such as a display coordinate position, an enlargement ratio, and a rotation angle, are determined.

  Next, the value of the time counter 233h is decremented by 1 (S4007), and it is determined whether or not the value of the time counter 233h after the subtraction is 0 or less (S4008). Then, when the value of the time counter 233h is 1 or more (S4008: No), the display setting process is ended and the process returns to the V interrupt process. On the other hand, when the value of the time counter 233h is 0 or less (S4008: Yes), it means that the effect time of the effect corresponding to the display data table set in the display data table buffer 233d has elapsed. At this time, if the variable display data table is set in the display data table buffer 233d, it is the timing to end the variable display and perform the stop display, so it is confirmed whether or not the confirmed display flag is on. (S4009).

  As a result, if the confirmed display flag is off (S4009: No), the effect of the confirmed display has not been performed yet, and it is the timing to perform the effect of the confirmed display. First, the confirmed display data table is stored in the display data table buffer 233d. The setting is made (S4010), and then the contents are cleared by writing Null data in the transfer data table buffer 233e (S4011). Then, time data corresponding to the presentation time in the confirmed display data table is set in the time counter 233h (S4012), and the value of the pointer 233f is initialized to 0 (S4013). Then, after the final display flag indicating that the final display effect is being performed in the ON state is set to ON (S4014), the content of the stop symbol determination flag is directly copied to the previous stop symbol determination flag provided in the work RAM 233. (S4015), and returns to the V interrupt processing.

  Thus, in the case where the variable display data table is set in the display data table buffer 233d, the final display effect of the stop symbol in the variable effect is displayed on the third symbol display device 81 in accordance with the end of the effect. Thus, the drawing content can be set. Further, by simply changing the display data table set in the display data table buffer 233b to the confirmed display data table, the effect to be displayed on the third symbol display device 81 can be easily changed to the confirmed display effect. Compared with the case where the display content is changed by activating another program as in the related art, the program is not complicated and bloated, so that no great load is applied to the MPU 231. Regardless of the processing capability of the display control device 114, various effect images can be displayed on the third symbol display 81.

  Note that the last stop symbol determination flag set by the process of S4015 is used to specify the third symbol to be displayed on the third symbol display device 81 in the next variable effect. That is, as described above, the display of the third symbol in the variable effect changes according to the stop symbol of the variable effect performed immediately before, and in the variable display data table, the change based on the data table is not changed. Until a predetermined time has elapsed from the start, the symbol offset information from the stop symbol of the variable effect performed immediately before is described. In the task process (S2204), until the predetermined time has elapsed since the start of the fluctuation, the stop symbol of the fluctuation effect performed immediately before is specified from the previous stop symbol determination flag set in S4015, and By adding the symbol offset information acquired by the display setting process to the specified stopped symbol, the third symbol to be actually displayed is specified. Thereby, the variable effect is started from the stop symbol in the immediately preceding variable effect.

  On the other hand, in the process of S4009, if the confirmed display flag is not on but off (S4009: No), it is determined whether the demonstration display flag is on (S4016). If the demonstration display flag is off (S4016: Yes), it means that the value of the clock counter 233h has become 0 or less with the end of the finalized display effect, so that the demonstration display data table is displayed in the display data table. The contents are set in the buffer 233d (S4017), and then the contents are cleared by writing Null data in the transfer data table buffer 233e (S4018). Then, time data corresponding to the effect time in the demonstration display data table is set in the time counter 233h (S4019). Then, the pointer 233f is initialized to 0 (S3320), the demonstration display flag indicating that the demonstration is being performed in the ON state is set to ON (S4021), and the present process ends, and the process returns to the V interrupt process.

  Thereby, when the display variation pattern command indicating the start of the next variation effect is not received after the final display effect is completed, the demonstration effect is automatically displayed on the third symbol display device 81. Can be set the drawing content.

  In the process of S4016, if the demonstration display flag is ON (S4016: No), the demonstration effect is performed after the finalized display effect ends, and this means that the demonstration effect has ended, so the display setting process ends as it is. Then, the process returns to the V interrupt processing. Then, in this case, as described above, various settings are performed by the pointer update process executed in the next V interrupt process so that the demonstration effect is started again. Until a new display variation pattern command is received, the demonstration effect can be repeatedly displayed on the third symbol display device 81.

  Note that the same processing as the display setting processing is also performed in the simple display setting processing (S2209) executed when the simple image display flag 233c is ON in the V interrupt processing (see FIG. 112B). However, in the simple display setting process, after the effect time of the fluctuation effect by the power-on fluctuation image ends, for a predetermined time, a simple power-on fluctuation image according to the stop symbol set based on the display stop type command. A process of setting a display data table that defines that the image is stopped and displayed in the display data table buffer 233d is performed.

  Next, with reference to FIG. 130 and FIG. 131, details of the above-described transfer setting process (S2205), which is one process of the V interrupt process executed by the MPU 231 of the display control device 114, will be described. First, FIG. 130A is a flowchart showing the transfer setting process.

  In this transfer setting process, first, it is determined whether or not the simple image display flag 233c is on (S4301). If the simple image display flag 233c is on (S4301: Yes), all image data to be resident in the resident video RAM 235 has not been transferred from the character ROM 234 to the resident video RAM 235, so the resident image transfer setting process Is executed (S4302), the transfer setting process ends, and the process returns to the V interrupt process. Thereby, a transfer instruction is set to the image controller 237 to transfer the image data to be resident in the resident video RAM 235 from the character ROM 234 to the resident video RAM 235. The details of the resident image transfer setting process will be described later with reference to FIG.

  On the other hand, as a result of the processing in S4301, if the simple image display flag 233c is not on, that is, if it is off (S4301: No), all the image data to be resident in the resident video RAM 235 is transferred from the character ROM 234 to the resident video. The data has been transferred to the RAM 235. In this case, the normal image transfer setting process is executed (S4303), the transfer setting process ends, and the process returns to the V interrupt process. As a result, a transfer instruction is set so that the subsequent transfer of image data from the character ROM 234 is performed to the normal video RAM 236. The details of the normal image transfer setting process will be described later with reference to FIG.

  Next, the resident image transfer setting process (S4302), which is one of the transfer setting processes (S2205) executed by the MPU 231 of the display control device 114, will be described with reference to FIG. FIG. 130B is a flowchart showing the resident image transfer setting process (S4302).

  In the resident image transfer setting process, first, it is determined whether or not an instruction to transfer untransferred image data has been issued to the image controller 237 (S4401). If the transfer instruction has been transmitted (S4401: Yes) Further, it is determined whether or not the image data transfer process performed by the image controller 237 based on the transfer instruction has been completed (S4402). In the process of S4402, after instructing the image controller 237 to transfer the image data, if a transfer end signal indicating the end of the transfer process is received from the image controller 237, it is determined that the transfer process has ended. . If it is determined that the transfer process is not completed by the process of S4402 (S4402: No), since the image transfer process is continuously performed in the image controller 237, the resident image transfer setting process is performed. finish. On the other hand, when it is determined that the transfer process has been completed (S4402: Yes), the process proceeds to S4403. Also, as a result of the process of S4401, if the transfer instruction of the untransferred image data has not been transmitted to the image controller 237 (S4401: No), the process proceeds to S4403.

  In the process of S4403, it is determined whether or not all the resident target image data to be resident in the resident video RAM 235 has been transferred (S4403). If there is an untransferred resident target image data (S4403: No), the process proceeds to S4403. A transfer instruction to the image controller 237 is set to transfer the resident image data to be transferred from the character ROM 234 to the resident video RAM 235 (S4404), and the resident image transfer setting process ends.

  As a result, the drawing list transmitted to the image controller 237 in the drawing processing includes the transfer data information on the untransferred resident target image data, and the image controller 237 transmits the transfer data described in the drawing list. The resident object image data can be transferred from the character ROM 234 to the resident video RAM 236 based on the data information. The transfer data information includes the start address and the end address of the character ROM 234 in which the resident target image data is stored, the information of the transfer destination (in this case, the resident video RAM 235), and the transfer destination (the transfer is performed here). The head address of an area provided in the resident video RAM 235 where the resident target image data is to be stored is included. The image controller 237 executes an image transfer process based on the transfer data information, reads out the image data specified in the transfer process from the character ROM 234, temporarily stores the read image data in the buffer RAM 237a, and then stores the image data in the unused period of the resident video RAM 236. Then, the data is transferred to the designated address of the resident video RAM 236. Then, when the transfer is completed, a transfer end signal is transmitted to the MPU 231.

  As a result of the processing in S4403, if all the resident target image data has been transferred (S4403: Yes), the simple image display flag 233c is set to off (S4405), and the resident image transfer setting processing ends. Thus, in the V interrupt processing (see FIG. 112 (b)), the command is not the simple command determination processing (see S2208 in FIG. 112 (b)) and the simple display setting processing (see S2209 in FIG. 112 (b)). Since the determination process (see FIGS. 113 to 126) and the display setting process (see FIGS. 127 to 129) are performed, the drawing of the image in the normal state is set. Displays the normal image. Further, the subsequent transfer of image data from the character ROM 234 is performed to the normal video RAM 236 by the normal image transfer setting process (see FIG. 131) (see S4301: No in FIG. 130A).

  By executing the resident image transfer setting process, the MPU 231 performs all resident operations to be resident in the resident video RAM 235 except for the power-on main image and the power-on fluctuation image that have already been transferred in the main process. The target image data can be transferred from the character ROM 234 to the resident video RAM 235. Then, the MPU 231 controls the image data transferred to the resident video RAM 235 so as to be maintained without being overwritten during power-on. Thus, the image data transferred to the resident video RAM 235 by the resident image transfer setting process is resident in the resident video RAM 235 while the power is on.

  Therefore, after all the image data to be resident in the resident video RAM 235 is transferred to the resident video RAM 235, the display control device 114 uses the image data resident in the resident video RAM 235 while using the image controller 237. Can perform image drawing processing. As a result, if the image data used for the drawing process is resident in the resident video RAM 235, it is not necessary to read the corresponding image data from the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed when drawing an image. Therefore, the time required for the reading can be omitted, the image can be drawn immediately, and the drawn image can be displayed on the third symbol display device 81.

  In particular, the resident video RAM 235 stores image data of frequently displayed images such as a rear image, a third symbol, a character symbol, and an error message, the main controller 110, the sound lamp controller 113, and the display controller 114. After the display is determined by, for example, the image data of the image to be displayed is made resident immediately. Therefore, even if the character ROM 234 is configured by the NAND flash memory 234a, various operations performed at an arbitrary timing by the player can be performed. In addition, the responsiveness until a certain image is displayed on the third symbol display device 81 can be kept high.

  Next, the normal image transfer setting process (S4303), which is one of the transfer setting processes (S2205) executed by the MPU 231 of the display control device 114, will be described with reference to FIG. FIG. 131 is a flowchart showing the normal image transfer setting process (S4303).

  In the normal image transfer setting process, first, a pointer 233f updated from the transfer data table set in the transfer data table buffer 233e by the pointer update process (S4005) of the previously executed display setting process (S2203). The information described at the indicated address is obtained (S4501). Then, it is determined whether or not the acquired information is the transfer data information (S4502). If the obtained information is the transfer data information (S4502: Yes), the character ROM 234 storing the transfer target image data is obtained from the transfer data information. (The storage source start address) and the end address (storage source end address), and the start address of the transfer destination (normal video RAM 236), and store them in the transfer data buffer provided in the work RAM 233 ( (S4503) Further, the transfer start flag provided in the work RAM 233 and indicating that there is image data to be transferred in the ON state is set to ON (S4504), and the process proceeds to S4505.

  Also, in the process of S4502, if the acquired information is not transfer data information but Null data (S4502: No), the processes of S4503 and S4504 are skipped, and the process proceeds to S4505. In the process of S4505, it is determined whether a new image data transfer instruction has been set to the image controller 237 after the previous image data transfer has been completed (S4505), and the transfer instruction is set. If the transfer has been completed (S4505: Yes), it is further determined whether or not the transfer of the image data performed by the image controller 237 has been completed based on the transfer instruction (S4506).

  In the process of S4506, after setting a transfer instruction of image data to the image controller 237 and receiving a transfer end signal indicating the end of the transfer process from the image controller 237, it is determined that the transfer process has ended. . If it is determined in step S4506 that the transfer process has not been completed (S4506: No), the image controller 237 continues the image transfer process. finish. On the other hand, if it is determined that the transfer process has been completed (S4506: Yes), the process proceeds to S4507. Also, as a result of the processing in S4505, if the image data transfer instruction has not been set to the image controller 237 after the end of the previous transfer processing (S4505: No), the process proceeds to S4507.

  In the process of S4507, it is determined whether or not the transfer start flag is on (S4507). If the transfer start flag is on (S4507: Yes), there is image data to be transferred, so the transfer start flag is set. Is turned off (S4508), the image data of the sprite indicated by the various kinds of information stored in the transfer data buffer by the processing of S4503 is set as the transfer target image data, and then the process proceeds to S4513. On the other hand, if the transfer start flag is not on but off (S4507: No), then it is determined whether the back image change flag is on (S4509). If the back image change flag is not on but off (S4509: No), there is no image data to be transferred, and the normal image transfer setting process ends as it is.

  On the other hand, if the back image change flag is on (S4509: Yes), it means that the back image is changed. Therefore, after setting the back image change flag to off (S4510), the back image provided for each back image type is set. Among the determination flags, the image data of the rear image corresponding to the rear image determination flag in the ON state is specified, and the image data is set as the transfer target image data (S4511). Furthermore, the start address (storage source start address) and the end address (storage source end address) of the character ROM 234 storing the image data of the back image corresponding to the back image determination flag in the ON state, and the transfer destination (normal) The start address of the video RAM 236) is acquired (S4512), and the process proceeds to S4513.

  If the back image discrimination flag in the ON state is that of the back A, all the corresponding image data is resident in the back image area 235c of the resident video RAM 235, and the image to be transferred to the normal video RAM 236 is stored. No data exists. Therefore, in the process of S4511, if the rear image discrimination flag in the ON state is that of the rear surface A, the normal image transfer process ends.

  In the process of S4513, it is determined whether or not the transfer target image data has already been stored in the normal video RAM 236 (S4513). The determination in the process of S4513 is performed by referring to the stored image data determination flag 233i. That is, the storage state corresponding to the sprite set as the transfer target image data is read out from the storage image data determination flag 233i, and if the storage state is “ON”, the image data of the transfer target sprite is the normal video data. It is determined that the data is stored in the RAM 236, and if the storage state is “off”, it is determined that the image data of the transfer target sprite is not stored in the normal video RAM 236.

  Then, as a result of the processing in S4513, if the image data to be transferred is stored in the normal video RAM 236 (S4513: Yes), there is no need to transfer the image data from the character ROM 234 to the normal video RAM 236. Then, the normal image transfer setting process ends. As a result, unnecessary transfer of image data from the character ROM 234 to the normal video RAM 236 can be suppressed, and the processing load on each unit of the display control device 114 and the traffic on the bus line 240 can be reduced. Can be planned.

  On the other hand, as a result of the processing in S4513, if the transfer target image data is not stored in the normal video RAM 236 (S4513: No), the transfer instruction of the transfer target image data is set (S4514). Thereby, the transfer data information of the transfer target image data is included in the drawing list transmitted to the image controller 237 in the drawing processing, and the image controller 237 transmits the transfer data information described in the drawing list. Based on this, the image data of the transfer target image can be transferred from the character ROM 234 to the normal video RAM 236. The transfer data information includes the start address and the end address of the character ROM 234 storing the image data of the transfer target image, information on the transfer destination (in this case, the normal video RAM 236), and the transfer destination (here, the transfer destination). The head address of the sub area provided in the image storage area 236a of the normal video RAM 236 in which the image data of the transfer target image to be transferred is stored is included. The image controller 237 executes an image transfer process based on the transfer data information, reads out the image data designated by the transfer process from the character ROM 234, and designates the designated video RAM (here, the normal video RAM 236). To the specified address. Then, when the transfer is completed, a transfer end signal is transmitted to the MPU 231.

  After the processing in S4514, the stored image data determination flag 233i is updated (S4515), and the normal transfer setting processing ends. As described above, the stored image data determination flag 233i is updated by setting the storage state corresponding to the sprite that has become the transfer target image data to “ON”, and by setting the sub state of the image storage area 236a that is the same as the one sprite. This is performed by setting the storage state corresponding to other sprites to be stored in the area to “off”.

  As described above, by executing the normal image transfer processing, the processing corresponding to the display stop type command is executed in the previously executed command determination processing, and as a result, the display stop type command When it is determined that the indicated stop type information is the jackpot type, the image data used in the fanfare effect can be transferred from the character ROM 234 to the normal video RAM 236 without delay. If the back image is changed based on the reception of the back image change command in the previously executed command determination process, the back image of the resident video RAM 235 of the image data used in the back image is used. Image data not stored in the image area 235c can be transferred from the character ROM 234 to the normal video RAM 236 without delay.

  In the present control example, the display data table is stored in the display data table buffer 233d according to a command (for example, a display variation pattern command) transmitted from the audio ramp control device 113 based on a command or the like from the main control device 110. Is set to the transfer data table corresponding to the display data table in the transfer data table buffer 233e. Then, the MPU 231 executes the normal image transfer setting process, and sends the image data to the image controller 237 in accordance with the transfer data information described in the area indicated by the pointer 233f of the transfer data table set in the transfer data table buffer 233e. Since the transfer instruction of the transfer target image data is set, the image data of the sprite used in the display data table set in the display data table buffer 233d is surely transferred from the character ROM 234 to the normal video RAM 236 at a desired timing. Can be.

  Here, in the transfer data table, the image data of the transfer target image data is stored so that the image data corresponding to the predetermined sprite is stored in the image storage area 236a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information is defined for a predetermined address, the image data is transferred from the character ROM 234 to the image storage area 236a in accordance with the transfer data information defined in the transfer data table, and thus, the predetermined data is defined in accordance with the display data table. When rendering a sprite, image data that is not resident in the resident video RAM 235 and that is required for rendering the sprite can be stored in the image storage area 236a without fail.

  Thus, even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, an image necessary for display can be read from the character ROM 234 in advance without delay and transferred to the normal video RAM 236. The corresponding effect can be displayed on the third symbol display device 81 while drawing the image of each sprite specified in the data table. Further, by describing the transfer data table, only the non-resident image data in the resident video RAM 235 can be easily and reliably transferred from the character ROM 234 to the normal video RAM 236.

  In the transfer data table, transfer data information is defined so that image data is transferred from the character ROM 234 to the normal video RAM 236 for each image data corresponding to a sprite. Thus, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. By controlling the transfer of image data from the character ROM 234 to the normal video RAM 236 on a sprite basis, the image data transfer can be controlled in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in load on transfer.

  Next, with reference to FIG. 132 (a), details of the above-described drawing processing (S2206), which is one processing of the V interrupt processing executed by the MPU 231 of the display control device 114, will be described. FIG. 132A is a flowchart showing this drawing processing.

  In the drawing process, the types of various sprites constituting one frame determined in the task process (S2204) and parameters necessary for drawing each sprite (display position coordinates, enlargement ratio, rotation angle, translucent value, α blending information , Color information, filter designation information) and the transfer instruction set by the transfer setting process (S2205), to generate a drawing list shown in FIG. 91 (S4601). That is, in the process of S4601, the storage RAM type and the address where the image data of the sprite is stored are specified for each sprite from the types of various sprites constituting one frame determined in the task process (S2204). The parameters necessary for the sprite determined in the task processing are associated with the specified storage RAM type and address. Then, the sprites are rearranged in the order of the sprite to be arranged from the rearmost side to the front side in the image of one frame, and the details of the sprites are arranged in the order of the rearranged sprites. A drawing list is generated by describing the type and address of a storage RAM in which image data of the sprite is stored as detailed drawing information (detailed information) and parameters necessary for drawing the sprite. If a transfer instruction is set by the transfer setting process (S2205), the leading address (storage source top address) of the character ROM 234 where transfer target image data is stored as transfer data information at the end of the drawing list. And the last address (storage source final address) and the start address of the transfer destination (normal video RAM 236).

  As described above, for each sprite, the area of the resident video RAM 235 where the image data of the sprite is stored, or the sub-area of the image storage area 236a of the normal video RAM 236 is fixed, so that the MPU 231 According to the sprite type, the storage RAM type and the address where the image data of the sprite is stored can be immediately specified, and the information can be easily included in the detailed information of the drawing list.

  When the drawing list is generated, the generated drawing list and the drawing target buffer information specified by the drawing target buffer flag 233j are transmitted to the image controller (S4602). Here, when the drawing target buffer flag 233j is 0, the drawing target buffer flag 233j is 1 including information for instructing to develop the image drawn in the first frame buffer 236b as the drawing target buffer information. Includes information instructing to develop an image drawn in the second frame buffer 236c as drawing target buffer information.

  Based on the drawing list received from the MPU 231, the image controller 237 draws images in order from the sprite described at the head of the drawing list, and develops the images by overwriting the frame buffer specified by the drawing target buffer information. Thereby, in the image of one frame generated by the drawing list, the sprite drawn first can be arranged at the rearmost side, and the sprite drawn last can be arranged at the frontmost side.

  When transfer data information is included in the drawing list, the transfer data information is used to determine the start address (storage source start address) and the end address (storage source end address) of the character ROM 234 in which transfer target image data is stored. ) And the head address of the transfer destination (normal video RAM 236) is extracted, and the image data stored from the storage source start address to the storage source end address is sequentially read from the character ROM 234 and temporarily stored in the buffer RAM 237a. After that, when the normal video RAM 236 is in an unused state, the image data stored in the buffer RAM 237a is sequentially transferred to the area indicated by the transfer destination start address of the normal video RAM 236. Then, the image data stored in the normal video RAM 236 is used based on the drawing list transmitted from the MPU 231 thereafter, and the image is drawn according to the drawing list.

  Note that the image controller 237 reads out image information of the previously developed image from a frame buffer different from the frame buffer indicated by the drawing target buffer information, and stores the image information together with the drive signal in the third symbol display device 81. Send to This allows the third symbol display device 81 to display the image developed in the frame buffer. In addition, the image drawn from one frame buffer can be displayed on the third symbol display 81 while the image drawn in one frame buffer is expanded, so that the drawing process and the display process can be performed simultaneously and in parallel. Can be.

  In the drawing process, after the process of S4602, the drawing target buffer flag 233j is updated (S4603). Then, the drawing process ends, and the process returns to the V interrupt process. The drawing target buffer flag 233j is updated by inverting its value, that is, by setting it to “1” when the value is “0” and by setting it to “0” when it is “1”. Done. Thus, the drawing target buffer is alternately set between the first frame buffer 236b and the second frame buffer 236c every time the drawing list is transmitted.

  Here, the transmission of the drawing list is performed by the MPU 231 based on the V interrupt signal transmitted from the image controller 237 every 20 milliseconds when the drawing process and the display process of the image for one frame are completed. It is performed every time the drawing process of the embedding process (see FIG. 112B) is executed. As a result, at a certain timing, the first frame buffer 236b is specified as a frame buffer for developing an image of one frame, and the second frame buffer 236c is specified as a frame buffer from which image information of one frame is read. Is performed, the second frame buffer 236c is designated as a frame buffer for developing the image of one frame 20 ms after the completion of the rendering process of the image of one frame, The first frame buffer 236b is designated as the frame buffer from which the image information of the minute is read. Therefore, the image information of the image previously developed in the first frame buffer 236b can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the second frame buffer 236c. .

  Then, after the next 20 milliseconds, the first frame buffer 236b is designated as a frame buffer for developing an image of one frame, and the second frame buffer 236c is designated as a frame buffer from which image information of one frame is read. Is done. Therefore, the image information of the image previously developed in the second frame buffer 236c can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the first frame buffer 236b. . Thereafter, the frame buffer for expanding the image for one frame and the frame buffer from which the image information for one frame is read out are changed to one of the first frame buffer 236b and the second frame buffer 236c every 20 milliseconds. By alternately designating, one frame of image display processing can be continuously performed in units of 20 milliseconds while one frame of image drawing processing is being performed.

  Next, with reference to FIG. 132 (b), details of the above-described counter update processing (S2207), which is one processing of the V interrupt processing executed by the MPU 231 of the display control device 114, will be described. FIG. 132 (b) is a flowchart showing the counter updating process.

  In the counter updating process, first, the display effect counter 233o is updated (S4701). Next, an update process of various counters provided in the display control device 114 is executed (S4702), and this process ends.

<Modification of First Embodiment>
Next, a modification of the first embodiment will be described with reference to FIGS. 133 to 137. In the modification of the first embodiment, a rescue timing is provided during the super-reach B effect period. If the frame button 22 is not pressed during the effect of Super Reach B and this rescue timing has elapsed, a rescue effect is executed. Here, as described above, the super reach B is an effect in which a large hit is notified by pressing the frame button 22 a plurality of times. Therefore, if the period during which the frame button 22 can be input is reduced, there may be cases where the pressing of the frame button 22 cannot be completed in time. However, in the present modified example, when the inputtable period of the frame button 22 is reduced (after the rescue timing has elapsed), the rescue effect is executed, and the press of the frame button 22 necessary for notifying the big hit is performed. The number of times decreases. As a result, the above-described problem can be avoided.

  With reference to FIG. 133, a description will be given of the timing at which the effect of Super Reach B is executed in the present modification. FIG. 133 is a schematic diagram schematically showing the execution timing of the super reach B effect.

  First, referring to FIG. 133 (a), the frame button 22 is not pressed until the first rescue timing and the second rescue timing elapse during the production of the super reach B, and thereafter, the frame button 22 is stopped during the stoppable period. The case where the stop display effect is executed by pressing the button 22 will be described.

  When the reach effect of Super Reach B (reach with the symbol of 7) is started, a screen in which the girl character in the center of the screen holds the symbol of 4 is displayed, as in the first embodiment described above. (See FIG. 77 (a)). In this state, when the frame button 22 is not pressed and the first rescue timing elapses, a rescue effect is executed, and the screen in which the character holds the symbol 5 and the symbol 5 as shown in FIG. Is changed to Similarly, when the frame button 22 is not pressed and the second rescue timing has elapsed, the rescue effect is executed again, and the character is a symbol of 4, a symbol of 5, and a symbol of 6 as shown in FIG. Will be changed to the screen holding the hand.

  In this state, when the frame button 22 is pressed during the stoppable period, an effect of throwing a symbol of 4, a symbol of 5, and a symbol of 6 is executed, and an effect of notifying a big hit is executed. As described above, in the present modification, the remaining number of effective effects required for the notification of the jackpot is reduced every time the rescue timing elapses. Thereby, in the reach effect, even if the player notices the pressing of the frame button 22 late, the number of times the necessary frame button 22 is pressed is reduced, so that the frame button 22 is pressed in time for the jackpot notification. Pressing can be performed.

  In addition, although the depression of the frame button 22 has been executed, the rescue effect is executed in the same manner as described above even when the rescue timing has elapsed without the effective effect. Thus, even if the throwing effect, which is an effective effect, is not displayed even though the frame button 22 is pressed, the effect proceeds at the rescue timing. As a result, it is possible to prevent the effect from proceeding even though the frame button 22 is pressed, and reduce complaints from the player.

  FIG. 133 (b) is a diagram showing the timing when the frame button 22 is pressed before the elapse of each of the above-described rescue timings. If the frame button 22 is pressed before the first rescue timing elapses and an effective effect is executed, the rescue effect is not executed even after the first rescue timing has elapsed, and the same applies to the second rescue timing.

  Next, details of the contents of the data table storage area 233b in the modification of the first control example will be described with reference to FIG. 135. FIG. 135 is a schematic diagram schematically showing the contents of the data table storage area 233b in this modification. The only difference between the data table storage area 233b and the first control example is that various display data tables for rescue display are provided in the fluctuating effect table storage area. Since they are the same, a detailed description thereof will be omitted.

  Each of the display data tables for rescue display stores the display data for rescue effects as shown in FIGS. 134 (a) and 134 (b) described above. The display data for the rescue effect is stored in the data table storage area 223b by the process of S2003 of the boot process (see FIG. 111) of the display control device 114, similarly to other display data tables. Then, in a display super reach B process (see FIG. 137) described later, when a rescue command is received, a rescue display display data table is set in the display data table buffer 233d.

  Next, the super reach B operation process (S1510) executed by the MPU 221 of the audio lamp control device 113 will be described with reference to FIG. FIG. 136 is a flowchart showing the super reach B operation process (S1510). The super reach B operation process (S1510) in the present modified example includes the first control example described above, determination whether the rescue timing has passed (S1830), and a rescue command for display when the rescue timing has passed. The difference is in the part to be set (S1831), and the other processing is the same, so that the detailed description is omitted.

  Specifically, in the process of S1803, if it is determined that the frame button 22 has not been pressed (S1803: No), it is determined whether the rescue timing corresponding to the remaining number of valid presses has elapsed (S1830). ). For example, as shown in FIG. 133 (a), in the case where the effective effect has never been executed (the number of remaining effective presses is three), the case where the first relief timing has elapsed corresponds to the case. In addition, when the first relief timing has elapsed and the relief effect has been performed once (the number of remaining effective pressings is two), the case where the second relief timing has elapsed corresponds to the case.

  In the processing of S1830, if it is determined that the rescue timing has not elapsed, the processing ends. On the other hand, if not, a display rescue command is set based on the elapsed timing (S1831). For example, if the first rescue timing has passed, a command for executing an effect with two symbols is set as shown in FIG. 134 (a), and if the second rescue timing has passed as shown in FIG. ), A command for executing an effect with three symbols is set. The rescue command set here is transmitted to the display control device 114, and the display of the rescue effect is performed by the display super reach B process (see FIG. 137) of the display control device 114 that has received the command. Become.

  Next, the display super reach B process executed by the MPU 231 of the display control device 114 will be described with reference to FIG. FIG. 137 is a flowchart showing the display super reach B process (S2704). The display super reach B process (S2704) in this modified example includes the above-described first control example, determination as to whether there is a rescue command (S2830), and displaying a rescue display display data table when a rescue command is present. The processing (S2831) for setting in the data table buffer 233d is different, and the other processing is the same, so that the detailed description is omitted.

  Specifically, when it is determined that there is no replacement command in the process of S2807 (S2807: No), it is determined whether there is a rescue command (S2830). If it is determined in step S2830 that there is no rescue command, the process ends.

  On the other hand, if it is determined in step S2830 that there is a rescue command, the rescue display data table is set in the display data table buffer 233d, and the process ends.

  As a result, a relief effect is executed based on the elapse of the relief timing. As a result, even if the period during which the frame button 22 can be input is reduced, a case where the pressing of the frame button 22 cannot be pushed in time can be relieved by executing the rescue effect.

  Hereinafter, the concept of various inventions included in the above-described embodiment in addition to the gaming machine of the present invention will be described.

  Effect executing means for executing a predetermined effect based on establishment of a start condition, display means for displaying an effect mode of the predetermined effect executed by the effect executing means, and operating means operable by a player And identification means for identifying a signal output by operating the operation means, and identification means for determining whether a specific condition is satisfied when a specific identification result is identified by the identification means. When the determination means determines that the specific condition is satisfied, the effect mode executed by the effect execution means based on the next established start condition is changed to a specific effect mode until a predetermined condition is satisfied. A gaming machine A1 comprising: an effect variable setting means for setting the variable.

  According to the gaming machine A1, an effect executing means for executing a predetermined effect based on establishment of a start condition, a display means for displaying an effect mode of the predetermined effect executed by the effect executing means, Means that can be operated by a person, identification means for identifying a signal output by operating the operation means, and a specific condition is satisfied when a specific identification result is identified by the identification means. Determination means for determining whether or not a specific condition is satisfied by the determination means. And effect variable setting means for setting the variable to a specific effect mode until the effect is changed. Therefore, when the specific condition is satisfied, the effect mode executed by the effect executing means can be changed to the specific effect mode based on the operation of the player, thereby improving the interest of the player. be able to.

  In the gaming machine A1, a back display means for displaying a back display mode displayed on the back side of the predetermined effect displayed on the display means, and the back display mode is determined based on a result of identification by the identification means. A gaming machine A2, comprising: scroll display means for scrolling display in the direction of. The specific condition is satisfied when a specific back symbol is displayed in the back display mode.

  According to the gaming machine A2, in addition to the effect of the gaming machine A1, the back display means for displaying the back display mode displayed on the back side of the predetermined effect displayed on the display means, and the identification by the identification means. Scroll display means for scrolling the rear display mode in a predetermined direction based on the result, wherein the specific condition is satisfied when a specific rear symbol is displayed in the rear display mode. is there. Therefore, the back display mode can be scroll-displayed based on the operation of the player. As a result, the interest of the player can be improved.

  In the gaming machine A2, the rear display means normally scrolls and displays the rear display mode in a predetermined direction, and when the predetermined identification result is determined by the identification means, A gaming machine A3 wherein the scroll display in the predetermined direction is changed to a scroll display in a direction based on the identification result.

  According to the gaming machine A3, in addition to the effect provided by the gaming machine A2, the back display means normally scrolls and displays the back display mode in a predetermined direction, and displays the identification means. When the predetermined identification result is determined, the scroll display in the predetermined direction is changed to the scroll display in the direction based on the identification result. Therefore, the scroll display is performed in a predetermined direction based on the operation of the player, and the operation may be performed again when the direction of the scroll display is changed. As a result, the burden on the player for executing the scroll display can be reduced.

  In any one of the gaming machines A1 to A3, the operation unit includes a plurality of operation units, and the plurality of operations includes a direction operation unit that instructs a scroll direction of the rear display mode, the specific identification result, A gaming machine A4 comprising at least an identified specific operation unit.

  According to the gaming machine A4, in addition to the effect provided by any one of the gaming machines A1 to A1, the operation means is constituted by a plurality of operation sections, and the plurality of operations instructs a scroll direction of the rear display mode. It comprises at least a direction operation unit and a specific operation unit identified as the specific identification result. Therefore, the scroll direction can be changed by operating the direction operation unit, and the effect can be changed by operating the specific operation unit. As a result, a gaming machine that is easy for the player to understand can be provided.

  Effect executing means for executing an effect of a game, display means for displaying an effect mode executed by the effect executing means, and effect mode selection for selecting an effect mode executed by the effect executing means from a plurality of effect modes A game machine having operating means that can be operated by a player, and operating the operating means each time a predetermined condition is satisfied, as an effect mode selected by the effect mode selecting means. A route effect mode in which the effect mode is changed by the player selecting one route from a plurality of routes is set, and when the route effect mode is executed, the route effect mode is executed in the previously executed route effect mode. A gaming machine B1 having auxiliary means for assisting in selecting a route other than the selected route.

  According to the gaming machine B1, an effect executing means for executing an effect of a game, a display means for displaying an effect mode executed by the effect executing means, and a plurality of effect modes for the effect mode executed by the effect executing means. And a production mode selection means for selecting from the modes, wherein the production mode has an operation means operable by a player, and the production mode selected by the production mode selection means is defined as: A route effect mode in which the effect mode is changed by the player selecting one route from a plurality of routes by operating the operation means is set, and when the route effect mode is executed, the route effect mode is previously executed. Auxiliary means for assisting in selecting a route other than the route selected in the route effect mode. This assists the player to select a route other than the previously selected route when selecting a route in the route effect mode. As a result, the operation load on the player when selecting a route other than the previously selected route can be reduced.

  In the gaming machine B1, a determination unit for performing a determination based on the satisfaction of a determination condition, a dynamic display unit for dynamically displaying identification information indicating determination information by the determination unit on the display unit, When the identification information indicating the specific determination information is displayed, in a gaming machine having privilege game execution means for executing a privilege game that is advantageous to the player, A gaming machine B2 for selecting the route effect mode based on execution of a bonus game by means.

  According to the gaming machine B2, in addition to the effect played by the gaming machine B1, a determining means for executing a determination based on the satisfaction of a determination condition and identification information indicating the determination information by the determining means are dynamically displayed on the display means. In the gaming machine having a dynamic display means and a bonus game execution means for executing a bonus game advantageous to the player when the identification information indicating the specific determination information is displayed on the display means, The effect mode selection means selects the route effect mode based on execution of a bonus game by the bonus game execution means. Therefore, the player can select the route effect mode during execution of the bonus game. As a result, the interest of the player during the execution of the privilege game can be improved.

  The gaming machine B3, wherein in the gaming machine B2, the effect executing means causes the display means to display the route effect mode selected by the effect mode selecting means during execution of the privilege game.

  According to the gaming machine B3, in addition to the effect played by the gaming machine B2, the effect executing means displays the route effect mode selected by the effect mode selecting means on the display means during execution of the privilege game. It is. Therefore, during execution of the bonus game, the route effect mode based on the operation of the player is displayed. As a result, the interest of the player during the execution of the privilege game can be improved.

  In any of the gaming machines B1 to B3, the route effect mode is such that a plurality of set squares are set on the route, and the set squares are set to the set squares by passing the set squares or stopping at the set squares. A gaming machine B4 having a route privilege granting means for granting a privilege that has been set.

  According to the gaming machine B4, in addition to the effects played by the gaming machines B1 to B3, in the route effect mode, a plurality of set squares are set on the route, and the set squares pass or stop at the set squares. Thus, a route privilege granting means for granting the privilege set in the set cell is provided. Therefore, when the route effect mode is displayed, it is possible to make the player expect that the privilege is given. As a result, the interest of the player can be improved.

  In the gaming machine B4, the route privilege granting means sets a privilege to be assisted by the assisting means so that the route privilege granting means can be started from the start of the next privilege game from the set cell passed or stopped as the privilege. A gaming machine B5, characterized in that:

  According to the gaming machine B5, in addition to the effect played by the gaming machine B4, the route privilege providing means can be started from the start of the next privilege game from the set cell passed or stopped as the privilege. The privilege to be assisted by the assisting means is set. Therefore, at the start of the next privilege game, the player can start from the set cell that has passed or stopped in the previous privilege game. As a result, it is possible to give the player an impression as if it were an effect continued from the previous privilege game, and it is possible to improve the interest of the player.

  Lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display means capable of dynamically displaying the identification information; And a bonus granting means for granting a privilege advantageous to a player when the lottery result by the lottery means is displayed with the identification information indicating that the lottery result is a specific lottery result. The information is configured by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained, and the dynamic display means And displaying a reach display mode in which one of the plurality of symbol rows is displayed in a state where one symbol row is dynamically displayed, and sets and displays a plurality of specific symbols as a combination indicating the specific lottery result. Also And a symbol changing means for changing the specific symbol of the symbol row dynamically displayed in the reach display mode to a specific display mode, and a specific variable changed by the symbol variable section based on establishment of a predetermined condition. A gaming machine C1 comprising: re-variable means for varying a symbol to an original display mode.

  According to the gaming machine C1, lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display of the identification information can be provided. Possible dynamic display means, and privilege providing means for providing a benefit advantageous to the player when the lottery result by the lottery means is displayed with the identification information indicating a specific lottery result. In the gaming machine, the identification information is constituted by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained. , The dynamic display means displays a reach display mode in which one of the plurality of symbol rows is displayed in a dynamically displayed state, and a specific symbol which is a combination indicating the specific lottery result Duplicate A symbol changing means for changing the specific symbol of the symbol row dynamically displayed in the reach display mode to a specific display mode, and changing the symbol based on establishment of a predetermined condition. Re-variable means for varying the specific symbol changed by the means to the original display mode. Therefore, even when there are a plurality of specific symbols that result in a specific lottery during the display of the reach display mode, the specific symbols are changed to the specific display mode by the symbol variable unit. Here, the specific symbol changed to the specific display mode is changed to the original display mode by the re-variable unit. As a result, during the display of the reach display mode in which there are a plurality of specific symbols serving as specific lottery results, the player need only pay attention to the specific display mode. Therefore, it is possible to provide a gaming machine that is easy for the player to understand.

  In the gaming machine C1, the player has operation means that can be operated by the player, and the dynamic display means dynamically displays the specific symbol changed by the symbol variable means and the symbols other than the specific symbol in the reach display mode. And a stop display means for stopping the dynamic display of the symbol row dynamically displayed in the reach display mode based on the operation of the operation means. Gaming machine C2.

  According to the gaming machine C2, in addition to the effect played by the gaming machine C1, the game machine C2 has operating means operable by the player, and the dynamic display means is configured to be the specific display variable by the symbol variable means in the reach display mode. A dynamic display of a symbol and a symbol other than the specific symbol is performed, and based on the operation of the operation means, the dynamic display of the symbol row dynamically displayed in the reach display mode is stopped and displayed. It has stop display means. Therefore, even when there are a plurality of specific symbols that result in a specific lottery during the display of the reach display mode, the specific symbols are changed to the specific display mode by the symbol variable unit. As a result, the player may perform an operation while paying attention to the changed specific display mode. Therefore, it is possible to provide a gaming machine that is easy for the player to understand.

  In the gaming machine C2, when the lottery result by the lottery means is a specific lottery result, the stop display means displays one of the specific symbols in the reach display mode at a timing when the operation means is operated. The gaming machine C3, wherein the stop display is performed so that the stop display is performed at a position where the display can be performed in combination with the symbol that is stopped and displayed in the above.

  According to the gaming machine C3, in addition to the effect of the gaming machine C2, when the lottery result by the lottery means is a specific lottery result, the stop display means sets the timing at which the operation means is operated. The stop display is performed so that one of the specific symbols is displayed at a position where it can be displayed in combination with the symbol that is stopped and displayed in the reach display mode. Therefore, the symbols which are stopped and displayed based on the operation of the player and which have been re-changed to the original display mode by the re-change means are displayed in combination with the symbols stopped in the reach display mode. As a result, the player can easily recognize whether or not the stopped and displayed symbol is a specific lottery result. Therefore, it is possible to provide a gaming machine that is easy for the player to understand.

  In the gaming machines C1 to C3, the reach display mode is configured to be a display mode in which two or more symbol columns are stopped and displayed with the same symbol and one symbol column is dynamically displayed. Gaming machine C4.

  According to the gaming machine C4, in addition to the effect provided by any one of the gaming machines C1 to C3, the reach display mode causes two or more symbol columns to be stopped and displayed with the same symbol, and one symbol column to be dynamically displayed. It is configured in a display mode. Therefore, the interest of the player can be improved.

  In any one of the gaming machines C1 to C4, the symbol changing means is configured to change and display the plurality of specific symbols in the specific display mode, which is the same display mode, and display the symbols. .

  According to the gaming machine C5, in addition to the effect provided by any of the gaming machines C1 to C4, the symbol variable means causes the plurality of specific symbols to be changed and displayed in the specific display mode that is the same display mode. Things. Therefore, even when there are a plurality of specific symbols that result in a specific lottery during the display of the reach display mode, the specific symbols are changed to the same specific display mode by the symbol variable unit. As a result, the player only needs to pay attention to one specific display mode during the display of the reach display mode in which there are a plurality of specific symbols serving as specific lottery results. Therefore, it is possible to provide a gaming machine that is easy for the player to understand.

  Lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display means capable of dynamically displaying the identification information; And a bonus granting means for granting a privilege advantageous to a player when the lottery result by the lottery means is displayed with the identification information indicating that the lottery result is a specific lottery result. The information is configured by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained, and the dynamic display means Displaying the one symbol row of the plurality of symbol rows in a dynamically displayed state in a reach display mode, and setting and displaying a specific symbol which is a combination indicating the specific lottery result. so Operating means that can be operated by a player, and the dynamic display is performed based on the operation of the operating means when the identification information is displayed in the reach display mode by the dynamic display means. Symbol varying means for varying the symbol of the symbol row being displayed, determining means for determining the remaining period of the period displayed in the reach display mode, and within the period determined by the determining means, the symbols are changed by the symbol varying means. The symbol variable determining means for determining whether or not the specific symbol can be changed, and when the symbol variable determining means determines that the specific symbol cannot be changed, the specific symbol is displayed in the remaining period of the reach display mode. A gaming machine D1 comprising: a special effect setting means for setting a specific effect to be displayed.

  According to the gaming machine D1, the lottery means for executing the lottery based on the establishment of the lottery condition, the display means for displaying the identification information indicating the lottery result by the lottery means, and the identification information can be dynamically displayed. Possible dynamic display means, and privilege providing means for providing a benefit advantageous to the player when the lottery result by the lottery means is displayed with the identification information indicating a specific lottery result. In the gaming machine, the identification information is constituted by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained. The dynamic display means displays a specific symbol row in a state of dynamically displaying one of the plurality of symbol rows in a reach display mode, so that the specific symbol is a combination indicating the specific lottery result. Set Operating means that can be operated by a player; and that the operating means is operated when the identification information is displayed in the reach display mode by the dynamic display means. A symbol varying means for varying the symbol of the symbol row dynamically displayed, a determining means for determining the remaining period of the period displayed in the reach display mode, and Symbol variable determining means for determining whether the symbol can be changed to the specific symbol by the symbol variable means, and when the symbol variable determining means determines that the specific symbol cannot be changed, the remaining period of the reach display mode And a specific effect setting means for setting a specific effect for displaying the specific symbol. Therefore, during execution of the reach display, the symbol can be changed to the specific symbol based on the operation of the player. Here, when the symbol cannot be changed based on the operation of the player during the remaining time of the reach display being executed, a specific effect for displaying the specific symbol is set. Thereby, even when there is no or little operation by the player, a specific symbol that is a combination indicating a specific lottery result can be set and displayed. As a result, in the execution of the reach display, even when there is no or little operation by the player, a specific symbol can be displayed to indicate that a specific lottery result has been obtained.

  In the gaming machine D1, in the specific effect, after the symbol row dynamically displayed in the reach display mode is stopped and displayed with a symbol different from the specific symbol, the stopped symbol is replaced with the specific symbol. A gaming machine D2 comprising an effect to be displayed.

  According to the gaming machine D2, in addition to the effect played by the gaming machine D1, the specific effect is to stop and display the symbol row dynamically displayed in the reach display mode with a symbol different from the specific symbol, This is an effect of replacing the stopped and displayed symbol with a specific symbol and displaying it. Therefore, when the symbol cannot be changed based on the operation of the player because there is no or little operation by the player, first, the symbol is stopped and displayed with a symbol different from the specific symbol. After that, the stopped and displayed symbol is replaced with a specific symbol. Thereby, even when there is no or little operation by the player, it is possible to execute an effect with less discomfort.

  In the gaming machine D1 or D2, when the lottery result by the lottery means is different from the specific lottery result, the symbol of the symbol row dynamically displayed in the reach display mode is specified regardless of the operation of the operation means. A gaming machine D3 having a prohibiting means for prohibiting changing to a symbol.

  According to the gaming machine D3, in addition to the effect played by the gaming machine D1 or D2, when the lottery result by the lottery means is different from the specific lottery result, the symbol of the symbol row dynamically displayed in the reach display mode is displayed. A prohibition unit for prohibiting changing to the specific symbol regardless of an operation of the operation unit. Therefore, it is possible to prevent a specific symbol indicating a specific lottery result from being displayed even though the lottery result is not the specific lottery result.

  Lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display means capable of dynamically displaying the identification information; And a bonus granting means for granting a privilege advantageous to a player when the lottery result by the lottery means is displayed with the identification information indicating that the lottery result is a specific lottery result. The information is configured by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained, and the dynamic display means Displaying the one symbol row of the plurality of symbol rows in a dynamically displayed state in a reach display mode, and setting and displaying a specific symbol which is a combination indicating the specific lottery result. so Operating means that can be operated by a player, and the dynamic display is performed based on the operation of the operating means when the identification information is displayed in the reach display mode by the dynamic display means. Symbol changing means for changing the symbol of the symbol row to a different symbol in a predetermined order, a determining means for determining the remaining period of the period displayed in the reach display mode, and a period determined by the determining means, A symbol variable determining unit that determines whether the symbol can be changed to the specific symbol by the symbol variable unit; and if the symbol variable determining unit determines that the symbol cannot be changed to the specific symbol, the symbol is determined in the remaining period. A gaming machine D4 having special symbol changing means for changing the symbol in an order in which the symbol can be changed.

  According to the gaming machine D4, lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display of the identification information can be provided. Possible dynamic display means, and privilege providing means for providing a benefit advantageous to the player when the lottery result by the lottery means is displayed with the identification information indicating a specific lottery result. In the gaming machine, the identification information is constituted by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained. , The dynamic display means displays a specific symbol row of the plurality of symbol rows in a dynamically displayed state in a reach display mode, and displays a specific symbol indicating a specific lottery result. Set Operating means that can be operated by a player; and that the operating means is operated when the identification information is displayed in the reach display mode by the dynamic display means. A symbol changing means for changing the symbols of the dynamically displayed symbol row to different symbols in a predetermined order, a discriminating means for discriminating a remaining period of a period displayed in a reach display mode, and discriminating by the discriminating means. Within the period to be performed, a symbol variable determining means for determining whether the symbol can be changed to the specific symbol by the symbol variable means, when it is determined that the specific symbol is not variable by the symbol variable determining means, Special symbol changing means for changing the symbol in an order that can be changed to the specific symbol in the remaining period. Therefore, during execution of the reach display, the symbol can be changed to the specific symbol based on the operation of the player. Here, if the symbol cannot be changed based on the operation of the player during the remaining time of the reach display being executed, the symbols are changed in the order in which the symbols can be changed to the specific symbols during the remaining period. Thereby, even if the start of the operation by the player is delayed, the symbol can be changed to the specific symbol based on the operation of the player.

  In the gaming machine D4, the special symbol changing means is configured to change and display the symbols in an order in which symbols to be changed in a plurality of orders among the predetermined order changed by the symbol changing means are combined. A gaming machine D5.

  According to the gaming machine D5, in addition to the effect played by the gaming machine D4, the special symbol variable unit combines symbols to be changed in a plurality of orders among the predetermined order changed by the symbol variable unit. The symbols are variably displayed in order. Therefore, even if the start of the operation by the player is delayed, the player can easily recognize that the symbol can be changed to the specific symbol based on the operation of the player.

  In addition, as a member protruded from the board surface, a nail, a windmill, a through gate, and the like are exemplified.

  In any one of the gaming machines A1 to A5, B1 to B6, C1 to C6, D1 to D8, and E1 to E15, the gaming machine is a slot machine. Above all, the basic configuration of the slot machine is as follows: "variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information is provided. The dynamic display of the identification information is started, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (stop button) or after a predetermined time elapses. And a special game state generating means for generating a special game state advantageous to the player on condition that the confirmed identification information is the specific identification information. In this case, coins and medals are typical examples of the game medium.

  In any of the gaming machines A1 to A5, B1 to B6, C1 to C6, D1 to D8, and E1 to E15, the gaming machine F2 is a pachinko gaming machine. Among them, as a basic configuration of a pachinko gaming machine, an operation handle is provided, and a ball is fired to a predetermined game area in accordance with the operation of the operation handle, and the ball is provided in an operation port arranged at a predetermined position in the game area. The requirement for winning (or passing through the operating port) is that the identification information dynamically displayed on the display means is fixedly stopped after a predetermined time. In addition, when a special game state occurs, a variable winning device (specific winning opening) disposed at a predetermined position in the game area is opened in a predetermined mode so that balls can be won, and a value corresponding to the winning number is obtained. A value (including data written on a magnetic card as well as a prize ball) is given.

  In any of the gaming machines A1 to A5, B1 to B6, C1 to C6, D1 to D8, and E1 to E15, the gaming machine is a combination of a pachinko gaming machine and a slot machine. Machine F3. Among them, the basic configuration of the integrated gaming machine is as follows: "variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information, and starting operation means (for example, an operation lever) The change of the identification information is started due to the operation of, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (for example, the stop button) or after a predetermined time elapses. A special game state generating means for generating a special game state advantageous to the player on condition that the fixed identification information at the time of stop is specific identification information, and using a ball as a game medium, , A predetermined number of balls are required at the start of the dynamic display, and a large number of balls are paid out when a special game state occurs.

22 frame button (part of operation means)
270 Selection switch (part of operation means)
270a Upper switch (part of operating means)
270b Right switch (part of operation means)
270c Lower switch (part of operating means)
270d Left switch (part of operation means)
270e decision switch (part of operating means)
81 3rd symbol display device (display means)
114 display control device (effect execution means)
S2202 production mode selection means S3001 auxiliary means

  The present invention relates to a gaming machine such as a pachinko machine.

In the gaming machine of the pachinko machine or the like, in Starring unloading, effect images is a game machine which is displayed on the basis of the button operation (Patent Document 1).

JP 2009-066141 A

However, in the above-described conventional gaming machines, there is a demand for further enhancing the interest in the game with respect to the effect based on the button operation .

SUMMARY An advantage of some aspects of the invention is to provide a gaming machine that can enhance the interest in a game with respect to an effect based on a button operation .

In order to achieve this object, the gaming machine according to claim 1 includes a lottery means for executing a lottery based on establishment of a lottery condition, and a display means for displaying identification information for indicating a lottery result by the lottery means. Dynamic display means capable of dynamically displaying the identification information on the display means, and when the lottery result by the lottery means is displayed with the identification information for indicating that it is a specific lottery result, And a privilege granting means capable of granting a privilege that is advantageous to the player, wherein the identification information is composed of a plurality of symbol rows and is displayed in a combination of specific symbols, whereby the lottery is performed. The dynamic display means is configured to indicate that the lottery result by the means is the specific lottery result, and the dynamic display means indicates the specific lottery result except for one symbol row among the plurality of symbol rows. And a combination for The identification information is displayed in the reach display mode by the operating means operable by the player and the dynamic display means, When a symbol that is a combination other than the specific symbol combination is displayed in the first symbol row, the symbol displayed in the first symbol row is based on the operation of the operating means. Is a symbol display means capable of displaying different symbols, a determination means for determining the remaining period of the period in which the identification information is dynamically displayed, and the remaining period determined by the determination means is less than a specific period In certain cases, the apparatus further comprises a specific effect setting means capable of setting a specific effect for displaying a specific symbol that is a combination of the specific symbol during the remaining period.

According to the gaming machine of claim 1, a lottery means for executing a lottery based on the establishment of the lottery condition, a display means for displaying identification information for indicating a lottery result by the lottery means, Dynamic display means capable of dynamically displaying on the display means, and when the lottery result by the lottery means is displayed with the identification information for indicating that the lottery result is a specific lottery result, it is advantageous to the player. And a privilege granting means capable of granting a special privilege, wherein the identification information is composed of a plurality of symbol rows and is displayed in a combination of specific symbols, so that a lottery result by the lottery means can be obtained. The dynamic display means is configured to indicate the specific lottery result, and the dynamic display means is a combination for indicating the specific lottery result except for one symbol row among the plurality of symbol rows. Possible The identification information is displayed in the reach display mode by the operating means operable by the player and the dynamic display means, and the gaming machine is displayed in the first symbol row. When a symbol that is a combination other than the specific symbol combination is displayed, a symbol different from the symbol displayed in the one symbol row is displayed based on the operation of the operation unit. Symbol display means capable of causing the identification information to be dynamically displayed, a determination means for determining a remaining period of the period in which the identification information is dynamically displayed, and when the remaining period determined by the determination means is equal to or shorter than a specific period, In the remaining period, there is provided a specific effect setting means capable of setting a specific effect for displaying a specific symbol that is a combination of the specific symbol. There is an effect that it is possible to improve the interest in the game with respect to output.

It is a front view of the pachinko machine in 1st Embodiment. It is a front view of the game board of a pachinko machine. It is a rear view of a pachinko machine. FIG. 2 is a block diagram illustrating an electrical configuration of the pachinko machine. It is a front perspective view of an operation unit. It is the exploded front perspective view of the operation unit which looked at the operation unit which disassembled from the front. It is a front view of an operation unit. It is a front view of an operation unit. It is a front view of an operation unit. It is a front exploded perspective view of a game board and a board lower unit. It is a front exploded perspective view of a game board and a board lower unit. It is a rear exploded perspective view of a game board and a board lower unit. It is a front exploded perspective view of a variable winning device. It is a rear exploded perspective view of the variable winning device. (A) is a top view of the variable winning device, (b) is a front view of the variable winning device, and (c) is a side view of the variable winning device as viewed in the direction of the arrow XVc in FIG. 15 (b). is there. 15A is a cross-sectional view of the variable prize winning device taken along the line XVIa-XVIa in FIG. 15B, and FIG. It is sectional drawing. (A) and (b) are partial front views of the game board. 17A is a cross-sectional view of the lower panel unit taken along line XVIIIa-XVIIIa in FIG. 17B, and FIG. 17B is a cross-sectional view of the lower panel unit taken along line XVIIIb-XVIIIb in FIG. FIG. 18C is a cross-sectional view of the lower panel unit in which the arrangement of the light irradiation unit is virtually changed from FIG. It is a front perspective view of a compound operation unit. It is a rear perspective view of a compound operation unit. It is a front exploded perspective view of a compound operation unit. It is a rear exploded perspective view of a compound operation unit. It is a front exploded perspective view of a main body member, a shielding member, and a swing member. FIG. 4 is an exploded rear perspective view of a main body member, a shielding member, and a swing member. (A) is a front view of the first guide arm, (b) is a bottom view of the first guide arm, and (c) is a first guide arm along line XXVc-XXVc in FIG. 25 (a). FIG. 25D is a cross-sectional view of the first guide arm taken along line XXVd-XXVd in FIG. 25A. 26A is a front view of the second guide arm, FIG. 26B is a bottom view of the second guide arm, and FIG. 26C is a second guide arm along line XXVIc-XXVIc in FIG. FIG. 26D is a cross-sectional view of the second guide arm taken along line XXVId-XXVId in FIG. 26A. (A) And (b) is a front view of a 1st guide arm, a 2nd guide arm, and wiring. It is a front view of a compound operation unit. It is a rear view of a compound operation unit. It is a front view of a compound operation unit. It is a rear view of a compound operation unit. It is a front view of a compound operation unit. It is a rear view of a compound operation unit. FIG. 30 is a partial cross-sectional view of the composite operation unit taken along the line XXXIV-XXXIV in FIG. 28. FIG. 33 is a partial cross-sectional view of the composite operation unit taken along the line XXXV-XXXV in FIG. 32. It is a front view of a compound operation unit. FIG. 37 is a partial cross-sectional view of the composite operation unit taken along the line XXXVII-XXXVII in FIG. 36. It is a front perspective view of a swing operation unit. It is a rear perspective view of a swing operation unit. It is a front exploded perspective view of a rocking operation unit. It is a back exploded perspective view of a rocking operation unit. (A) is a front view of the oscillating operation unit, and (b) is a side view of the oscillating operation unit as viewed in the direction of the arrow XXXXIIb in FIG. 42 (a). It is a front view of a swing operation unit. 43A is a cross-sectional view of the drive side arm member, the driven side arm member, and the first bridging member taken along the line XXXXIVa-XXXIVa in FIG. 43, and FIG. It is sectional drawing of a member, a driven side arm member, and a 2nd bridge member. (A) is a partial side view of the swinging operation unit as viewed in the direction of the arrow XXXXVa in FIG. 43, and (b) and (c) show that the driven arm member is bent forward from the state of FIG. FIG. 6 is a partial side view of the swinging operation unit illustrating the state in a time series. FIG. 44 is a cross-sectional view of the drive-side arm member and the driven-side arm member taken along the line XXXXIV-XXXXXIV in FIG. 43. FIG. 44 is a partial cross-sectional view of the swinging operation unit along the line XXXXV-XXXXV in FIG. 43. It is a front view of a drive side arm member and a driven side arm member. It is a front view of a drive side arm member and a driven side arm member. It is a front view of a drive side arm member and a driven side arm member. (A) And (b) is a partial front view of the swing operation unit in 2nd Embodiment. (A) to (c) are front views of the swing operation unit in the third embodiment, and (d) is a cross-sectional view of the swing operation unit along the line Ld-Ld in FIG. 52 (b). It is a front view of a compound operation unit in a 4th embodiment. (A) And (b) is a partial front view of a composite operation unit. It is a rear view of the compound operation unit in a 5th embodiment. (A) to (c) are partial rear views of the composite operation unit. It is a partial front view of a compound operation unit in a 6th embodiment. (A) And (b) is a partial front view of a composite operation unit. (A) And (b) is a partial front view of the swing operation unit in 7th Embodiment. It is a front view of the game board in an 8th embodiment. FIG. 61 is a partial cross-sectional view of the gaming board taken along line LXI-LXI in FIG. 60. (A) is a front view of the first guide arm in the ninth embodiment, (b) is a bottom view of the first guide arm, and (c) is a perspective view of a detachable front locking member. . (A) is a front view of a 2nd guide arm, (b) is a bottom view of a 2nd guide arm, (c) is a 2nd guide arm in the LXIIIc-LXIIIc line of FIG. FIG. (A) and (b) are front views of a first guide arm and a second guide arm of the wiring guide arm, and (c) is a first view of the wiring guide arm along the line LXIVc-LXIVc in FIG. It is sectional drawing of a guide arm and a 2nd guide arm. (A) is a figure which showed typically the area division setting of a display screen, and an effective line setting, and (b) is a figure which illustrated the actual display screen. (A) is a schematic diagram illustrating a screen of the super background notice, and (b) is a schematic diagram illustrating a screen when the screen of (a) is horizontally scroll-displayed in the super background notice. . (A) is a schematic view illustrating a screen on which a special image is displayed in the super background notice, and (b) is a schematic view illustrating a screen suggesting a transition to the door inside background in the super background notice. It is. (A) is a schematic diagram illustrating a screen in which the mode of the stray eyes is displayed in the super reach A, and (b) is a schematic diagram illustrating a mode screen of the double reach in the super reach A. . (A) is a schematic diagram illustrating a screen displayed in Super Reach A, and (b) is a schematic diagram illustrating a screen displayed in Super Reach A. (A) is a schematic diagram illustrating a screen displayed in Super Reach A, and (b) is a schematic diagram illustrating a screen displayed in Super Reach A. It is the schematic diagram which illustrated the screen at the time of a big hit in super reach A. (A) is a schematic diagram illustrating a screen displayed in the big hit effect, and (b) is a schematic diagram illustrating a screen displayed in the big hit effect. (A) is a schematic diagram illustrating a screen displayed in the big hit effect, and (b) is a schematic diagram illustrating a screen displayed in the big hit effect. (A) is a schematic diagram illustrating a screen displayed in the big hit effect, and (b) is a schematic diagram illustrating a screen displayed in the big hit effect. (A) is a schematic diagram illustrating the timing of the effect performed in Super Reach B, and (b) is a schematic diagram illustrating the timing of the effect performed in Super Reach B. (A) is a schematic diagram illustrating the timing of the effect performed in Super Reach B, and (b) is a schematic diagram illustrating the timing of the effect performed in Super Reach B. (A) is a schematic diagram illustrating a screen displayed in super reach B, and (b) is a schematic diagram illustrating a screen displayed in super reach B. (A) is a schematic diagram illustrating a screen displayed in super reach B, and (b) is a schematic diagram illustrating a screen displayed in super reach B. It is a figure showing the outline of various counters. FIG. 3 is a block diagram illustrating an electrical configuration of a RAM in the main control device. (A) is a block diagram showing an electrical configuration of a ROM in the main control device, and (b) schematically shows a correspondence relationship between a first random number counter C1 and a special symbol big hit determination value. (C) is a schematic diagram schematically showing the contents of the first hit type selection table, and (d) is a second random number counter C4 and a normal symbol hit determination value. FIG. 3 is a schematic diagram schematically showing the correspondence relationship of FIG. (A) is a block diagram showing an electrical configuration of a variation pattern selection table provided in a ROM in the main control device, and (b) shows a correspondence between a variation type counter CS1 and a variation type at the time of a big hit. It is a schematic diagram which showed typically, (c) is the schematic diagram which showed typically the correspondence relationship between the fluctuation | variation type counter CS1 and fluctuation | variation type at the time of a deviation (normal), (d) FIG. 9 is a schematic diagram schematically showing a correspondence relationship between a variation type counter CS1 and a variation type in (probable variation). FIG. 2A is a block diagram illustrating an electrical configuration of a ROM in the audio ramp control device, and FIG. 2B is a block diagram illustrating an electrical configuration of a RAM in the audio ramp control device. FIG. 3 is a block diagram illustrating an electrical configuration of the display control device. FIG. 3 is a block diagram illustrating an electrical configuration of a RAM in the display control device. FIG. 4 is a schematic diagram schematically showing the contents of a data table storage area provided in a RAM in the display control device. (A) is a schematic diagram schematically showing the contents of a mass setting table storage area provided in a RAM in a display control device, and (b) is a schematic diagram showing a normal mass setting provided in the mass setting table storage area. It is the schematic diagram which showed typically the content of the table, (c) is the schematic diagram which showed typically the content of the continuous mass setting table provided in the mass setting table storage area. (A) is an explanatory view explaining the back surface A, and (b) is an explanatory diagram explaining the back surface B. It is the schematic diagram which showed an example of the display data table typically. FIG. 4 is a schematic diagram schematically illustrating an example of a transfer data table. It is the schematic diagram which showed an example of the drawing list typically. 5 is a flowchart illustrating a timer interrupt process executed by an MPU in the main control device. It is a flow chart which shows special design change processing performed by MPU in a main control unit. It is a flowchart showing a special symbol change start process executed by the MPU in the main control device. It is a flowchart which shows the start winning process performed by MPU in a main control apparatus. It is a flowchart which shows the normal symbol fluctuation | variation process performed by MPU in a main control apparatus. It is a flowchart which shows the through gate passage process performed by MPU in a main control apparatus. 9 is a flowchart illustrating an NMI interrupt process executed by the MPU in the main control device. 5 is a flowchart illustrating a start-up process performed by an MPU in a main control device. 5 is a flowchart illustrating main processing executed by an MPU in the main control device. It is a flowchart which shows the jackpot control processing performed by MPU in a main control apparatus. 5 is a flowchart illustrating a start-up process performed by an MPU in the audio lamp control device. 5 is a flowchart illustrating a main process executed by an MPU in the audio lamp control device. It is the flowchart which showed the command determination process performed by MPU in a voice lamp control apparatus. 5 is a flowchart illustrating a variable display setting process executed by the MPU in the audio lamp control device. It is the flowchart which showed SW input monitoring and production processing performed by the MPU in the audio lamp control device. It is the flowchart which showed the super background operation process performed by MPU in an audio lamp control device. It is the flowchart which showed the big hit operation process performed by the MPU in the voice lamp control device. It is the flowchart which showed the super reach B time operation process performed by the MPU in the audio lamp control device. 5 is a flowchart illustrating a main process executed by an MPU in the display control device. 9 is a flowchart illustrating a boot process executed by the MPU in the display control device. (A) is a flowchart showing a command interruption process executed by the MPU in the display control device, and (b) is a flowchart showing a V interruption process executed by the MPU in the display control device. is there. 9 is a flowchart illustrating a command determination process executed by the MPU in the display control device. (A) is a flowchart showing a variation pattern command process executed by the MPU in the display control device, and (b) is a flowchart showing a stop type command process executed by the MPU in the display control device. is there. It is the flowchart which showed the super-background effect process performed by MPU in a display control apparatus. 6 is a flowchart illustrating reach-related command processing executed by an MPU in the display control device. It is the flowchart which showed the super reach B process for a display performed by MPU in a display control apparatus. It is the flowchart which showed the big hit related command processing which is executed by the MPU inside the display control device. (A) is a flowchart showing an opening command process executed by the MPU in the display control device, and (b) is a flowchart showing a round number command process executed by the MPU in the display control device. . 9 is a flowchart illustrating a map setting process executed by the MPU in the display control device. 9 is a flowchart showing an ending command process executed by an MPU in the display control device. 9 is a flowchart illustrating a background image change command process executed by the MPU in the display control device. 6 is a flowchart illustrating SW-related command processing executed by the MPU in the display control device. 9 is a flowchart illustrating a super-background SW process executed by the MPU in the display control device. It is a flowchart which showed the big hit SW process performed by MPU in a display control apparatus. 9 is a flowchart illustrating an error command process executed by the MPU in the display control device. 5 is a flowchart illustrating a display setting process executed by the MPU in the display control device. 9 is a flowchart illustrating a warning image setting process executed by the MPU in the display control device. 9 is a flowchart illustrating a pointer update process executed by the MPU in the display control device. (A) is a flowchart showing a transfer setting process executed by the MPU in the display control device, and (b) is a flowchart showing a resident image transfer setting process executed by the MPU in the display control device. is there. 9 is a flowchart illustrating a normal image transfer setting process executed by the MPU in the display control device. (A) is a flowchart showing a drawing process executed by the MPU in the display control device executed by the MPU in the display control device, and (b) is a counter executed by the MPU in the display control device. This is an update process. (A) is a schematic diagram illustrating the timing of the effect performed in the super reach B in the modified example of the first control example, and (b) is performed in the super reach B in the modified example of the first control example. It is the schematic diagram which illustrated the timing of the effect | action. (A) is a schematic diagram illustrating a screen displayed in super reach B in a modified example of the first control example, and (b) is a screen displayed in super reach B in a modified example of the first control example. It is the schematic diagram which illustrated. FIG. 10 is a schematic diagram schematically showing the contents of a data table storage area provided in a RAM in a display control device according to a modification of the first control example. It is a super reach B operation process executed by the MPU in the voice lamp control device in a modified example of the first control example. It is a flowchart which shows the display super reach B process performed by the MPU in the display control apparatus in the modification of a 1st control example. It is the schematic diagram which showed the frame button and the selection switch typically.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, an embodiment in which the present invention is applied to a pachinko gaming machine (hereinafter, simply referred to as “pachinko machine”) 10 will be described as a first embodiment with reference to FIGS. 1 to 50. FIG. 1 is a front view of the pachinko machine 10 according to the first embodiment, FIG. 2 is a front view of the game board 13 of the pachinko machine 10, and FIG. 3 is a rear view of the pachinko machine 10.

  As shown in FIG. 1, the pachinko machine 10 has an outer frame 11 having an outer shell formed by a wooden frame combined in a substantially rectangular shape, and an outer frame 11 formed to have substantially the same outer shape as the outer frame 11. And an inner frame 12 supported to be openable and closable. Metal hinges 18 are attached to the outer frame 11 at two upper and lower positions on the left side in front view (see FIG. 1) to support the inner frame 12, and the side on which the hinges 18 are provided is used as an opening / closing axis. The frame 12 is supported to be openable and closable toward the front side.

  A game board 13 (see FIG. 2) having a large number of nails, winning holes 63, 64, and the like is detachably mounted on the inner frame 12 from the back side. When a ball (game ball) flows down in front of the game board 13, a ball game is performed. The inner frame 12 has a ball launching unit 112a (see FIG. 4) that launches a ball into the front area of the game board 13 and a launch that guides the ball fired from the ball launch unit 112a to the front area of the game board 13. A rail (not shown) and the like are attached.

  On the front side of the inner frame 12, a front frame 14 covering the front upper side and a lower plate unit 15 covering the lower side are provided. In order to support the front frame 14 and the lower plate unit 15, metal hinges 19 are attached to two upper and lower positions on the left side when viewed from the front (see FIG. 1), and the side on which the hinge 19 is provided is used as an opening / closing axis. The lower plate unit 14 and the lower plate unit 15 are supported to be openable and closable toward the front side. The locking of the inner frame 12 and the locking of the front frame 14 are respectively released by inserting a dedicated key into the keyhole 21 of the cylinder lock 20 and performing a predetermined operation.

  The front frame 14 is assembled with decorative resin parts, electric parts, and the like, and is provided with a window portion 14c having an approximately elliptical opening at a substantially central portion thereof. A glass unit 16 having two glass sheets is disposed on the back side of the front frame 14, and the front of the game board 13 is visible on the front side of the pachinko machine 10 via the glass unit 16.

  On the front frame 14, an upper plate 17 for storing a ball is formed in a substantially box shape that protrudes toward the front side and has an open upper surface, and prize balls, loaned balls, and the like are discharged to the upper plate 17. The bottom surface of the upper plate 17 is formed to be inclined downward to the right as viewed from the front (see FIG. 1), and the ball introduced into the upper plate 17 is guided to the ball firing unit 112a (see FIG. 4) by the inclination. A frame button 22 is provided on the upper surface of the upper plate 17. The frame button 22 is operated by the player when, for example, changing the stage of the effect displayed on the third symbol display device 81 (see FIG. 2) or changing the effect of the super reach. You.

  Light emitting means such as various lamps is provided around the front frame 14 (for example, at a corner). These light-emitting means are controlled to change the light-emitting mode by lighting or blinking according to a change in the game state at the time of a big hit or at a predetermined reach, and play a role of enhancing the effect of the effect during the game. At the periphery of the window 14c, there are provided illuminations 29 to 33 in which light-emitting means such as LEDs are incorporated. In the pachinko machine 10, these illumination parts 29 to 33 function as effect lamps such as a jackpot lamp, and at the time of a jackpot or a reach effect, the illumination parts 29 to 33 are turned on by lighting or blinking of a built-in LED. Or, it flashes to notify that a jackpot is in progress or that the player is reaching one step before the jackpot. In addition, at the upper left of the front frame 14 when viewed from the front (see FIG. 1), there is provided a display lamp 34 which has a built-in light emitting means such as an LED and is capable of displaying when a prize ball is being paid out and when an error has occurred.

  Further, a small window 35 is formed below the right illumination unit 32 by attaching a transparent resin from the back side so that the back side of the front frame 14 can be visually recognized, and a sticking space K1 (FIG. 2) can be viewed from the front of the pachinko machine 10. Further, in the pachinko machine 10, a plating member 36 made of chrome-plated ABS resin is attached to a region around the illuminated portions 29 to 33 in order to bring out more gorgeousness.

  A ball lending operation unit 40 is provided below the window 14c. The ball lending operation unit 40 includes a frequency display unit 41, a ball lending button 42, and a return button 43. When the ball lending operation unit 40 is operated in a state in which bills, cards, and the like are inserted into a card unit (ball lending unit) (not shown) arranged on the side of the pachinko machine 10, the ball is slid according to the operation. Lending is done. More specifically, the frequency display unit 41 is an area in which balance information of a card or the like is displayed, and a built-in LED is turned on, and the balance is displayed as a number as balance information. The ball lending button 42 is operated to obtain a lending ball based on information recorded on a card or the like (recording medium), and the lending ball is supplied to the upper plate 17 as long as there is a remaining amount on the card or the like. Is done. The return button 43 is operated when requesting the return of a card or the like inserted in the card unit. In a pachinko machine in which balls are lent directly to the upper plate 17 from a ball lending device or the like without a card unit, a so-called cash machine, the ball-lending operation unit 40 is unnecessary. A decorative seal or the like may be added to the installation portion to make the component configuration common. A pachinko machine using a card unit and a cash machine can be shared.

  In the lower plate unit 15 located below the upper plate 17, a lower plate 50 for storing spheres that could not be completely stored in the upper plate 17 is formed in a substantially box shape with an open upper surface in a central portion thereof. I have. On the right side of the lower plate 50, an operation handle 51 operated by a player to drive a ball into the front of the game board 13 is provided.

  Inside the operation handle 51, a touch sensor 51a for permitting driving of the ball firing unit 112a, a firing stop switch 51b for stopping firing of the ball during a pressing operation, and a rotation of the operation handle 51. A variable resistor (not shown) that detects a dynamic operation amount (rotational position) based on a change in electric resistance is incorporated. When the operation handle 51 is rotated clockwise by the player, the touch sensor 51a is turned on and the resistance value of the variable resistor changes in accordance with the amount of rotation operation, and the resistance value of the variable resistor is changed. The ball is fired at an intensity (firing intensity) corresponding to, and the ball is hit into the front of the game board 13 with a flying amount corresponding to the operation of the player. When the operation handle 51 is not operated by the player, the touch sensor 51a and the firing stop switch 51b are off.

  At the lower front part of the lower plate 50, a ball release lever 52 for operating when discharging the balls stored in the lower plate 50 downward is provided. The ball-pulling lever 52 is constantly urged rightward, and is slid leftward against the urging, so that a bottom opening formed on the bottom surface of the lower plate 50 is opened. The ball naturally drops from the bottom opening and is discharged. The operation of the ball removing lever 52 is usually performed in a state where a box (generally referred to as a “thousand boxes”) for receiving the balls discharged from the lower plate 50 is placed below the lower plate 50. As described above, the operation handle 51 is disposed on the right side of the lower plate 50, and the ashtray 53 is mounted on the left side of the lower plate 50.

  As shown in FIG. 2, the game board 13 includes a base plate 60 cut into a substantially square shape in a front view, a number of nails (not shown) for ball guidance, a windmill (not shown), and a rail 61. , 62, a general winning opening 63, a first winning opening 64, a second winning opening 640, a variable winning device 330, a through gate 67, a variable display device unit 80, and the like. 1)). The base plate 60 is made of a light-transmissive resin material, and is formed so that a player can visually recognize various structures disposed on the back side of the base plate 60 from the front side. The general winning opening 63 and the variable display device unit 80 are provided in through holes formed in the base plate 60 by router processing, and are fixed from the front side of the game board 13 with tapping screws or the like. The first prize port 64, the second prize port 640, and the variable prize apparatus 330 are formed in the lower panel unit 300 which is fitted into a receiving opening 60a of the base plate 60 described later.

  The front central portion of the game board 13 can be visually recognized from the front side of the inner frame 12 through the window 14c (see FIG. 1) of the front frame 14. The configuration of the game board 13 will be described below mainly with reference to FIG.

  An outer rail 62 formed by bending a band-shaped metal plate into a substantially arc shape is planted on the front of the game board 13, and a band-shaped metal plate similar to the outer rail 62 is provided inside the outer rail 62. The arc-shaped inner rail 61 formed by the above is planted. The inner rail 61 and the outer rail 62 surround the outer periphery of the front of the game board 13, and the front and rear of the game board 13 and the glass unit 16 (see FIG. 1) surround the front and back of the game board 13. A game area in which a game is played is formed by the behavior of. The game area is an area defined by two rails 61 and 62 and a resin outer edge member 73 connecting between the rails, which is the front of the game board 13 (a winning opening or the like is provided and fired). The area where the falling ball flows down).

  The two rails 61 and 62 are provided to guide the ball fired from the ball firing unit 112a (see FIG. 4) to the upper part of the game board 13. A return ball preventing member 68 is attached to a tip portion (upper left portion of FIG. 2) of the inner rail 61 to prevent a ball once guided to the upper portion of the game board 13 from returning to the ball guide passage again. Is done. A return rubber 69 is attached to the tip of the outer rail 62 (upper right portion in FIG. 2) at a position corresponding to the maximum flight portion of the ball, and the ball fired at a predetermined momentum hits the return rubber 69 and momentum. Is rebounded toward the center while being attenuated.

  First symbol display devices 37A and 37B each including a plurality of LEDs as light emitting means and a 7-segment display are provided at a lower left portion (a lower left portion in FIG. 2) of the game area when viewed from the front. The first symbol display devices 37A and 37B are for performing display according to each control performed by the main control device 110 (see FIG. 4), and mainly display the game state of the pachinko machine 10. In the present embodiment, the first symbol display devices 37A and 37B are configured to be properly used depending on whether the ball has won the first winning opening 64 or the second winning opening 640. Specifically, when the ball wins the first winning opening 64, the first symbol display device 37A operates, while when the ball wins the second winning opening 640, the first symbol display device 37A operates. The symbol display device 37B is configured to operate.

  In addition, the first symbol display devices 37A and 37B use LEDs to indicate whether the pachinko machine 10 is in the process of probable change, during working hours, or during normal operation, or to indicate whether or not the pachinko machine 10 is fluctuating. Whether the stop symbol is a symbol corresponding to a probable jackpot or a symbol corresponding to an ordinary jackpot is indicated by an illuminated state, the number of retained balls is indicated by an illuminated state, and the round during the jackpot is displayed by a 7-segment display device. Display numbers and errors. In addition, the plurality of LEDs are configured such that the emission colors (for example, red, green, and blue) of each LED are different, and the combination of the emission colors may indicate various game states of the pachinko machine 10 with a small number of LEDs. it can.

  In the pachinko machine 10, the lottery is performed when the first winning port 64 and the second winning port 640 have a winning. In the lottery, the pachinko machine 10 determines whether or not it is a big hit (big hit lottery), and when it is determined to be a big hit, also determines the big hit type. As the jackpot type determined here, a 15R certain-variable jackpot, a 4R certain-variable jackpot, and a 15R regular large jackpot are prepared. The first symbol display devices 37A and 37B not only indicate whether or not the result of the lottery is a jackpot as a stop symbol after the end of the change, but if the jackpot is a jackpot, a symbol corresponding to the jackpot type is displayed. .

  Here, “15R probability variable jackpot” is a probability variable jackpot in which the maximum number of rounds shifts to a high probability state after 15 rounds of jackpot, and “4R probability variable jackpot” means a maximum round number of four rounds. Is a probable jackpot that transitions to a high probability state after. The “15R normal jackpot” is a jackpot in which the maximum number of rounds shifts to the low probability state after the jackpot of 15 rounds and the time saving state is reached during a predetermined number of changes (for example, 100 changes). is there.

  The “high-probability state” refers to a state in which the subsequent jackpot probability is increased as an added value after the end of the jackpot, that is, when the probability is changing (probable change), in other words, a game that is easily shifted to the special game state. State. The high probability state (probable change) in the present embodiment includes a state of a game in which the winning probability of a second symbol described later increases and a ball can easily enter the second winning opening 640. The “low-probability state” refers to a state where the probability of change is not being changed, and a state in which the jackpot probability is normal, that is, a state in which the probability of jackpot is lower than that in the case of probability change. The time saving state (medium time saving) of the “low probability state” is a state in which the jackpot probability is a normal state, and the jackpot probability of the second symbol is increased while the jackpot probability remains unchanged. This refers to a game state in which a ball is likely to win. On the other hand, the state where the pachinko machine 10 is in the normal state is a state of the game in which the probability is not changed or the time is not reduced (a state in which neither the big hit probability nor the second symbol hit probability is increased).

  During probable change or during working hours, not only the probability of hitting the second symbol increases, but also the time during which the electric accessory 640a attached to the second winning opening 640 is opened is changed. Is set. When the electric accessory 640a is in an open state (open state), a ball is awarded to the second winning opening 640 as compared to when the electric accessory 640a is in a closed state (closed state). It will be in an easy state. Therefore, during a probability change or during a shortened working hours, a ball can easily enter the second winning opening 640, and the number of jackpot lotteries can be increased.

  In addition, during the probability change or during the working hours, instead of changing the opening time of the motorized accessory 640a attached to the second winning opening 640, or in addition to changing the opening time, the power A change may be made to increase the number of times that the accessory 640a is released from the normal number. In addition, during the probability change or during working hours, the winning probability of the second symbol is not changed, and the electric accessory 640a associated with the second winning opening 640 is opened and the electric accessory 640a is opened once. At least one of the number of times may be changed. In addition, during probable change or during working hours, the time during which the electric accessory 640a associated with the second winning opening 640 is opened or the number of times the electric accessory 640a is opened per hit is not determined. Only the probability may be changed so as to increase as compared with the normal state.

  In the game area, a plurality of general winning openings 63 are provided in which five to fifteen balls are paid out as winning balls when the balls win. Further, a variable display device unit 80 is provided in a central portion of the game area. The variable display device unit 80 uses the winning (starting winning) in the first winning opening 64 and the second winning opening 640 as a trigger, and synchronizes with the variable display on the first symbol display devices 37A and 37B, and outputs the third symbol. A third symbol display device 81 composed of a liquid crystal display (hereinafter simply abbreviated as "display device") for performing a variable display, and an LED for varying display of a second symbol when the ball of the through gate 67 passes is used as a trigger. A second symbol display device (not shown) is provided. Further, a center frame 86 is provided in the variable display device unit 80 so as to surround the outer periphery of the third symbol display device 81.

  The third symbol display device 81 is composed of a large-sized 9-inch liquid crystal display. The display content is controlled by the display control device 114 (see FIG. 4), so that, for example, the upper, middle and lower 3 Two symbol columns are displayed. Each symbol row is composed of a plurality of symbols (third symbols), and these third symbols are horizontally scrolled for each symbol row, and the third symbol is variably displayed on the display screen of the third symbol display device 81. It has become. In the third symbol display device 81 of the present embodiment, the display of the gaming state accompanying the control of the main control device 110 (see FIG. 4) is performed by the first symbol display devices 37A and 37B, whereas the first symbol display device 37A displays the game state. The decorative display corresponding to the display of the symbol display devices 37A and 37B is performed. Note that the third symbol display device 81 may be configured using, for example, a reel or the like instead of the display device.

  The second symbol display device alternately lights a symbol “O” and a symbol “X” as display symbols (second symbols (not shown)) for a predetermined time each time a ball passes through the through gate 67. The variable display is performed. In the pachinko machine 10, when it is detected that the ball has passed through the through gate 67, a winning lottery is performed. If the winning lottery results in a winning, the symbol "O" is stopped and displayed on the second symbol display device after the variation of the second symbol is displayed. If the result of the winning lottery is off, the symbol “x” is stopped and displayed on the second symbol display device after the variation display of the third symbol.

  In the case of the pachinko machine 10, when the variable display on the second symbol display device is stopped at a predetermined symbol (in this embodiment, a symbol of “○”), the electric accessory 640a attached to the second winning opening 640 is moved for a predetermined time. Only in the operating state (open).

  The time required for the fluctuation display of the second symbol is set to be shorter during the probable change or during the time reduction than in the normal game state. Thus, during the probable change and during the time reduction, the fluctuation display of the second symbol is performed in a short time, so that the winning lottery can be performed more than during the normal. Therefore, the chance of winning in the winning lottery increases, so that the player can be given many opportunities to open the electric accessory 640a of the second winning opening 640. Therefore, the ball can easily enter the second winning opening 640 during the probability change and during the working hours.

  In addition, during the probability change or during the working hours, the probability of winning is increased, and the opening time and the number of times of opening the electric accessory 640a per hit are increased. When the ball is in a state where it is easy to win, the time required for the variable display of the second symbol may be constant regardless of the gaming state. On the other hand, when the time required for the fluctuation display of the second symbol is set to be shorter than the normal time during the probability change or during the time saving, the hit probability may be constant regardless of the game state, or one hit may be performed. The opening time and the number of times of opening of the electric accessory 640a with respect to may be constant regardless of the gaming state.

  The through gate 67 is assembled to the game board 13 in the left and right regions of the variable display device unit 80, and is configured to allow a part of the ball fired on the game board 13 to pass through. When the ball passes through the through gate 67, a winning lottery of the second symbol is performed. After the winning lottery, the variable display is performed on the second symbol display device. If the result of the winning lottery is a hit, a symbol of "○" is displayed as a stop symbol of the variable display, and the result of the winning lottery is out of order. For example, a symbol "x" is displayed as a stop symbol of the variable display.

  The number of times the ball has passed through the through gate 67 is held up to a total of four times, and the number of held balls is displayed by the above-mentioned first symbol display devices 37A and 37B, and at the second symbol holding lamp (not shown). Is also lit. Four second symbol holding lamps are provided for the maximum number of holdings, and are disposed symmetrically below the third symbol display device 81.

  The variable display of the second symbol is performed by switching on and off of a plurality of lamps in the second symbol display device as in the present embodiment, as well as the first symbol display devices 37A and 37B and the third symbol display. This may be performed using a part of the symbol display device 81. Similarly, the lighting of the second symbol holding lamp may be performed by a part of the third symbol display device 81. Further, the maximum number of reserved balls for passing the ball through the through gate 67 is not limited to four, and may be set to three or less, or five or more (for example, eight). The number of through gates 67 is not limited to two, and may be one, for example. Further, the mounting position of the through gate 67 is not limited to the left and right of the variable display device unit 80, but may be, for example, below the variable display device unit 80. Further, since the number of reserved balls is indicated by the first symbol display devices 37A and 37B, the second symbol retaining lamp may not be turned on.

  Below the variable display unit 80, a first winning port 64 in which a ball can win is provided. When a ball wins in the first winning opening 64, a first winning opening switch (not shown) provided on the back side of the game board 13 is turned on, and the main control unit 110 is turned on by turning on the first winning opening switch. A jackpot lottery is performed in (see FIG. 4), and a display corresponding to the lottery result is shown on the first symbol display device 37A.

  On the other hand, below the first winning opening 64 in front view, a second winning opening 640 where a ball can win is arranged. When a ball wins in the second winning opening 640, a second winning opening switch (not shown) provided on the back side of the game board 13 is turned on, and the main control device 110 is turned on by turning on the second winning opening switch. A jackpot lottery is performed at (see FIG. 4), and a display corresponding to the lottery result is shown on the first symbol display device 37B.

  Each of the first winning port 64 and the second winning port 640 is also one of winning ports in which five balls are paid out as winning balls when the ball wins. In the present embodiment, the number of award balls to be paid out when a ball wins in the first winning opening 64 and the number of award balls to be paid out when a ball wins to the second winning opening 640 are the same. The number of award balls to be paid out when a ball wins in the first winning opening 64 is different from the number of award balls to be paid out when a ball wins to the second winning opening 640, for example, the number of balls to the first winning opening 64. May be configured such that the number of award balls paid out when the player wins is three, and the number of award balls paid out when a ball wins in the second winning opening 640.

  The second winning opening 640 is provided with an electric accessory 640a. The electric accessory 640a is configured to be openable and closable. Normally, the electric accessory 640a is in a closed state (reduced state), so that the ball does not easily enter the second winning opening 640. On the other hand, when the symbol “O” is displayed on the second symbol display device as a result of the second symbol change display performed when the ball passes through the through gate 67, the electric accessory 640 a is in the open state (enlarged). State), and the ball is in a state where it is easy to win the second winning opening 640.

  As described above, the probability of hitting the second symbol is higher during the probable change and during the working hours, and the time required to display the variation of the second symbol is shorter than that during the normal period. Are easily displayed, and the number of times the electric accessory 640a is opened (increased) increases. Further, during probable change and during working hours, the time during which the electric accessory 640a is opened is longer than during normal times. Therefore, a state in which a ball can easily win the second winning opening 640 can be created during the probability change and during the working hours, as compared with the normal time.

  Here, the probability of a big hit in the case where the ball has won in the first winning opening 64 and the case where the ball has won in the second winning opening 640 is the same in the low probability state and the high probability state. However, the probability of a 15R probability variable jackpot being selected as a jackpot type selected in the event of a jackpot is higher when a ball wins the second winning opening 640 than when a ball wins the first winning opening 64. Is set. On the other hand, the first winning opening 64 does not have the motorized accessory as in the second winning opening 640, and the ball is always in a state where it can win.

  Therefore, during normal times, the electric winning accessory attached to the second winning opening 640 is often in a closed state, and it is difficult to win the second winning opening 640. Then, the ball is fired so that the ball passes to the left of the variable display device unit 80 (so-called “left-handed”), and by winning the first winning opening 64, a lot of chances of a jackpot lottery are obtained, and the jackpot is won. It is more advantageous for the player to aim for that.

  On the other hand, when the ball is passed through the through gate 67 during the probable change or during working hours, the electric accessory 640a attached to the second winning opening 640 is likely to be opened and the second winning opening 640 is easily won. Therefore, the ball is fired toward the second winning opening 640 so that the ball passes to the right of the variable display device 80 (so-called “right-handed”), and passes through the through gate 67 to open the electric accessory. At the same time, it is more advantageous for the player to aim for a 15R probability change jackpot by winning the second winning opening 640.

  In the pachinko machine 10 according to the present embodiment, since the configuration of the game board 13 is symmetrical, the pachinko machine 10 can aim at the first winning opening 64 by “right-handing” or the second winning opening 640 by “left-handing”. You can also aim. For this reason, the pachinko machine 10 of the present embodiment provides the player with a method of shooting a ball in accordance with the playing state of the pachinko machine 10 (whether the game is being changed, is being reduced in time, or is usually being made). Need to be changed to “left-handed” and “right-handed”. Therefore, the trouble of changing the way of hitting the ball can be eliminated.

  A variable winning device 330 (see FIG. 11) is provided below the first winning opening 64, and a specific winning opening 65a is provided at a substantially central portion thereof. In the pachinko machine 10, when the jackpot lottery performed due to the winning in the first winning port 64 or the second winning port 640 becomes a jackpot, after a predetermined time (variable time) elapses, the jackpot stop symbol is displayed. Thus, the first symbol display device 37A or the first symbol display device 37B is turned on, and a stop symbol corresponding to the jackpot is displayed on the third symbol display device 81 to indicate the occurrence of the jackpot. After that, the game state transitions to a special game state (big hit) where the ball is easy to win. In this special game state, the specific winning opening 65a which is normally closed is opened for a predetermined time (for example, until 30 seconds elapse or until 10 balls are won).

  The specific winning opening 65a is closed after a predetermined time has elapsed, and after the closing, the specific winning opening 65a is opened again for a predetermined time. The opening / closing operation of the specific winning opening 65a can be repeated up to, for example, 15 times (15 rounds). The state in which the opening / closing operation is being performed is one form of a special game state that is advantageous to the player, and the player is paid out a larger amount of prize balls than usual in order to give a game value (game value). Is performed. The details of the variable winning device 330 (see FIG. 11) that opens and closes the specific winning opening 65a will be described later. However, in brief, the moving upper cover member 332 of the variable winning device 330 slides, and the specific winning opening 65a is opened. It is opened and closed.

  The special game state is not limited to the above-described embodiment. A large opening that is opened and closed separately from the specific winning opening 65a is provided in the game area, and when the LED corresponding to the big hit is lit on the first symbol display devices 37A and 37B, the specific winning opening 65a is opened for a predetermined time. During the opening of the specific winning opening 65a, a game state in which a large opening provided separately from the specific winning opening 65a is opened for a predetermined time and a predetermined number of times when a ball wins inside the specific winning opening 65a is a special game. It may be formed as a state. The number of the specific winning opening 65a is not limited to one, and one or two or more (for example, three) may be arranged. The present invention is not limited to the lower left side of the winning opening 64, but may be, for example, the left side of the variable display unit 80.

  At the lower right corner of the game board 13, there is provided a sticking space K 1 for sticking a stamp or an identification label, etc. The stamp or the like stuck to the sticking space K 1 is a small window of the front frame 14. 35 (see FIG. 1).

  The game board 13 is provided with an out port 314. A ball that flows down the game area and does not win any of the winning ports 63, 64, 65a, and 640 is guided to a ball discharge path (not shown) through the out port 314. The out opening 314 is provided in a pair on the left and right of the specific winning opening 65a.

  In the game board 13, a large number of nails are planted for appropriately dispersing and adjusting the falling direction of the ball, and various members (accessories) such as a windmill are provided.

  As shown in FIG. 3, on the back side of the pachinko machine 10, control board units 90 and 91 and a back pack unit 94 are mainly provided. The control board unit 90 includes a main board (main control device 110), an audio lamp control board (audio lamp control device 113), and a display control board (display control device 114). The control board unit 91 is provided with a payout control board (payout control device 111), a launch control board (fire launch control device 112), a power supply board (power supply device 115), and a card unit connection board 116.

  In the back pack unit 94, a back pack 92 and a payout unit 93 forming a protective cover unit are unitized. In addition, each control board includes an MPU as a one-chip microcomputer for controlling each control, a port for communicating with various devices, a random number generator used for various lotteries, and a time counting and synchronization. A clock pulse generating circuit and the like are mounted as needed.

  The main control device 110, the sound lamp control device 113 and the display control device 114, the payout control device 111 and the firing control device 112, the power supply device 115, and the card unit connection board 116 are housed in the board boxes 100 to 104, respectively. . Each of the board boxes 100 to 104 includes a box base and a box cover that covers an opening of the box base. The box base and the box cover are connected to each other, and each control device and each board are stored.

  Further, the substrate box 100 (main control device 110) and the substrate box 102 (dispensing control device 111 and firing control device 112) non-openably connect the box base and the box cover by a sealing unit (not shown) (the caulking structure). Consolidation). In addition, a seal (not shown) is attached to the connection between the box base and the box cover over the box base and the box cover. This sealing seal is made of a brittle material. If the sealing seal is to be peeled off to open the substrate boxes 100 and 102, or if the substrate boxes 100 and 102 are forcibly opened, the box base side and the box cover are closed. Cut to the side and. Therefore, by checking the sealing unit or the sealing seal, it is possible to know whether or not the substrate boxes 100 and 102 have been opened.

  The dispensing unit 93 includes a tank 130 located at the top of the back pack unit 94 and opening upward, a tank rail 131 connected below the tank 130 and gently inclined toward the downstream side, and a downstream side of the tank rail 131. A case rail 132 vertically connected to the side, and a payout device 133 provided at the most downstream portion of the case rail 132 and paying out balls by a predetermined electrical configuration of a payout motor 216 (see FIG. 4). ing. The balls supplied from the island facilities of the game hall are sequentially supplied to the tank 130, and the payout device 133 pays out a required number of balls as needed. A vibrator 134 for applying vibration to the tank rail 131 is attached to the tank rail 131.

  The dispensing control device 111 is provided with a state return switch 120, the firing control device 112 is provided with an operation knob 121 for a variable resistor, and the power supply device 115 is provided with a RAM erasure switch 122. The state return switch 120 is operated to clear the clogged ball (return to a normal state) when a payout error occurs, such as a clogged ball in the payout motor 216 (see FIG. 4). The operation knob 121 is operated to adjust the firing force of the firing solenoid. The RAM erase switch 122 is operated when the power is turned on to return the pachinko machine 10 to the initial state.

  Next, an electrical configuration of the pachinko machine 10 will be described with reference to FIG. FIG. 4 is a block diagram showing an electrical configuration of the pachinko machine 10. As shown in FIG.

  The main control device 110 is equipped with an MPU 201 as a one-chip microcomputer which is an arithmetic device. The MPU 201 includes a ROM 202 storing various control programs and fixed value data executed by the MPU 201, and a memory for temporarily storing various data and the like when executing the control programs stored in the ROM 202. A certain RAM 203 and other various circuits such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit are built in. In the main control device 110, the main processing of the pachinko machine 10 such as the jackpot lottery, the setting of the display on the first symbol display device 37A, 37B and the third symbol display device 81, and the lottery of the display result on the second symbol display device are performed by the MPU 201. Execute

  Various commands are transmitted from the main control device 110 to the sub-control device by the data transmission / reception circuit in order to instruct the sub-control devices such as the payout control device 111 and the sound lamp control device 113 to operate. Such a command is transmitted from the main control device 110 to the sub control device only in one direction.

  The RAM 203 includes, in addition to various areas, counters, and flags, a stack area in which the contents of internal registers of the MPU 201 and a return address of a control program executed by the MPU 201 are stored. A work area (work area) in which values are stored. The RAM 203 has a configuration in which a backup voltage is supplied from the power supply 115 to retain data (backup) even after the power of the pachinko machine 10 is cut off, and all data stored in the RAM 203 is backed up. .

  When the power is shut down due to the occurrence of a power failure or the like, the stack pointer and the value of each register at the time of the power shutdown (including when a power failure occurs; the same applies hereinafter) are stored in the RAM 203. On the other hand, when the power is turned on (including turning on the power by turning off the power, the same applies hereinafter), the state of the pachinko machine 10 is returned to the state before the power was turned off based on the information stored in the RAM 203. Writing to the RAM 203 is executed when the power is turned off by a main process (not shown), and restoration of each value written to the RAM 203 is executed in a startup process (not shown) when the power is turned on. It should be noted that the power failure signal SG1 from the power failure monitoring circuit 252 is input to the NMI terminal (non-maskable interrupt terminal) of the MPU 201 when the power is cut off due to the occurrence of a power failure or the like. , An NMI interrupt process (not shown) as a power failure process is immediately executed.

  An input / output port 205 is connected to the MPU 201 of the main controller 110 via a bus line 204 composed of an address bus and a data bus. The input / output port 205 has a payout control device 111, a sound lamp control device 113, a first symbol display device 37A, 37B, a second symbol display device, a second symbol hold lamp, and a lower side of an opening / closing plate of the specific winning opening 65a. A solenoid 209 including a large opening solenoid for opening and closing the front side and a solenoid for driving an electric accessory is connected, and the MPU 201 sends various commands and control signals to these via an input / output port 205. Send

  The input / output port 205 includes various switches 208 including a switch group (not shown) and a sensor group including a slide position detection sensor S and a rotation position detection sensor R, and a RAM erasure switch circuit 253 described later provided in the power supply device 115. Is connected, and the MPU 201 executes various processes based on signals output from the various switches 208 and the RAM erase signal SG2 output from the RAM erase switch circuit 253.

  The payout control device 111 drives the payout motor 216 to control the payout of prize balls and loaned balls. The MPU 211 as an arithmetic unit has a ROM 212 storing a control program executed by the MPU 211, fixed value data, and the like, and a RAM 213 used as a work memory or the like.

  Like the RAM 203 of the main control device 110, the RAM 213 of the payout control device 111 has a stack area in which the contents of the internal registers of the MPU 211 and the return address of the control program executed by the MPU 211 are stored, and various flags and counters. , I / O and the like are stored. The RAM 213 has a configuration in which a backup voltage is supplied from the power supply device 115 so that data can be retained (backed up) even after the power of the pachinko machine 10 is cut off, and all data stored in the RAM 213 is backed up. Note that, similarly to the MPU 201 of the main control device 110, the NMI terminal of the MPU 211 is configured to receive the power failure signal SG1 from the power failure monitoring circuit 252 when the power is shut off due to the occurrence of a power failure or the like. When input to the MPU 211, an NMI interrupt process (not shown) as a process at the time of a power failure is immediately executed.

  An input / output port 215 is connected to the MPU 211 of the payout control device 111 via a bus line 214 composed of an address bus and a data bus. The input / output port 215 is connected to the main control device 110, the payout motor 216, the firing control device 112, and the like. Although not shown, the payout control device 111 is connected to a prize ball detection switch for detecting the paid prize ball. The prize ball detection switch is connected to the payout control device 111, but is not connected to the main control device 110.

  The launch control device 112 controls the ball launch unit 112a so as to have a launching strength of the ball according to the amount of rotation of the operation handle 51 when the main control device 110 gives an instruction to launch the ball. . The ball firing unit 112a includes a firing solenoid and an electromagnet (not shown), and the firing solenoid and the electromagnet are permitted to be driven when predetermined conditions are satisfied. Specifically, the touch sensor 51a detects that the player is touching the operation handle 51, and the operation is performed on condition that the firing stop switch 51b for stopping firing of the ball is turned off (not operated). The firing solenoid is excited in accordance with the amount of turning operation (rotating position) of the handle 51, and the ball is fired with a strength corresponding to the amount of operation of the operating handle 51.

  The sound lamp control device 113 outputs sound from a sound output device (such as a speaker (not shown)) 226, turns on and off lights from a lamp display device (lighting units 29 to 33, display lamps 34, etc.) 227, and produces a fluctuation effect (fluctuation). It controls the setting of the display mode of the third symbol display device 81, which is performed by the display control device 114, such as display) and a notice effect. The MPU 221 as an arithmetic unit has a ROM 222 storing a control program executed by the MPU 221 and fixed value data, and the like, and a RAM 223 used as a work memory or the like.

  The input / output port 225 is connected to the MPU 221 of the audio ramp control device 113 via a bus line 224 composed of an address bus and a data bus. The input / output port 225 includes a main controller 110, a display controller 114, an audio output device 226, a lamp display device 227, other devices 228, a frame button 22, a selection switch 270 (an upper switch 270a, a right switch 270b, a lower switch 270c). , Left switch 270d), decision switch 270e, and the like. Other devices 228 include drive motors 433, 462, 551 and solenoid 474.

  The sound lamp control device 113 determines the display mode of the third symbol display device 81 based on various commands (variation pattern command, stop type command, etc.) received from the main control device 110, and commands the determined display mode to a command. (Display variation pattern command, display stop type command, etc.). Further, the sound lamp control device 113 monitors an input from the frame button 22 and, when the player operates the frame button 22, changes the stage displayed on the third symbol display device 81 or performs super reach. The display control device 114 is instructed to change the effect content at the time. When the stage is changed, a back image change command including information on the changed stage is transmitted to the display control device 114 so that the third image display device 81 displays a rear image corresponding to the changed stage. . Here, the back image is an image displayed on the back side of the third symbol, which is a main image displayed on the third symbol display device 81. The display control device 114 displays various images on the third symbol display device 81 according to the command transmitted from the audio lamp control device 113.

  Further, the sound lamp control device 113 receives a command (display command) representing the display content of the third symbol display device 81 from the display control device 114. Based on the display command received from the display control device 114, the sound lamp control device 113 outputs a sound corresponding to the display content from the sound output device 226 in accordance with the display content of the third symbol display device 81. Lighting and extinguishing of the lamp display device 227 are controlled in accordance with the display contents.

  The display control device 114 is connected to the audio lamp control device 113 and the third symbol display device 81 and, based on a command received from the audio lamp control device 113, performs a variation effect of the third symbol in the third symbol display device 81. It controls display. In addition, the display control device 114 appropriately transmits a display command for notifying the display content of the third symbol display device 81 to the audio lamp control device 113. The sound lamp control device 113 outputs the sound from the sound output device 226 in accordance with the display content indicated by the display command, so that the display of the third symbol display device 81 and the sound output from the sound output device 226 are matched. be able to.

  The power supply unit 115 includes a power supply unit 251 for supplying power to each unit of the pachinko machine 10, a power failure monitoring circuit 252 for monitoring power interruption due to a power failure or the like, and a RAM provided with a RAM erase switch 122 (see FIG. 3). And an erase switch circuit 253. The power supply unit 251 is a device that supplies a required operating voltage to each of the control devices 110 to 114 and the like via a power supply path (not shown). As an outline, the power supply unit 251 takes in a voltage of AC 24 volts supplied from the outside, and outputs a voltage of 12 volts for driving various switches such as various switches 208, a solenoid such as the solenoid 209, a motor, and the like. A voltage of 5 volts for logic, a backup voltage for RAM backup, and the like are generated, and these 12 volts, 5 volts and backup voltage are supplied to necessary voltages to the control devices 110 to 114 and the like.

  The power failure monitoring circuit 252 is a circuit for outputting a power failure signal SG1 to each NMI terminal of the MPU 201 of the main control device 110 and the MPU 211 of the payout control device 111 when the power is cut off due to the occurrence of a power failure or the like. The power failure monitoring circuit 252 monitors a DC stable voltage of 24 volts, which is the maximum voltage output from the power supply unit 251, and determines that a power failure (power interruption, power interruption) has occurred if this voltage falls below 22 volts. Then, the power outage signal SG1 is output to the main control device 110 and the payout control device 111. Based on the output of the power failure signal SG1, the main control device 110 and the payout control device 111 recognize the occurrence of the power failure and execute the NMI interrupt processing. Note that, even after the DC stable voltage of 24 volts becomes less than 22 volts, the power supply unit 251 outputs the voltage of 5 volts, which is the drive voltage of the control system, for a time sufficient for executing the NMI interrupt processing. Is maintained at a normal value. Therefore, main controller 110 and payout controller 111 can normally execute and complete the NMI interrupt process (not shown).

  The RAM erasure switch circuit 253 is a circuit for outputting a RAM erasure signal SG2 for clearing the backup data to the main controller 110 when the RAM erasure switch 122 (see FIG. 3) is pressed. The main controller 110 clears the backup data when the RAM erasing signal SG2 is input when the power of the pachinko machine 10 is turned on, and also controls the payout control device 111 to execute a payout initialization command for clearing the backup data. Transmit to the device 111.

  Next, the game board 13 and the operation unit 200 will be described with reference to FIGS. First, with reference to FIGS. 5 and 6, a description will be given of a structure in which the units 400 and 500 are housed in the rear case 210. FIG.

  FIG. 5 is a front perspective view of the operation unit 200, and FIG. 6 is an exploded front perspective view of the operation unit 200 when the disassembled operation unit 200 is viewed from the front.

  As shown in FIGS. 5 and 6, the operation unit 200 is opened on one side (front side in FIG. 6) from the bottom wall 211 and the outer wall 212 erected from the outer edge of the bottom wall 211. And a rear case 210 formed in a box shape. The rear case 210 is formed in a rectangular frame shape in a front view by forming a rectangular opening 211a at the center of the bottom wall portion 211. The opening 211a is formed in a size corresponding to the outer shape of the third symbol display device 81 (see FIG. 2) (that is, in which the third symbol display device 81 can be disposed).

  The left, right, and upper outer wall portions 212 include an intermediate wall portion 212a formed in the middle in the front-rear direction and parallel to the bottom wall portion 211, and a fastening portion 212b capable of fastening a member to the intermediate wall portion 212a. On the front side of the intermediate wall portion 212a, the outer wall portion 212 extends from the end opposite to the opening 211a of the intermediate wall portion 212a, and on the back side of the intermediate wall portion 212a, the outer wall portion 212 is It extends from the end of the side 212a adjacent to the opening 211a.

  The holding and fixing portion 446 and the fixing plate 461 are fastened and fixed to the fastening portion 212b formed on the left and right intermediate wall portions 212a, and the guide plate 424 is fixed to the fastening portion 212b formed on the upper middle wall portion 212a. Are fastened and fixed.

  Here, the fixing plate 461 is a member that supports a drive motor 462 that generates a driving force for driving the composite operation unit 400, and the holding and fixing portion 446 is a member that fixes one end of the biasing spring 445, and the guide plate 424. Is a member for guiding the movement of the connecting member 423 (see FIG. 20) of the composite operation unit 400. In other words, none of these is a production part directly visible to the player, but a part having an auxiliary role of production for generating a driving force for the operation of the combined operation unit 400 or guiding the operation. .

  By disposing the fixing plate 461, the holding and fixing portion 446, and the guide plate 424 having such a role near the front side of the rear case 210, a space near the rear side of the rear case 210 can be opened. By using the vacant space on the rear side as a space for retreating a portion that is actually visually recognized by the player, such as the shielding member 420, the constituent members of the composite operation unit 400 can be stacked back and forth, and the opening 211a The width required for retracting the composite operation unit 400 to the outside can be reduced. Therefore, the formation width of the bottom plate portion 211 can be reduced. Thereby, the opening 211a can be enlarged, and the formation range of the third symbol display device 81 can be enlarged.

  In the operation unit 200, the composite operation unit 400 and the swing operation unit 500 are respectively housed in the internal space of the rear case 210, and are configured as one unit.

  Specifically, the composite operation unit 400 is disposed on the left, right, and upper portions of the area formed by the inner surface of the outer wall 212 of the rear case 210, and the swing operation unit 500 is disposed inside the outer wall 212 of the rear case 210. It is disposed below the area formed by the side surface (see FIG. 5).

  Next, with reference to FIGS. 7 to 9, an outline of operation modes of the composite operation unit 400 and the swing operation unit 500 will be described. In the description of FIGS. 7 to 9, FIGS. 5 and 6 will be referred to as appropriate.

  7 to 9 are front views of the operation unit 200. FIG. Note that FIG. 7 shows a state where the main body member 410 of the composite operation unit 400 is located at the overhang position, FIG. 8 shows a state where the moving member 540 of the swing operation unit 500 is located at the overhang position, and FIG. The state in which the main body member 410 of the composite operation unit 400 and the moving member 540 of the swing operation unit 500 are arranged at the extended position is illustrated.

  As shown in FIG. 7, the composite operation unit 400 operates the main body member 410 between the retracted position shown in FIG. 5 and the extended position shown in FIG. That is, at the retracted position shown in FIG. 5, the main body member 410 is retracted above the opening 211a of the rear case 210 (see FIG. 2). On the other hand, in the extended position shown in FIG. 7, the main body member 410 is lowered, and the main body member 410 is disposed at the center of the opening 211a of the rear case 210 (that is, in front of the third symbol display device 81, see FIG. 2). . The composite operation unit 400 is a unit that performs two kinds of operations (sliding operation and swinging operation) in which the shielding member 420 moves in a different manner by sliding the main body member 410 as described later.

  As shown in FIG. 8, the swing operation unit 500 operates the moving member 540 between the retracted position shown in FIG. 5 and the extended position shown in FIG. In the retracted position shown in FIG. 5, the moving member 540 is retracted below the opening 211a of the rear case 210 (see FIG. 2). On the other hand, in the overhang position shown in FIG. 8, the moving member 540 is raised, and the moving member 540 is disposed at the center of the opening 211a of the rear case 210 (that is, in front of the third symbol display device 81, see FIG. 2). . The moving members 540 are formed as a pair of left and right, and at the projecting position shown in FIG.

  As shown in FIG. 9, both the composite operation unit 400 and the swing operation unit 500 can be arranged at the extended position. In this case, the composite operation unit 400 and the swing operation unit 500 can be visually recognized as an integrated decorative member (partially overlapped in a front view), and a decorative member having a width equal to or larger than the width outside the opening 211a is formed. be able to. Thereby, the effect of the combined operation unit 400 and the swing operation unit 500 can be improved. In addition, since the composite operation unit 400 and the swing operation unit 500 project toward the center of the opening 211a in different directions (downward and upward), for example, compared with a case where all the movable members extend in the same direction, The distance that each member moves from the retracted position to the extended position can be reduced. Accordingly, when the moving speeds of the combined operation unit 400 and the swing operation unit 500 are the same, the period of moving from the retreat position to the overhang position can be reduced.

  Next, with reference to FIG. 10 to FIG. 18, the board lower unit 300 disposed below the game board 13 will be described. 10 and 11 are front exploded perspective views of the game board 13 and the board lower unit 300, and FIG. 12 is a rear exploded perspective view of the game board 13 and the board lower unit 300. Note that FIG. 10 shows a state in which only the front plate member 320 is disassembled from the game plate 13, and FIGS. 11 and 12 show that the front unit 310 and the variable winning device 330 of the lower panel unit 300 are further divided from FIG. It is disassembled from the board 13. In order to facilitate understanding, the game board 13 is illustrated in a simplified manner.

  As shown in FIG. 10, a specific winning opening 65a is formed along the lower edge of the inner rail 61. Since the lower edge of the inner rail 61 is formed in a downwardly convex curved shape, the arrangement position of the specific winning opening 65a is smaller than that in the case where the lower side of the specific winning opening 65a is formed by a straight line along the left-right direction. Can be lowered downward. The outer edge of the specific winning opening 65a has an upper side formed by the movable upper lid member 332, a lower side formed by the lower edge of the inner rail 61, and left and right sides formed by left and right walls of the opening upper portion 313. .

  As described below, the specific winning opening 65a is switched between the closed state and the open state by sliding the movable upper cover member 332 back and forth, and the opening and closing operation of the specific winning opening 65a is, for example, up to 15 times. Times (15 rounds) can be repeated.

  As shown in FIG. 11, the lower panel unit 300 is a unit that forms an out port 314 from which a ball is discharged and a specific winning port 65 a, and is a receiving unit that is formed in the lower part of the game panel 13 in the front-rear direction. The front unit 310 is fitted into the opening 60a from the front side and fastened and fixed, the front plate member 320 is fastened and fixed to the front unit 310 from the front side and has a ball path formed on the back side, and the receiving opening 60a. And a variable winning device 330 having a movable upper lid member 332 that is fitted and fastened and fixed from the back side and changes the flowing direction of the ball.

  The front side unit 310 includes a plate-shaped main body plate portion 311 formed so that a ball can flow down the front side, and an electric accessory 640a in which a pair of members is opened and closed right and left at the front center of the main body plate portion 311. A plate-shaped inclined plate portion 312 protruding forward from the left and right upper portions of the main body plate portion 311; an upper opening portion 313 recessed upward from a lower bottom portion of the main body plate portion 311; And a pair of out ports 314 that are drilled in the front-rear direction on both left and right sides of the part 313 and that discharge the ball out of the game area.

  The main body plate portion 311 is formed in a front-rear direction at a position surrounded by a first winning opening lower side 311a formed above the electric accessory 640a and forming a lower side of the first winning opening 64 and a pair of members of the electric accessory 640a. A second winning opening 640 provided, a light irradiating device 311b arranged below the second winning opening 640 to illuminate the front side of the second winning opening 640, and a rib-like front outside the out opening 314. And a ball-flowing rib 311c that is protruded.

  The light irradiation device 311b is accommodated in the accommodating recess 323a (see FIG. 12) of the front plate member 320, and is directed upward (to the second winning opening 640 side) due to the ball winning the second winning opening 640. The LED member is irradiated with light.

  The ball flowing rib 311c adjusts the flowing direction of the ball rolling along the inner rail 61, and will be described later in detail with reference to FIG.

  The inclined plate portion 312 is formed so that a ball can roll on the upper side surface, is disposed on the left and right of the electric accessory 640a, and is inclined downward as it approaches the electric accessory 640a. Thus, when the electric accessory 640a is in the open state in which the electric accessory 640a is tilted left and right, the ball that is rolled down by rolling the inclined plate portion 312 can be made to win the second winning opening 640 with a high probability. On the other hand, when the electric accessory 640a is in the closed state in which it stands up, the sphere that rolls down the inclined plate portion 312 can drop with high probability to the front side of the upper opening portion 313.

  The upper opening portion 313 is formed to be inclined upward toward the left and right center. Here, by setting the vertical width of the central portion in the left-right direction of the specific winning opening 65a to be equal to or larger than the diameter of the sphere, the vertical width of the left and right walls of the upper opening portion 313 (corresponding to the left and right walls of the specific winning opening 65a). ) Can be set to a length less than or equal to the diameter of the sphere (see FIG. 17). In this case, it is difficult to make the ball win from the left and right ends of the specific winning opening 65a, but the ball flows down to the center of the game board 13 along the inner rail 61, and the center of the specific winning opening 65a in the left and right direction. , The game can be continued.

  Here, when the upper and lower side surfaces of the specific winning opening 65a are parallel planes (a plane extending in the left-right direction), until the straight line intersecting with the inner rail 61 becomes the same as the length of the lower surface of the specific winning opening 65a. It is necessary to arrange the specific winning opening 65a so as to rise from the lower edge of the inner rail 61. Therefore, the position of the specific winning opening 65a becomes higher.

  On the other hand, in the present embodiment, since the lower side surface of the specific winning opening 65a is formed to be curved similarly to the lower surface of the inner rail 61, it is not necessary to arrange the specific winning opening 65a upward, and the specific winning opening 65a is positioned at a low position. Can be arranged.

  Further, since the upper side surface of the specific winning opening 65a is inclined downward as it approaches the left and right ends, the ball is moved to the specific winning opening 65a as compared with a case where the upper side surface is formed by a plane extending in the left and right direction. Can be lowered downward. Thereby, the lower edge of the third symbol display device 81 can be lowered.

  The out opening 314 is formed as a pair on the left and right sides of the upper opening portion 313, and the lower side of the out opening 314 is disposed below and the upper side of the out opening 314 is disposed above the left and right ends of the upper opening portion 313. You. That is, the upper opening portion 313 is formed below the out opening 314. Thereby, the arrangement of the variable winning device 330 described later can be lowered, and the lower edge of the third symbol display device 81 can be lowered. Note that, even with such an arrangement, in the present embodiment, the sphere flows down the upper surface of the movable upper lid member 332 which has an upper side surface substantially the same as the shape of the upper opening portion 313 and is slid in the front-rear direction. Is discharged to the out port 314 (see FIG. 17), so that the game can be continued.

  The front plate member 320 is a plate-shaped member formed of a light-transmissive resin material, is disposed on the front side of the front unit 310, and is formed so that a sphere can flow between itself and the main body plate portion 311. Plate portion 321, a first winning opening front portion 322 arranged at the upper end of the main body plate portion 321 for guiding the ball to the lower side 311 a of the first winning opening, and disposed below the electric accessory 640 a. The lower part 323 of the electric accessory which is provided, the lower plate 324 of the outer opening disposed along the lower surface of the outlet 314, and the rear side protruding from the main body plate 321 along the lower edge of the inner rail 61. And a ball feeder 325.

  The main body plate portion 321 includes a spherical flow rib 321a protruding in a rib shape on the back side outside the lower opening plate 324. The ball running rib 321a adjusts the flowing direction of the ball rolling along the inner rail 61, and the details will be described later with reference to FIG.

  The electric accessory lower support portion 323 includes a housing recess 323a that is a horizontally long recess, and the light irradiation device 311b is housed in the housing recess 323a.

  The outer mouth lower plate 324 is provided with thin ribs extending in the front-rear direction on the upper side surface in the left-right direction. Further, the out-opening lower plate 324 includes a step portion 324a projecting upward at left and right inner end portions. Due to the unevenness formed on the upper side surface of the out mouth lower plate 324, the flowing ball can be decelerated. The ribs formed on the lower plate 324 are formed to be inclined downward toward the rear side. Thus, the speed at which the flowing ball is discharged to the out port 314 can be improved.

  Since the above-mentioned inclined plate portion 312 is formed directly above the lower plate 324 (see FIG. 17), the ball falling after rolling the inclined plate portion 312 is directed toward the lower plate 324. Falling is suppressed. In other words, the ball that falls after rolling on the inclined plate portion 312 falls inside the left-right direction of the pair of out-opening lower plates 324 (the position where the movable upper lid member 332 is disposed), or Either it falls to the outer end (near the ball-flowing rib 321a and at the boundary between the rib formation range and the rail on which the ball flows). These are both out of the rib formation range. Thus, it is possible to suppress the ball from falling from a high place on the lower plate 324 of the outer opening, and to improve the durability of the lower plate 324 of the outer opening.

  The step portion 324a is a step formed between the out opening 314 and the specific winning opening 65a, and a ball flowing down in the left-right direction and flowing down the upper side surface of the out opening lower plate 324 exceeds the step portion 324a. Thus, it is prevented from flowing down to the center in the left-right direction (see FIG. 17). That is, the ball that flows down from the left and right direction and flows down the upper side surface of the out-port lower plate 324 is guided exclusively to the out-port 314.

  The ball feeder 325 mainly includes a back side surface 325a formed on the back side, and left and right side surfaces 325b connected to the back side surface 325a and formed on the left and right sides.

  The rear side surface 325a is inclined downward toward the rear side, and the left and right side surface 325b is inclined toward the center toward the rear side. Thereby, the falling direction of the sphere that has reached the sphere feeding unit 325 can be directed to the back side. Therefore, it is possible to suppress the ball from staying in front of the specific winning opening 65a, and to prevent a so-called over winning.

  Next, the variable winning device 330 will be described with reference to FIGS. FIG. 13 is an exploded front perspective view of the variable winning device 330, FIG. 14 is an exploded rear perspective view of the variable winning device 330, and FIG. 15 (a) is a top view of the variable winning device 330. 15 (b) is a front view of the variable winning device 330, and FIG. 15 (c) is a side view of the variable winning device 330 as viewed in the direction of the arrow XVc in FIG. 15 (b).

  As shown in FIGS. 13 and 14, the variable winning device 330 includes a main body member 331 that forms a skeleton, a movable upper lid member 332 that is inserted through the main body member 331 from the front, and that is formed to be slidable in the front-rear direction. A rear lid member 334 accommodating a solenoid 333 for generating a driving force for slidingly moving the movable upper lid member 332 and a lever member 334b pivoted by the solenoid 333, and being fastened and fixed to the rear side of the main body member 331. And mainly comprising.

  The main body member 331 is provided with a deformed through hole 331a through which the movable upper lid member 332 is inserted, a lower passage 331b through which a ball won at the specific winning opening 65a flows down, and is disposed below the lower passage 331b and directed upward. A light irradiating device 331c for irradiating light, and a back side housing portion 331d which is a recess formed to be recessed toward the front side on the back side and houses the solenoid 333, the lever member 334b, and the like. .

  As shown in FIGS. 15A and 15B, the deformed through hole 331a is a through hole formed along the shape of the movable upper lid member 332, and is a front side for receiving the front side plate portion 332a. It mainly has an opening 331a1 and a rear opening 331a2 for accommodating the rear plate 332b.

  The front opening 331a1 is a pentagon-shaped dent having a lower side extending horizontally in a front view, and being inclined upward as the upper side goes toward the center, and having left and right sides extending vertically.

  The rear opening 331a2 is an opening formed by cutting off the left and right portions of the front opening 331a1 from the central part on the rear side of the front opening 331a1. That is, the outer shape of the lower side and the upper side of the rear opening 331a2 and the outer shape of the lower side and the upper side of the front opening 331a are not formed in the front-rear direction, but are formed at surface positions. Thereby, the movable upper lid member 332 can be smoothly guided.

  The lower passage 331b is formed as a pair of right and left so as to allow a ball to pass therethrough (see FIG. 18A), and is formed so as to protrude below the lower edge of the inner rail 61. Is provided (see FIG. 15B).

  The light irradiating device 331c is a device that illuminates the lower passage 331b, the plate-shaped portion 332a1, and the like with light, and is disposed below the inner rail 61 (below the receiving opening 60a). Thus, since the devices and the like required for the light irradiation device 331c can be disposed below the inner rail 61, a space on the back side of the game board 13 can be secured, and the third symbol display device 81 (FIG. 2) can be lowered downward.

  The light irradiation device 331c includes a light irradiation unit 331c1 that irradiates light. The light irradiation part 331c1 is formed as a pair of right and left directly below the lower passage 331b, and irradiates light upward.

  The back side housing portion 331d communicates with the front opening portion 331a1 with the rear opening portion 331a2 interposed therebetween.

  The moving upper lid member 332 is a long member formed of a light-transmissive resin material, and includes a front plate portion 332a housed in the front opening 331a1, a rear plate portion 332b housed in the rear opening 331a2. A central rib 332c protruding downward along the central axis of the front plate portion 332a and the rear plate portion 332b, and a connection hole 332d formed vertically in a rear end portion of the rear plate portion 332b. Prepare mainly.

  The front side plate portion 332a is formed in a plate-like portion 332a1 formed in such a manner as to rise and incline toward the center in the left-right direction along the shape of the upper side of the front opening portion 331a1, and is formed in the vertical direction of the plate-like portion 332a1. And a guide rib 332a3 that protrudes downward at the left-right end of the plate-shaped portion 332a1 and extends in the front-rear direction.

  The plate-shaped portion 332a1 includes a front inclined side surface 332a1f that is formed to be inclined downward toward the rear side as it goes downward (see FIG. 16) and that is recessed toward the rear side toward the center in the left-right direction. Since the front inclined side surface 332a1f is formed so as to be concave toward the rear side toward the center in the left-right direction, the ball can flow toward the center side when the ball is sandwiched between the front plate member 320 and the front inclined side surface 332a1f. In addition, it is possible to prevent the sliding operation of the movable upper lid member 332 from being hindered by the ball.

  Since the front inclined side surface 332a1f is formed as a part for reflecting light as described later, a metal film is formed on the front inclined side surface 332a1f or mirror-finished to reflect light effectively. You may. In this embodiment, a tape that reflects light is attached.

  The guide rib 332a3 is formed along the left and right side surfaces of the front opening 331a1 in the assembled state (see FIG. 15), and is in contact with the lower side surface of the front opening 331a1. Thereby, it is possible to suppress the displacement in the left-right direction at the time of sliding movement of the movable upper cover member 332.

  The center rib 332c is formed at a bent portion of the front plate portion 332a formed by bending a plate shape. Thereby, the rigidity of the front side plate part 332a can be improved. Further, when the movable upper lid member 332 is slid forward (when the movable upper lid member 332 of the variable winning device 330 is in the retracted state), the movable upper lid member 332 is fixed to the back side of the upper opening portion 313. Accordingly, it is possible to prevent the movable upper lid member 332 from malfunctioning due to the collision between the center rib 332c and the ball.

  The connection hole 332d is a through hole through which the connection portion 334b4 of the lever member 334b is inserted and the displacement due to the swing of the lever member 334b is transmitted to the movable upper cover member 332 (see FIG. 16).

  The solenoid 333 mainly includes a main body 333a serving as a driving source, and a hook-shaped hook-shaped member 333b disposed below the main body 333a and vertically moved below the lever member 334b.

  The rear cover member 334 mainly includes a plate-shaped main body portion 334a, and a lever member 334b pivotally supported by the main body portion 334a and having a front end formed to be movable in the front-rear direction.

  The lever member 334b includes a main body 334b1 extending vertically and a pair of shafts 334b2 protruding in the left and right directions at the lower end of the main body 334b1 in a columnar shape and supported by the main body 334a. A lower claw portion 334b3 that extends below the main body portion 334b1 at a substantially intermediate position between the pair of shaft portions 334b2 and is formed so as to be able to receive the hook-shaped member 333b between the main body portion 334b1 and the upper end portion of the main body portion 334b1. And a connecting portion 334b4 formed to bulge in a columnar shape.

  Next, the sliding movement of the movable upper cover member 332 will be described with reference to FIG. FIG. 16A is a cross-sectional view of the variable winning device 330 taken along the line XVIa-XVIa in FIG. 15B, and FIG. 16B is a diagram showing the movable upper cover member 332 sliding from the state of FIG. 16A. It is sectional drawing of the variable winning device 330 after it is made to perform. FIG. 16A illustrates a retracted state in which the movable upper lid member 332 is disposed rearward, and FIG. 16B illustrates a protruding state in which the movable upper lid member 332 is disposed forward, and FIG. In order to facilitate understanding of the path E1, the central rib 332c is partially omitted. In FIGS. 16A and 16B, the inner rail 61 and the front plate member 320 in the assembled state (see FIG. 2) are virtually illustrated by imaginary lines.

  As shown in FIG. 16A, when the movable upper lid member 332 is in the retracted state, the hook-shaped member 333b is disposed upward, and the lever member 334b is tilted backward. In this state, the ball can flow down in front of the variable winning device 330, that is, the ball can win (open state) at the specific winning opening 65a (see FIGS. 10 and 17).

  On the other hand, as shown in FIG. 16 (b), when the movable upper cover member 332 is in the overhanging state, the hook member 333b is pressed downward, so that the lever member 334b is tilted forward about the shaft portion 334b2, and The movable upper lid member 332 is slid to the front side while being in contact with the side surface of the side housing portion 331b. In this state, the ball cannot be won (closed state) at the specific winning opening 65a (see FIGS. 10 and 17).

  In this case, the back side surface of the lower end of the hook-shaped member 333b abuts on the end of the lower claw portion 334b3 of the lever member 334b in the front-rear direction, whereby the swing of the lever member 334b is mechanically restricted. (The hook-shaped member 333b is arranged in the moving direction of the lower claw portion 334b3, and the moving direction of the lower claw portion 334b3 is orthogonal to the moving direction of the hook-shaped member 333b). Therefore, the driving force of the solenoid 333 can be suppressed as compared with the case where the swing of the lever member 334b is stopped by the driving force of the solenoid 333.

  Here, the path of the light emitted from the light irradiation device 331c will be described with reference to FIG.

  As shown in FIG. 16A, when the movable upper cover member 332 is in the retracted state, the light emitted upward from the light irradiation unit 331c1 reaches the front inclined side surface 332a1f of the plate-shaped portion 332a1 along the path E1. I do. At this time, since the front inclined side surface 332a1f is formed so as to be inclined rearward as it goes downward, the light emitted from below and reaching the front inclined side surface 332a1f is reflected toward the front (player side). In this case, the player can visually recognize as if the front inclined side surface 332a1f of the movable upper lid member 332 is emitting light. Further, since the light reflected by the front inclined side surface 332a1f is projected on the light projection range E0 of the front plate member 320, the front plate member 320 can be noticed. Thereby, the performance ability of the movable upper lid member 332 and the front plate member 320 can be improved.

  Here, when an LED or the like is arranged on the movable upper cover member 332 to cause the movable upper cover member 332 to emit light, the movable upper cover member 332 may be enlarged. On the other hand, in the present embodiment, since the LED is not provided on the movable upper lid member 332, it is possible to improve the performance of the movable upper lid member 332 as an effect portion while suppressing the movable upper lid member 332 from being enlarged. Can be.

  As shown in FIG. 16B, when the movable upper cover member 332 is in the extended state, the light is emitted upward along the path E2 from the light irradiation unit 331 c 1, and the light traveling toward the front inclined side surface 332 a 1 f is transmitted to the inner rail 61. Does not reach the front inclined side surface 332a1f of the plate portion 332a1. In this case, the light irradiated from the light irradiation unit 331c1 along the path E1 reaches the intermediate position of the plate-shaped portion 332a1 of the front plate portion 332a and only passes through as it is, so the front inclined side surface 332a1f and the front plate member 320 Is visually recognized by the player as dark.

  That is, depending on whether the movable upper lid member 332 is in the retracted state or the extended state, whether or not the light irradiated from the light irradiation unit 331c1 reaches the front inclined side surface 332a1f changes. Whether or not the light projection range E0 of the member 320 is visually recognized changes. Therefore, by checking the state of the brightness of the light projecting range E0 of the front inclined side surface 332a1f and the front plate member 320, it can be confirmed whether or not a ball can be won in the specific winning opening 65a.

  Accordingly, even when the movable upper lid member 332 slides back and forth as in the present embodiment, it is difficult to grasp the change in the state of the movable upper lid member 332 in a front view (FIGS. 17A and 17B). )), It is possible to easily confirm whether or not a ball can be won in the specific winning opening 65a by a change in the brightness of the light projection range E0.

  Here, the movable upper lid member 332 operates to form a closed state that prevents the ball from passing to the specific winning opening 65a and an open state that allows the ball to pass to the specific winning opening 65a ( Only the forward / backward slide movement) changes the brightness state of the projection range E0. In other words, since the state of the light projecting range E0 is changed only by the operation required for the movable upper lid member 332 to continue the game, no additional mechanism is required. In other words, the movable upper lid member 332 can be used for both the purpose of switching whether or not the ball passes through the specific winning opening 65a and the purpose of producing an effect using the light emitted from the light irradiation unit 331c1.

  When the sphere passes through the lower passage 331b and crosses the path E1, the light emitted from the light irradiating unit 331c may be reflected by the sphere to produce an effect. In this case, the vicinity of the inner rail 61 (below the light projection range E0 in FIGS. 16A and 17B) can be brightly illuminated in a front view.

  With reference to FIG. 17, a description will be given of the flow of the ball when the movable upper lid member 332 forms the extended state and when the movable upper lid member 332 forms the retracted state. FIG. 17A and FIG. 17B are partial front views of the game board 13. FIG. 17A illustrates a case where the movable upper lid member 332 forms an overhanging state (see FIG. 16B), and FIG. 17B illustrates a case where the movable upper lid member 332 is in the retracted state (FIG. 16B). 17 (a) is shown. In FIGS. 17 (a) and 17 (b), the main body plate portion 321 of the front plate member 320 is shown in imaginary lines. 17 (a) and 17 (b), whether or not the movable upper lid member 332 is overhanging is shown by the presence or absence of hatching. That is, in FIG. 17 (a) and FIG. 17 (b), the shaded portion is in contact with the front plate member 320 or the front plate is so large that it blocks the passage of a ball between the front plate member 320. This is a portion close to the member 320.

  In the state shown in FIG. 17A, the sphere that falls on the route C2 flows down along the upper side surface of the movable upper lid member 332 and is discharged to the out port 314. In this case, the movable upper lid member 332 may fall down due to the weight of the ball, and when the left and right ends of the movable upper lid member 332 are moved below the step portion 324a, the ball is discharged to the out port 314. You will not be able to play games.

  On the other hand, in the present embodiment, the movable upper lid member 332 has a length several times (about four times as long as that shown in FIG. 16 (b)) the length protruding to the front side of the modified through hole 331a. It is housed in the modified through hole 331a and is formed so as to be able to contact the side surface of the modified through hole 331a in the vertical direction over the front and rear direction of the variable winning device 330. Therefore, by reducing the clearance between the movable upper lid member 332 and the deformed through hole 331a, it is possible to prevent the movable upper lid member 332 from falling down due to the weight of the ball colliding with the movable upper lid member 332. Accordingly, the left and right ends of the movable upper cover member 332 can be formed at the same level as the step 324a, and the nail to the specific winning opening 65a can be lowered. The rim can be lowered.

  As shown in FIG. 17B, when the movable upper lid member 332 is in the retracted state, the ball can flow down to the specific winning opening 65a. At this time, the ball rolling on the route C1 from the left and right along the inner rail 61 collides with the step portion 324a and is discharged to the out opening 314, and the ball falling on the route C2 from above toward the specific winning opening 65a. Rolls on the inner rail 61 and reaches the specific winning opening 65a.

  Here, in the present embodiment, the vertical width of the left and right ends of the specific winning opening 65a is formed to be equal to or less than the diameter of the sphere. That is, the vertical distance from the inner rail 61 at the left and right ends of the movable upper lid member 332 is formed to be equal to or less than the diameter of the sphere. Therefore, the height of the step portion 324a from the inner rail 61 can be reduced, and the arrangement of the out port 314 to which the ball falling from the step portion 324a reaches can also be lowered.

  In this case, it is difficult for the ball to enter from the left and right ends of the specific winning opening 65a (in addition, in the present embodiment, the ball is blocked by the base plate 60). However, since the lower side of the specific winning opening 65a is formed along the inner rail 61, the ball that has flowed to the front side of the left and right ends of the specific winning opening 65a rolls toward the center of the game area along the inner rail 61 by gravity. Is moved, and the ball enters the specific winning opening 65a from there. In addition, since the lower edge of the inner rail 61 is formed to be inclined rearward (see FIG. 16), the ball can smoothly enter the specific winning opening 65a (see FIG. 17).

  Thereby, the movable upper lid member 332 forming the upper side of the specific winning opening 65a is separated upward from the inner rail 61 at least in the vicinity of the center of the game area (near where the inner rail 61 is disposed at the lowest position) or more than the diameter of the ball. It is sufficient to lower the position of the movable upper lid member 332 downward. Therefore, the arrangement position of the variable winning device 330 can be lowered in comparison with the case where it is necessary to be separated upward from the inner rail 61 more than the diameter of the sphere at a position other than the vicinity of the center of the inner rail 61. Thereby, the space on the back side of the game board 13 can be secured, and the lower edge of the third symbol display device 81 (see FIG. 2) can be lowered.

  Next, with reference to FIG. 18, a description will be given of the function of the spherical flow ribs 311c and 321a and the spherical feed portion 325 and the fact that light is collected by the front inclined side surface 332a1f. 18A is a cross-sectional view of the lower panel unit 300 taken along line XVIIIa-XVIIIa in FIG. 17B, and FIG. 18B is a lower panel unit 300 taken along line XVIIIb-XVIIIb in FIG. 17A. 18C is a cross-sectional view of the lower panel unit 300 in which the arrangement of the light irradiation unit 331c1 is virtually changed from FIG. 18B.

  In FIG. 18A, the rolling path of the ball is described by paths C1a, C1b, and C2a, and the movable upper lid member 332 in the retracted state is illustrated by imaginary lines. The moving upper lid member 332 is located on the near side (upper side in FIG. 17B) with respect to the cross section of FIG. 18A, and is not actually visible. FIG. 18 (a) is shown by an imaginary line in a state where the positions (when viewed in the vertical direction) match. 18B and FIG. 18C, three spheres flowing down the lower passage 331b are virtually illustrated.

  The path of a ball that is rolled from the left and right along the inner rail 61 (see FIG. 11) and discharged to the out port 314 will be described. As shown in FIG. 18 (a), the sphere rolling from the left / right direction toward the center of FIG. 18 (a) abuts on at least one of the sphere running rib 311c or the sphere running rib 321a. That is, the sphere rolling while abutting on the main body plate portion 311 of the front unit 310 abuts against the ball-flowing rib 311c, and the sphere rolling while abutting on the main body plate portion 321 of the front plate member 320 is a ball-flowing rib. 321a.

  Here, when the sphere flows and abuts against the rib 311c, the velocity direction of the sphere is directed in the direction along the path C1a, and then abuts on the sphere flowing rib 321a. Therefore, regardless of whether the ball rolls while abutting on the main body plate portion 311 of the front unit 310 or rolls while abutting on the main body plate portion 321 of the front plate member 320, the rolling ball has a longer ball length. It can contact the rib 321a.

  By causing the ball rolling along the inner rail 61 (see FIG. 11) to flow into contact with the rib 321a, the velocity direction of the ball can be directed in the direction along the path C1b. In this case, the velocity of the ball can be directed to the rear side (upward in FIG. 18A) before the ball is arranged on the front side of the out port 314. Therefore, the period from when the ball is arranged on the front side of the out port 314 to when the ball is discharged from the game area can be shortened, and it is possible to suppress the ball from staying on the front side of the out port 314. At the same time, the opening width of the out port 314 can be suppressed. Thereby, when the specific winning opening 65a (see FIG. 10) and the out opening 314 are arranged side by side, the arrangement of the specific winning opening 65a can be lowered below the game area.

  A case where the ball falls between the stepped portions 324a arranged in a pair on the left and right will be described. In this case, the ball that has fallen between the steps 324a rolls toward the center in the left-right direction, and the ball abuts on the left and right side surfaces 325b of the ball feeder 325, so that the velocity direction of the ball is along the path C2a. Change. Thus, the ball can be prevented from staying in front of the specific winning opening 65a (see FIG. 10), so that an over winning can be suppressed.

  When the sphere flows down along the lower passage 331b and crosses the light irradiated from the light irradiation unit 331c1, the sphere blocks the light, so that the light does not reach the front inclined side surface 332a1f. Therefore, it is possible to confirm whether or not the ball has won the specific winning opening 65a (see FIG. 17) based on whether the light projecting range E0 of the front inclined side surface 332a1f or the front plate member 320 is viewed bright or dark. it can.

  Thereby, as in the present embodiment, the front plate member 320 formed of a light-transmitting resin material is disposed in front of the specific winning opening 65a, and the inside of the specific winning opening 65a is difficult to visually recognize. Also, it can be confirmed that the ball has entered the specific winning opening 65a by the change in the brightness of the light projecting range E0. Therefore, it is not necessary to remove the specific winning opening 65a obliquely from above in order to confirm that the ball enters the specific winning opening 65a, and the burden on the player can be reduced.

  In the present embodiment, the irradiation direction of the light irradiated from the light irradiation unit 331c1 and the flow direction of the sphere flowing down the lower passage 331b intersect at an angle close to a right angle (see FIG. 18B). Therefore, compared to the case where the ball flows down in the light traveling direction (see FIG. 18C) or the case where the ball flows down in the light irradiation direction, the ball enters the specific winning opening 65a. The period in which the sphere flowing down the lower passage 331b blocks light can be shortened. In other words, it is possible to lengthen the period in which the light projecting range E0 of the front inclined side surface 332a1f and the front plate member 320 is viewed brightly, and it is possible to secure the performance of the front inclined side surface 332a1f and the front plate member 320.

  As shown in FIG. 18B, when the light path E1 and the flowing direction of the sphere flowing down the lower passage 331b intersect (cross) at an angle close to a right angle, the light path E1 is blocked by the sphere. Thereafter, around the time when the sphere passes through the front end of the lower passage 331b (the right side in FIG. 18B), the light is no longer blocked by the sphere (light reaches the front inclined side surface 332a1f).

  In this case, even if the balls continue to flow down the lower passage 331b, the path E1 is shielded for each ball, so that the change in the brightness of the light projecting range E0 of the front inclined side surface 332a1f and the front plate member 320 is reduced. By confirming, it is possible to confirm the number of balls that have entered the specific winning opening 65a.

  On the other hand, as shown in FIG. 18C, when the light path E3 and the flowing direction of the sphere flowing down the lower passage 331b are close to parallel, after the light path E3 is blocked by the sphere, When the sphere reaches the rear end of the lower passage 331b (left side in FIG. 18C, near the sensor S) and falls downward, light is no longer blocked by the sphere (so that the light reaches the front inclined side surface 332a1f). Become). That is, until then, the light path E3 remains blocked by the sphere.

  In this case, when the balls continue to flow down the lower passage 331b, the light path E3 is blocked by the first sphere (the left sphere in FIG. 18C) as long as the sphere is arranged in the lower passage 331b. Further, after the first ball falls downward from the rear end of the lower passage 331b (left side in FIG. 18 (c)), the light path is changed to the second ball (right side ball in FIG. 18 (c)). E3 is blocked. In addition, when the second ball (the third ball) enters the lower passage 331b when the second ball falls from the rear end of the lower passage 331b, a light path is applied to the lower ball 331b. E3 is blocked. As described above, the sphere continues to block the light path E3, and the sphere is always visually recognized as dark while flowing down the lower passage 331b. That is, the number of times that light is visually recognized or darkly changed does not always match the number of balls entering the specific winning opening 65a, and the number of balls entering the specific winning opening 65a does not always match. Confirmation becomes difficult. On the other hand, the present embodiment has the advantages described above.

  As shown in FIG. 18A, the front inclined side surface 332a1f is formed so as to be depressed toward the rear side toward the center in the left-right direction, so that the light emitted from the pair of left and right light irradiation units 331c1 is irradiated by the front inclined side surface 332a1f. By being reflected, the light is condensed along the path E1 to the center of the front plate member 320, and reaches the light projection range E0 (see FIG. 17B).

  Here, in the present embodiment, since the front plate member 320 is disposed on the front side of the movable upper cover member 332, the specific winning opening 65a can be hidden, while the front inclined side surface 332a1f is visually recognized through the front plate member 320. Therefore, it may be difficult to grasp a change in brightness of the front inclined side surface 332a1f. In that case, it is necessary to increase the intensity of light of a light emitting element such as an LED used for the light irradiation unit 331c1, and there is a problem that light emitting elements that can be used for the light irradiation unit 331c1 are limited.

  On the other hand, the front inclined side surfaces 332a1f converge the light irradiated from the light irradiation unit 331c1 to the center of the front plate member 320, so that the light irradiated from the pair of light irradiation units 331c1 is overlapped, The intensity of light visually recognized in the light projection range E0 can be improved. Therefore, the degree of freedom in selecting a light-emitting element that can be used for the light irradiation section 331c1 can be improved (a light-emitting element with low light intensity can be selected).

  In addition, since the light emitted from the pair of light irradiation units 331c1 is partially overlapped and visible when viewed from the front (see FIG. 17B), the colors of the light are different from each other so that the pair of light irradiation Light of a total of three colors, that is, the color of the light emitted from the unit 331c1 and the color obtained by combining the colors, can be visually recognized in the projection range E0 (see FIG. 17B).

  Here, since the light emitted from each of the pair of light irradiation units 331c1 is shielded by the sphere rolling along the path C2a independently (see FIG. 18), at the timing when the sphere shields the light, The color of light visually recognized in the light projection range E0 can be variously switched.

  For example, in FIG. 18, a case is considered in which “blue” light is emitted from the right light irradiation unit 331c1 and “red” light is emitted from the left light irradiation unit 331c1. In this case, when the movable upper cover member 332 is in the retracted state, the light is emitted from the right side in the order of “blue”, “purple (overlapping portion)”, and “red” in the light emitting range E0 (see FIG. 17B). Is visually recognized.

  In this case, if the sphere rolls on the path C2a on the right side of FIG. 18 to block the light emitted from the light irradiation unit 331c1, the light of “blue” will be blocked. Only the red light is visible.

  On the other hand, when the sphere rolls on the path C2a on the left side of FIG. 18 and blocks the light emitted from the light irradiation unit 331c1, the light of the “red” color is blocked. Only "blue" light is visible.

  As described above, the mode of the light visually recognized in the light projection range E0 can be changed depending on which path the ball rolls and which light from the light irradiation unit 331c1 is blocked. Since the change in the light mode is caused by a ball flowing down the game area along a random path while colliding with a nail or the like, the change in the light mode can be generated at random timing. That is, as compared with a case where the change of the mode of the light irradiated from the light irradiation unit 331c1 is caused by the electronic control, it is possible to perform the effect with more randomness, and it is possible to improve the effect of the effect.

  In the present embodiment, the front inclined side surface 332a1f is formed in a U-shape as viewed from above, but may be formed in a parabolic shape as viewed from above from the viewpoint of condensing light.

  Next, the composite operation unit 400 will be described with reference to FIGS.

  FIG. 19 is a front perspective view of the composite operation unit 400, and FIG. 20 is a rear perspective view of the composite operation unit 400. 19 and 20 illustrate a state in which the main body member 410 of the combined operation unit 400 is disposed at the retracted position, and the drive motor 462 and the fixed plate 461 are not illustrated. In the composite operation unit 400, the guide member 450 and the rear upper plate 470 are fastened and fixed to the bottom wall 211 (see FIG. 6) of the rear case 210.

  FIG. 21 is an exploded front perspective view of the composite operation unit 400, and FIG. 22 is an exploded rear perspective view of the composite operation unit 400. As shown in FIGS. 21 and 22, the composite operation unit 400 has a horizontally-long rectangular main body member 410 which can be slid in the vertical direction, and one end portion of which can be guided at both left and right ends of the main body member 410. A pair of members connected to each other, the other end portions of which are pivotally supported with each other; a swing member 430 disposed so as to be swingable on the center front side of the main body member 410; A pair of leg members 440 which are fastened and fixed at both ends and extend in the vertical direction, a guide member 450 in which a guide hole 452 for guiding the leg member 440 is formed, and a driving force required for moving the leg member 440. A driving device 460 to be generated, a rear upper plate 470 fastened and fixed above the opening 211a of the rear case 210, and a wiring connecting the rear upper plate 470 and the main body member 410 to accommodate wiring therein. Composed mainly comprises a guide arm 480, a.

  FIG. 23 is an exploded front perspective view of the main body member 410, the shielding member 420 and the swing member 430, and FIG. 24 is an exploded rear perspective view of the main body member 410, the shielding member 420 and the swing member 430.

  As shown in FIGS. 23 and 24, the main body member 410 has a plate-like base member 411 formed to be long in the left-right direction, and is provided in both left and right ends of the base member 411 in the front-rear direction, and A long hole-shaped leg insertion hole 412 that is extended, and a direction that is arranged inside the leg insertion hole 412 of the base member 411 in the left-right direction and is drilled in the front-rear direction and rises and leans toward the left-right center axis of the base member 411. And a columnar member extending from the upper end of the base member 411 to the front side, and one end of the wiring guide arm 480 is pivotally supported. An arm shaft support portion 414, a holding portion 415 extending upward from the center in the left-right direction of the base member 411 and having a hook-like tip, and a swing member 430 provided as a pair at a lower end portion of the base member 411. Shaft support hole 431a A supporting portion 416 to be supported, a photosensor 417 disposed in front of the base member 411 to detect the sensor passage portion 435d of the swing member 430, a decorative plate portion 418 formed in a substantially semicircular shape in a front view, Mainly equipped.

  The base member 411 has a shape in which a central portion in the left-right direction hangs downward from both left and right end portions. Thereby, a space can be formed above the center in the left-right direction, and the wiring guide arm 480 can be disposed in the space (see FIG. 29).

  The leg insertion hole 412 is formed in a long hole shape, and the rotation of the leg member 440 with respect to the base member 411 is suppressed by inserting the connection fixing portion 442 (see FIG. 21) of the leg member 440. You. Thereby, the posture of the leg member 440 and the main body member 410 can be stabilized.

  The guide hole 413 is an elongated hole through which the insertion shaft portion 421c of the shielding member 420 is inserted and slid, and has a width slightly larger than the diameter of the insertion shaft portion 421c. Above the guide hole 413, a front cover 413a is provided, which covers the front side of the leg insertion hole 412 and has a side surface facing the guide hole 413 formed along the upper side of the guide hole 413. On the side, a support plate 413b, which is a plate-shaped portion protruding from the front side of the base member 411 and is inclined upward along the guide hole 413, is provided.

  The support plate 413b has an end on the front side in contact with the back surface of the swing base member 421. Thus, the swinging movement of the swing base member 421 is suppressed by the support plate 413b, so that the posture during the movement of the shielding member 420 can be stabilized.

  The arm shaft support portion 414 is disposed on the left side in front view of the center portion of the base member 411. More specifically, the arm shaft support portion 414 is disposed at an intermediate portion between a portion where the upper end portion of the base member 411 starts to drop and a central portion in the left-right direction. Is done. Note that the end (lower end) of the third guide arm 483 (see FIG. 21) of the wiring guide arm 480 is supported by the arm shaft support 414, and a collar member is provided at the tip of the arm shaft support 414. Fastened and fixed.

  The holding portion 415 is a portion that is hooked on a slide lever 473 (see FIG. 21) disposed on the rear upper plate 470. That is, in a state where the main body member 410 is located at the retracted position (see FIG. 29), the upper end of the slide lever 473 and the lower end of the hook-shaped portion of the holding portion 415 are in contact with each other, The downward movement of the main body member 410 is restricted. Note that an inclined surface 415a is formed on the upper surface of the tip portion formed in a hook shape. The inclined surface 415a does not hinder the movement of the main body member 410 even when the main body member 410 is moved to the retracted position with the slide lever 473 extended.

  The decorative plate portion 418 is a decorative portion that is visually recognized in a front view together with the shielding member 420 when the main body member 410 is disposed at the extended position, and in a state where the main body member 410 is disposed at the retracted position (FIG. 29), which is in contact with the lower surface of the contact plate 421d.

  The shielding member 420 includes a swing base member 421 formed in such a manner that ends of a pair of plate members are pivotally supported, and a decorative member whose upper end is fastened and fixed to the front side of the swing base member 421. 422, a pair of connecting members 423 whose one ends are pivotally supported coaxially with the pivot position of the swing base member 421, and a guide on which the other end of the connecting member 423 is pivoted. A guide plate 424 formed with a hole 424b and fastened and fixed to the upper end on the front side of the rear case 210.

  The swing base member 421 is formed of a pair of plate-like members 421 a formed in a substantially arc shape, and is a swing shaft that is coaxially supported by a shaft support hole 423 d formed at one end of the connection member 423. It mainly includes a hole 421b, a pair of left and right insertion shaft portions 421c that are inserted and guided in the guide holes 413 of the main body member 410, and a contact plate 421d that protrudes from the rear side and contacts the upper surface of the main body member 410. .

  The swing shaft hole 421b is a portion that serves as a swing shaft of the pair of plate members 421a, while a shaft support rod 423c inserted through one end of the connection member 423 is penetrated and supported by the connection member 423. It is.

  Since the insertion shaft portion 421c is inserted into the guide hole 413 of the main body member 410, the left and right ends of the shielding member 420 are moved as the main body member 410 is moved downward from the intermediate position (see FIG. 30). It is moved close to the center in the left-right direction.

  The contact plate 421d is a curved surface projecting rearward from the plate-shaped member 421a, and is formed along the shape of the upper surface of the decorative plate portion 418. As a result, the upper surface of the main body member 410 and the lower surface of the contact plate 421d are brought into contact at the retracted position.

  The decorative member 422 includes a pair of thick portions 422 a disposed on the front side of the swing base member 421, and a portion formed below the swing base member 421 in a front view, and a lower end portion. And a hanging portion 422b formed to be curved backward from the swing base member 421.

  The hanging portion 422b is arranged closer to the main body member 410 than the swing base member 421.

  The connecting member 423 is formed of a pair of rod members 423a bent in a U-shape at the bending portion 423b, and includes a pivot rod 423c. One end of the rod member 423a has a pivot rod 423c. A shaft support hole 423d through which is inserted is formed, and a slide shaft portion 423e that is inserted into and guided by the guide hole 424b of the guide plate 424 is formed at the other end of the rod member 423a.

  The bent portion 423b is bent above a straight line connecting the shaft support hole 423d and the slide shaft portion 423e. That is, the bent portion 423b is disposed farther from the swing base member 421 than the straight line connecting the shaft support hole 423d and the slide shaft portion 423e. Therefore, a large space can be secured between the swing base member 421 and the connecting member 423, and the degree of freedom in designing the swing base member 421 can be improved.

  The slide shaft portion 423e is formed from a cylindrical portion inserted into the guide hole 424b, and a disk-shaped collar member fastened and fixed to the tip of the cylindrical portion.

  The guide plate 424 includes a base plate 424a that is fastened and fixed to the rear case 210, and a pair of guide holes 424b that are formed in left and right end portions of the base plate 424a in the front-rear direction and extend in the left-right direction. , Mainly comprising. A pair of guide holes 424b are formed at the same height.

  The guide hole 424b is formed in the left-right direction, that is, the direction along the upper outer edge of the opening 211a of the rear case 210. Therefore, the width required for the guide plate 424 to guide the connecting member 423 can be suppressed. In this case, since the guide plate 424 can be disposed at a position farther from the third symbol display device 81, the shielding member 420 can be formed larger accordingly.

  The oscillating member 430 is a member pivotally supported by the shaft supporting portion 416, and includes a main body member 431 that is oscillated and a base that is provided to protrude toward the front side of the center of the base member 411. A member 432, a drive motor 433 fastened and fixed to the base member 432 to generate a drive force for driving the main body member 431, a drive gear 434 supported by the drive motor 433, and meshed with the drive gear 434. A transmission gear 435 pivotally supported above the base member 432 with respect to the drive gear 434, and a connection member 436 connecting the connection shaft 435c of the transmission gear 435 and the connection shaft 431b of the main body member 431. Prepare for.

  The main body member 431 is a member in which a hemispherical decorative part is formed on the front side. And a connection shaft 431b that is disposed at the center on the side and that is supported at one end of the connection member 436.

  The connection shaft 431b is disposed on the rear side of the main body member 431 at a position closer to the shaft support hole 431a than the end on the opposite side (upper side) of the shaft support hole 431a. Accordingly, the moving width of the upper end of the main body member 431 can be made larger than the moving width in which the connecting member 436 is actually moved back and forth.

  The transmission gear 435 is supported by the base member 432 and extends substantially half way around the main body 435a where a gear meshing with the drive gear 434 is formed, and extends to the opposite side of the gear formed on the main body 435a. Overhang 435b, a cylindrical connecting shaft 435c projecting rightward from the front end of the overhang 435b, and formed along the left front side of the overhang 435b. And a sensor passage portion 435d (see FIG. 34), which is formed in a fan shape when viewed in the left-right direction and whose peripheral portion passes through the photosensor 417.

  The connection member 436 is a rod-shaped member having holes parallel to each other at both ends. The connection member 436 includes a one-side connection hole 436a that is formed at one end and is supported by the connection shaft 431b of the main body member 431. And a second connection hole 436b which is bored at the other end and is supported by the connection shaft 435c of the transmission gear 435.

  Returning to FIG. 21 and FIG. The arm member 440 is formed of a long plate-shaped main body 441 having a pair extending in the vertical direction, and a long hole having a cross section protruding from the upper end of the main body 441 to the front side being long in the vertical direction. A coupling fixing portion 442, a pair of insertion shaft portions 443 protruding rearward from upper and lower ends of the main body 441 and inserted through the guide holes 452 of the guide member 450, and a front side from the lower end of the main body 441. A locking portion 444 that protrudes from the rear case 210 and a locking portion 444 where one end of the biasing spring 445 is locked, and the other end of the biasing spring 445 whose one end is locked to the locking portion 444. And a holding and fixing portion 446 fastened and fixed to the front side.

  The main body portion 441 has a rack gear 441a engraved on a side surface facing the main body member 410, and the rack gear 441a is meshed with the drive gear 463 of the drive device 460. The force is transmitted to the leg member 440.

  The insertion shaft portion 443 is formed in a vertically long hole shape and is inserted into the guide hole 452 of the guide member 450 extending vertically, so that the posture of the leg member 440 with respect to the guide member 450 is stabilized. Can be. Further, since the insertion shaft portion 443 is formed as a pair of upper and lower portions, the posture of the leg member 440 with respect to the guide member 450 can be stabilized.

  The urging spring 445 generates an urging force for moving the leg member 440 toward the retracted position (see FIG. 19). At this time, the other end of the biasing spring 445 functions as a fixed-side end locked by the holding and fixing portion 446, and one end functions as a moving-side end locked by the locking portion 444.

  The guide member 450 includes a main body member 451 which is a vertically long plate member arranged in a pair of left and right, and a long hole formed in the main body member 451 in a pair of upper and lower sides in the front and rear direction and extending in the vertical direction. , A pair of fixing portions 453 for fixing the driving device 460 at the center in the vertical direction of the main body member 451, and the leg member 440 disposed at the front side of the upper end portion of the main body member 451 and the retracted position ( (See FIG. 19) and a cover member 454 disposed on the front side of the leg member 440.

  The driving device 460 has a shape in which the side close to the main body member 410 is lowered one step backward, the side close to the main body member 410 is fixed to the fixing portion 453 of the guide member 450, and the opposite side is the fastening portion 212b ( Mainly includes a fixing plate 461 fixed to the fixing plate 461, a driving motor 462 fastened and fixed to the fixing plate 461, and a driving gear 463 supported by the driving motor 462.

  Since the fixing plate 461 has a shape in which the side away from the main body member 410 is raised by one step toward the front side, a gap surrounded by the rear case 210 and the fixing plate 461 may be formed on the side away from the main body member 410. it can. Here, when the urging springs 445 are arranged on the left and right sides of the leg member 440, the width of the leg members 440 including the urging springs 4454 in the left and right direction is increased, whereby the left and right width of the opening 211a is reduced. I was In the present embodiment, the biasing spring 445 can be provided in a gap (formed on the front side of the leg member 440) surrounded by the rear case 210 and the fixing plate 461, and the left and right sides of the leg member 440 are correspondingly arranged. Space in the direction can be suppressed.

  The rear upper plate 470 is a member fastened and fixed to a bottom wall portion 211 (see FIG. 6) formed above the opening 211a of the rear case 210, and includes a plate-shaped main body portion 471 and the main body portion 471. A column-shaped shaft support portion 472 protruding from the upper left end in front view to the front side, a slide lever 473 elongated in the left-right direction provided in the center of the main body portion 471, and the slide lever 473 is arranged in the left-right direction. And a front cover 475 fastened and fixed to the main body 471 so as to cover the front side of the slide lever 473.

  The shaft support portion 472 is a portion on which the one-side cylindrical portion 481b (see FIG. 25) of the wiring guide arm 480 is supported, and a collar member C is fastened and fixed to the tip. The wiring to be introduced into the main body member 410 is disposed so as to pass through the vicinity of the shaft support 472.

  The slide lever 473 is a member that is in contact with the lower surface of the holding portion 415 of the main body member 410 in a state where the main body member 410 is located at the retracted position (see FIG. 29), and prevents the main body member 410 from moving downward. is there. An inclined surface 473a is formed on the lower surface of the tip of the slide lever 473. The contact between the inclined surface 473a and the inclined surface 415a of the main body member 410 makes it possible to suppress the resistance generated between the contact surfaces.

  The overhang of the slide lever 473 is changed depending on whether or not electricity is conducted to the solenoid 474. For example, when the electricity is conducted, the slide lever 473 projects leftward when viewed from the front. If the electricity is conducted, the slide lever 473 is brought into contact with the lower surface of the holding portion 415, and the body member 410 Is prevented from moving downward (see FIG. 29). On the other hand, when the electricity is not conducted, the slide lever 473 does not contact the holding portion 415, and the main body member 410 can be moved downward.

  Here, it is conceivable that the solenoid 474 is driven as the main body member 410 is disposed at the retracted position, and the slide lever 473 comes into contact with the holding portion 415. However, in this case, the driving force from the driving device 460 cannot be released until the solenoid 474 moves the slide lever 473 after the main body member 410 is disposed at the retracted position. Therefore, when changing the operation of the driving device 460 by detecting the arrangement of the main body member 410, it is necessary to control the driving device 460 in consideration of the time for the solenoid 474 to move the slide lever 473, which is difficult to control. It becomes.

  On the other hand, in the present embodiment, the inclined surface 415a of the holding portion 415 is arranged to face the inclined surface 473a of the slide lever 473 by moving the main body member 410 upward with the slide lever 473 extended (FIG. 31). ), And the slide lever 473 is pushed back. When the main body member 410 is located at the retracted position and the contact between the holding portion 415 and the slide lever 473 in the longitudinal direction of the slide lever 473 is released, the slide lever 473 projects again and the lower surface of the holding portion 415 and the slide lever The upper surface of the 473 is in contact with the upper surface (see FIG. 29). Accordingly, regardless of the arrangement of the main body member 410, by keeping the slide lever in the extended state, the downward movement after the main body member 410 is moved to the retracted position can be prevented. Therefore, control of the driving device 460 becomes easy.

  The front cover 475 is a member in which a slide groove 475a, which is a concave groove for guiding the slide lever 473, is formed along the left and right direction on the back surface. The slide lever 473 is slid by the slide groove 475a of the front cover 475. The displacement in the vertical direction during the movement is suppressed.

  The wiring guide arm 480 is a movable mechanism that is formed of a resin material and guides the wiring W from the rear upper plate 470 fastened and fixed to the rear case 210 to the main body member 410. A first guide arm 481 in which one side cylindrical portion 481b to be formed is pivotally supported by the shaft support portion 472, and a second guide arm 482 in which the other end of the first guide arm 481 is pivotally supported at one end. And a third guide arm 483 that pivotally supports the other end of the second guide arm 482 at one end and the other end is pivotally supported by the arm shaft support 414.

  Here, the wiring W is an electric wiring (for example, a flat harness) formed in a belt shape (widely formed in the direction perpendicular to the paper surface of FIG. 27). The length of the second guide arm 482 in the longitudinal direction is shorter than the diameter of the collar member C than the first guide arm 481, and the length of the third guide arm 483 is longer than that of the second guide arm 482. Is shorter than the diameter of the collar member C.

  The wiring guide arm 480 is configured to be able to accommodate the wiring W therein, and is a member that prevents the wiring W from being broken and disconnected. Accordingly, it is not necessary to arrange the wiring W introduced into the main body member 410 through the leg members 440, and it is possible to suppress a space for disposing the leg members 440. Therefore, the opening 211a can be enlarged in the left-right direction.

  Next, the first guide arm 481 and the second guide arm 482 will be described with reference to FIGS. Note that the third guide arm 483 is configured as a technical idea including the ones described for the first guide arm 481 and the second guide arm 482, and thus the description thereof is omitted here.

  FIG. 25 (a) is a front view of the first guide arm 481, FIG. 25 (b) is a bottom view of the first guide arm 481, and FIG. 25 (c) is XXVc of FIG. 25 (a). It is sectional drawing of the 1st guide arm 481 in the -XXVc line, and FIG.25 (d) is sectional drawing of the 1st guide arm 481 in the XXVd-XXVd line of FIG.25 (a).

  As shown in FIGS. 25A to 25D, the first guide arm 481 includes a plate-shaped arm portion 481a formed in a long plate shape, and a left end of the plate-shaped arm portion 481a when viewed from the front. The axis is disposed on the vertical line of the lower bottom surface (the lower side surface in FIG. 25A) of the plate-shaped arm portion 481a, and the one-side cylindrical portion 481b extending in the front-rear direction, and the plate-shaped arm portion At the end opposite to the one-side tubular portion 481b among the ends of the one-side tubular portion 481a, an axis is arranged on a vertical line on the lower bottom surface of the plate-shaped arm portion 481a and the other-side tubular portion extending in the front-rear direction. 481c, an attachment portion 481d formed in a plate shape at a predetermined interval above the plate-shaped arm portion 481a, a bottom portion 481e connecting the plate-shaped arm portion 481a and the attachment portion 481d on the back side, and an attachment portion 481d. Front locking portion 481 extending from the front side surface to plate-shaped arm portion 481a And, mainly includes the.

  The wiring W is inserted through the inside of the concave cross-section formed by the plate-shaped arm portion 481a, the attachment portion 481d, and the bottom portion 481e (see FIG. 27). Accordingly, it is possible to suppress the wiring W from being rubbed with other members or being sandwiched by other members.

  The plate-shaped arm portion 481a has a cutout portion 481a1 formed at a portion facing the front locking portion 481f, and the plate-shaped arm portion 481a has a reduced thickness at the portion where the cutout portion 481a1 is formed. .

  The cutout portion 481a1 is a recess formed in the plate-shaped arm portion 481a in a shape slightly larger than the front locking portion 481f in a front view, and is formed across the width of the plate-shaped arm portion 481a. Note that the formation of the bottom portion 481e is omitted in the portion where the notch portion 481a1 is formed (the bottom portion 481e is formed to penetrate).

  By configuring the notch portion 481a1 as described above, the first guide arm 481 can be easily manufactured by die molding (by one-way die cutting). Further, by inserting the wiring W from the notch 481a1, the wiring W can be easily accommodated in the first guide arm 481.

  The portion of the plate-like arm portion 481a other than the portion where the notch portion 481a1 is formed has a shorter interval with the attachment portion 481d than the overhang width of the front locking portion 481f. Therefore, in a state where the wiring W is accommodated in the first guide arm 481 and is extended in the longitudinal direction (see FIG. 27A), it is possible to prevent the wiring W from dropping to the front side (FIG. 27A). Can be prevented.

  The plate-shaped arm portion 481a includes a rib portion N formed in a rib shape in the width direction on a side surface facing the attachment portion 481d. The rib portion N is formed in the vicinity of the other cylindrical portion 481c that is pivotally supported by the second guide arm 482, and a rib protruding from the second guide arm 482 at an intermediate portion of the plate-like arm portion 481a. The portions N are formed alternately.

  The other-side cylindrical portion 481c includes an enlarged-diameter portion 481c1 whose inner diameter is partially increased. In order to form an overlap margin with the second guide arm, the rear-side end surface is closer to the front than the bottom portion 481e. It is formed (see FIG. 25B).

  The enlarged diameter portion 481c1 is formed over a half circumference (upper half circumference in FIG. 25 (a)) on the inner peripheral side of the other cylindrical portion 481c, and is formed from the other bottom portion 481e2 of the other cylindrical portion 481c. The depression is formed to a length that is approximately half the length of the cylinder of the side cylindrical portion 481c (see FIG. 25C).

  The attachment portion 481d includes an arc-shaped attachment portion 481d1 formed as an arc coaxial with the other-side tubular portion 481c around the other-side tubular portion 481c, and is extended forward from the plate-shaped arm portion 481a. . Thereby, even when the flat locking portion 481f is formed, a gap for inserting the wiring from the front side can be secured.

  The attachment portion 481d includes a rib portion N formed in a rib shape in the width direction on a side surface facing the plate-shaped arm portion 481a. The rib portion N is formed at an intermediate position between the rib portions N projecting from the plate-shaped arm portion 481a at an intermediate portion of the attachment portion 481d.

  The arcuate attachment portion 481d1 is formed with a radius larger than the radius of the substantially arcuate shape formed when the wiring W is bent outward (upper right in FIG. 27B) of the other cylindrical portion 481c. You.

  Further, since the wiring guide arm 480 is formed at the upper end inside the rear case 210 (see FIG. 7), when replacing or performing maintenance of the wiring W, the wiring is attached along a route not blocked by the rear case 210. Need to be removed. In the present embodiment, the attachment portion 481d close to the upper wall surface of the rear case 210 is formed so as to protrude forward from the plate-shaped arm portion 481a separated from the upper wall surface of the rear case 210. Therefore, for example, when removing the wiring W, the wiring W may be pulled out to the front side and pulled out in the direction from the attachment portion 481d toward the plate-shaped arm portion 481a. It will not be. The wiring may be inserted in the opposite direction. Therefore, the maintainability of the replacement of the wiring W can be improved.

  The bottom portion 481e is disposed above the one-side cylindrical portion 481b and formed in a fan shape around the axis of the one-side cylindrical portion, and is disposed above the other-side cylindrical portion 481c. And a bottom portion 481e2 formed in a fan shape centered on an axis spaced apart from the axis of the side cylindrical portion 481c by a predetermined distance. Note that the end of the arcuate attachment portion 481d1 is formed to the left in front view than the end of the other-side bottom portion 481e2.

  The planar locking portion 481f is a claw-shaped member that prevents the wiring W from falling off from the front side. That is, the wiring W is formed with a width shorter than the length from the bottom portion 481e to the front locking portion 481f.

  26 (a) is a front view of the second guide arm 482, FIG. 26 (b) is a bottom view of the second guide arm 482, and FIG. 26 (c) is XXVIc of FIG. 26 (a). FIG. 26D is a cross-sectional view of the second guide arm 482 taken along line XXVIc, and FIG. 26D is a cross-sectional view of the second guide arm 482 taken along line XXVId-XXVId in FIG.

  As shown in FIGS. 26 (a) to 26 (d), the second guide arm 482 has a plurality of configurations having the same technical concept as the first guide arm 481, and the description of the configuration is omitted. I do. That is, the plate-like arm portion 481a is on the plate-like arm portion 482a, the other-side tubular portion 481c is on the other-side tubular portion 482c, the attachment portion 481d is on the attachment portion 482d, the bottom portion 481e is on the bottom portion 482e, and the front locking portion. 481f respectively correspond to the front locking portions 482f.

  The plate-shaped arm portion 482a includes a cutout portion 482a2 at a portion facing the front locking portion 482f. The technical idea of the notch 482a2 is the same as the technical idea of the notch 481a1, and a description thereof will be omitted.

  The plate-shaped arm portion 482a and the attachment portion 482d include a rib portion N on the side surface facing each other. A rib portion N is formed in the attachment portion 482d in the vicinity of one side pivot portion 482b that is pivotally supported by the first guide arm 481. In the middle portion of the second guide arm 482, the rib portion N is formed by the plate-shaped arm portion 482a. And the attachment portion 482d.

  The second guide arm 482 has a one-side support 482b, which is formed in a columnar shape from the upper right portion of the bottom portion 482e to the front side and has a fastening portion formed at the end thereof, and the one-side support 482b as an axis. One bottom 482e1 formed in a substantially circular arc shape and extending on the same plane from the bottom 482e, and the right end of the plate-like arm 482a protruding from the vicinity of the outer periphery of the one bottom 482e1 to the front side. And an arc-shaped plate portion 482a1 connected to the main body.

  The arc-shaped plate portion 482a1 is formed with a radius larger than the radius of the substantially arc-shaped shape formed when the wiring W is bent outward (upper right in FIG. 27B) of the other cylindrical portion 481c. You.

  The one-side shaft support portion 482b is a portion where the reduced diameter portion 482b1 is formed and the other side cylindrical portion 481c of the first guide arm 481 is inserted, and the front side surface of the one side bottom portion 482e1 is the other side cylindrical portion. It is formed so as to be able to contact the rear side surface of the shape portion 481c. Therefore, in the assembled state (see FIG. 27), the bottom portions 481e and 482e are formed on the same plane, and the bottom portions 481e and 482e can contact each other in the respective rotation directions of the first guide arm 481 and the second guide arm 482. It is formed. Therefore, excessive rotation of the first guide arm 481 and the second guide arm 482 can be prevented, and the wiring W can be prevented from being excessively bent (see FIG. 27).

  The reduced-diameter portion 482b1 is formed over a half circumference (a lower half circumference in FIG. 26A) on the outer peripheral side of the one-side shaft support portion 482b, and the one-side shaft support portion 482b has one side shaft from the one bottom portion 482e1 side. The depression is formed to a length approximately half the length of the support portion 482b (see FIG. 26C).

  Next, the swing of the second guide arm 482 with respect to the first guide arm 481 will be described with reference to FIG. FIGS. 27A and 27B are front views of the first guide arm 481, the second guide arm 482, and the wiring W. FIG. 27A illustrates a state in which the second guide arm 482 is folded with respect to the first guide arm 481 (corresponding to the state in FIG. 29), and FIG. The state where the second guide arm 482 is swung counterclockwise from the state of a) to the end of the movable range in which the second guide arm 482 can swing with respect to the first guide arm 481 (corresponding to the state of FIG. 33). Illustrated. In FIG. 27 (b), one side bottom portion 482e1 of the second guide arm 482 and the other side bottom portion 481e2 of the first guide arm 481 are in contact with each other, thereby preventing the second guide arm 482 from further swinging. Is done.

  As shown in FIG. 27 (a), the wiring W is formed by a concave portion (FIG. 25 (d) and FIG. 26 (d) formed by the plate-shaped arm portions 481a and 482a, the attachment portions 481d and 482d, and the bottom portions 481e and 482e. ) See). Therefore, due to the rigidity of the first guide arm 481 or the second guide arm 482, it is possible to prevent the wiring W from being bent to such a degree that the wiring W is disconnected during the movement of the main body member 410.

  In addition, at the pivotal support positions of the first guide arm 481 and the second guide arm 482 (the right end in FIG. 27A), the wiring W is disposed so as to wrap around the other-side cylindrical portion 481c. Therefore, at the pivotal support positions of the first guide arm 481 and the second guide arm 482, the wiring W is suppressed from being bent with a radius of curvature equal to or smaller than the diameter of the other cylindrical portion 481c. Therefore, it is possible to prevent the wiring W from being bent, and it is possible to suppress disconnection of the wiring W.

  The state of FIG. 27A corresponds to the state illustrated in FIG. 29, that is, the state where the main body member 410 is located at the retracted position. As for the speed at which the main body member 410 is moved from the retreat position to the overhang position, the higher the speed, the easier it is to improve the effect. When starting the main body member 410 from a state where the main body member 410 is stopped at the retracted position, it is necessary that the driving device 460 generate a driving force that exceeds the inertial force of the main body member 410 and the inertial force of the wiring guide arm 480. Therefore, in the state of FIG. 27A, it is desirable that the rotation resistance of the first guide arm 481 and the second guide arm 482 constituting the wiring guide arm 480 at the pivotal support position be small.

  In the present embodiment, as shown in FIG. 27A, in a state where the second guide arm 482 is folded with respect to the first guide arm 481, the enlarged diameter portion 481c1 and the enlarged diameter portion 481c1 around the axis of the one cylindrical portion 481b. The reduced diameter portion 482b1 surrounds. The enlarged diameter portion 481c1 and the reduced diameter portion 482b1 are portions that are depressed in a direction away from a counterpart member forming a pivotal relationship, and have an effect of suppressing rotational friction during rotation of the shaft. In a state in which the second guide arm 482 is folded with respect to the first guide arm 481, the enlarged diameter portion 481c1 and the reduced diameter portion 482b1 are formed around the entire circumference of the one cylindrical portion 481b. Therefore, resistance when rotating the second guide arm 482 with respect to the first guide arm 481 is suppressed.

  On the other hand, in the state of FIG. 27B, the range in which the enlarged-diameter portion 481c1 and the reduced-diameter portion 482b1 are arranged around the axis of the one-side cylindrical portion 481b is substantially half a circumference (FIG. 27B: upper half circumference). ). As shown in FIG. 27B, the large-diameter portion 481c1 and the small-diameter portion 482b1 mostly overlap. In this case, the rotational resistance of the first guide arm 481 and the second guide arm 482 can be increased as compared with the state shown in FIG.

  From the state in which the second guide arm 482 is folded with respect to the first guide arm 481, the larger the diameter-increasing portion 481c1 and the diameter-reducing portion 482b1 overlap as the second guide arm 482 is rotated with respect to the first guide arm 481. And the rotational resistance of the first guide arm 481 and the second guide arm 482 increases. That is, as the second guide arm 482 is rotated with respect to the first guide arm 481, the speed of the second guide arm 482 can be reduced.

  Therefore, the speed at which the other side bottom portion 481e2 and one side bottom portion 482e1 come into contact with each other can be reduced, and the first guide arm 481 and the second guide arm 482 make the other side bottom portion 481e2 and the one side bottom portion 482e1 come into contact with each other. The load received by contact can be suppressed. As a result, the durability of the first guide arm 481 and the second guide arm 482 can be improved, and the first guide arm 481 and the second guide arm 482 are urged to the opposite sides (the second guide arm 482 is It can be prevented from bending toward the side further rotated counterclockwise from the state (b).

  In the present embodiment, since the wiring guide arm 480 is formed by three members being pivotally supported, the moving speed of the wiring guide arm 480 is variable even when the moving speed of the main body member 410 is constant. can do.

  For example, in a state where the main body member 410 is disposed at the extended position (see FIG. 33), the posture of the wiring guide arm 480 is not limited to one way, and the third guide arm 483 can rotate upward (posture). Changeable) is changeable. Therefore, the movement speed of the first guide arm 481 can be adjusted by changing the posture of the third guide arm 483 even while the main body member 410 is moving. Therefore, even if the moving speed of the wiring guide arm 480 is changed during the movement of the main body member 410, it is not necessary to change the moving speed of the main body member 410 accordingly.

  As shown in FIG. 27B, when the other-side bottom portion 481e2 and the one-side bottom portion 482e1 come into contact with each other, a gap is formed between the arc-shaped attachment portion 481d1 and the arc-shaped plate portion 482a1. Even if the wiring W is bent to the outside of the other cylindrical portion 481c (upper right in FIG. 27B) due to this gap, the wiring W is sandwiched between the arc-shaped attachment portion 481d1 and the arc-shaped plate portion 482a1. Can be prevented, and disconnection of the wiring W can be prevented.

  As shown in FIG. 27B, when the wiring guide arm 480 is in the open state, the wiring W largely moves to the outside of the other cylindrical portion 481c, and particularly, the first guide arm 481 and the second guide The wiring W is likely to be displaced near the end of the arm 482 (supporting position). When the wiring W is repeatedly displaced with respect to the first guide arm 481 and the second guide arm 482, the wiring W rubs against the inner surfaces of the first guide arm 481 and the second guide arm 482, and the durability of the wiring W is increased. There is a possibility that the property is reduced.

  On the other hand, in the present embodiment, the wiring W and the first guide arm 481 and the rib W formed on the inner surface of the first guide arm 481 and the second guide arm 482 are hooked on the wiring W. The resistance with the second guide arm 482 can be improved, and the displacement of the wiring W can be suppressed.

  In the vicinity of the pivotal support positions of the first guide arm 481 and the second guide arm 482, the wiring W is effective by forming the rib portion N on the side surface opposite to the direction in which the wiring W separates from the other cylindrical portion 481c. Can be supported. That is, for example, the portion of the wiring W extending from the connecting position of the arc-shaped attachment portions 481d1 to the attachment portion 481d is pressed against the plate-shaped arm portion 481a along the shape of the arc-shaped attachment portion 481d1. . Therefore, by forming the rib portion N at the pressed portion, the resistance between the wiring W and the plate-shaped arm portion 481a can be increased.

  In addition, the side surface of the portion near the pivotal support position of the plate-shaped arm portion 481a against which the wiring W is pressed is curved and depressed to the opposite side of the attachment portion 481d, so that the wiring W is fitted into the depression. The displacement between W and the plate-shaped arm portion 481a can be suppressed. In this case, since the surface of the curved dent and the wiring W come into surface contact with each other, the local wear of the wiring W is suppressed as compared with the case where the wiring W receives resistance at the point contact from the rib portion N. Can be.

  Further, the distance between the plate-shaped arm portion 481a and the attachment portion 481d may be increased near the pivotal support position. For example, the attachment portion 481d may be inclined in such a manner as to move away from the plate-shaped arm portion 481a as the front engagement portion 481f on the right side in FIG. 27B approaches the other cylindrical portion 481c. In this case, the slack of the wiring W in the vicinity of the support portion is obtained by bending the wiring W by a portion where the distance between the attachment portion 481d and the plate-shaped arm portion 481a is widened (a portion near the other cylindrical portion 481c). The wiring W can be absorbed, and the displacement of the wiring W at the intermediate portion of the first guide arm 481 (the portion sandwiched between the front locking portions 481f) can be suppressed (the wiring W cancels the slack near the supporting portion). Therefore, displacement of the first guide arm 481 in the longitudinal direction can be suppressed). Therefore, it is possible to prevent the wiring W from rubbing against the inner side surface of the first guide arm 481 and to be worn, thereby improving the durability of the wiring W.

  In an intermediate portion between the first guide arm 481 and the second guide arm 482, the rib portions N are alternately formed on the inner side surfaces opposed to each other. Therefore, compared to the case where the rib portion N is formed only on one of the inner surfaces facing each other, the wiring W can be more easily hooked on more rib portions N. Thereby, the resistance between the wiring W and the first guide arm 481 and the second guide arm 482 can be increased, and the displacement between the wiring W and the first guide arm 481 and the second guide arm 482 is suppressed. can do.

  In FIG. 27, a disk-shaped collar member C fastened and fixed to the front side of the wiring guide arm 480 is illustrated by imaginary lines. The collar member C is fastened and fixed to, for example, the tip of the one-side shaft support 482b or the tip of the shaft support 472 (see FIG. 21) inserted into the one-side cylindrical portion 481b, and the front of each of the cylindrical portions 481b, 481c. It is a member that prevents movement to the side.

  In this embodiment, the collar member C extends to a position where at least a part thereof overlaps with the adjacent attachment portions 481d and 482d in a front view, or does not overlap with the attachment members 481d and 482d in a front view. 482d to a position where the wiring W does not fall off. For example, at the left end of FIG. 27B, a gap is formed between the collar member C and the attachment portion 481d, but the wiring W is separated from the one-side tubular portion 481b (the portion where the wiring W is deformed outward). Therefore, there is little possibility that the wiring W falls off from the gap. That is, since the collar member C is extended so as to overlap with the wiring W when viewed from the front (FIG. 27), it has a diameter sufficient to prevent the wiring W from falling off. This prevents the wiring W from dropping from the wiring guide arm 480.

  Here, assuming that the first guide arm 481 and the second guide arm 482 are formed to have the same length, the collar member C abuts when the first guide arm 481 and the second guide arm 482 are folded, It cannot be folded. On the other hand, in the present embodiment, the first guide arm 481 and the second guide arm 482 have different longitudinal lengths. That is, in a state where the first guide arm 481 and the second guide arm 482 are folded until their extending directions are parallel to each other (see FIG. 27A), the first guide arm 481 and the second guide arm 482 are arranged on the front side of the one-side cylindrical portion 481b. The collar member C provided is different from the collar member C provided on the front side of the other cylindrical portion 482c to such an extent that the collar member C does not interfere with the other.

  Thus, by disposing the collar member C, it is possible to suppress the wiring W from falling off from the wiring guide arm 480, and to suppress the arrangement space by folding the wiring guide arm 480. It is desirable that the lengths of the first guide arm 481 and the second guide arm 482 in the longitudinal direction (the length up to the axis of the collar member C) be different from the diameter of the collar member C or more.

  Next, the operation of the composite operation unit 400 will be described. First, with reference to FIGS. 28 to 33, a change in the posture of the shielding member 420 with respect to the sliding movement of the main body member 410 will be described.

  28 is a front view of the combined operation unit 400, FIG. 29 is a rear view of the combined operation unit 400, FIG. 30 is a front view of the combined operation unit 400, and FIG. 32 is a front view of the composite operation unit 400, and FIG. 33 is a rear view of the composite operation unit 400.

  28 and 29 illustrate a state in which the main body member 410 is disposed at the retracted position. In FIGS. 30 and 31, the posture of the swing base member 421 with respect to the main body member 410 from the state illustrated in FIGS. 28 and 29. The state where the main body member 410 is arranged at an intermediate position where the slide shaft portion 423e of the connecting member 423 is arranged at the inner end of the guide hole 424b with the state shown in FIG. The state where the member 410 is arranged at the overhang position is illustrated.

  Also, in FIG. 28, the main body member 431 of the swing member 430 is illustrated by an imaginary line, and in FIGS. 28, 30 and 32, a part of the main body member 410 is illustrated by a hidden line, and the overlapping portion P is indicated by an imaginary line. 29, 31 and 33, the rear upper plate 470 is shown by imaginary lines.

  Further, in FIG. 30, the vicinity of the connection member 423 is enlarged and the state in which the connection member 423 has moved by a predetermined amount from the center-side ends of the pair of guide holes 424b in the enlarged view is illustrated by imaginary lines. Is done. In FIG. 31, the vicinity of the guide hole 413 is enlarged and the state in which the insertion shaft 421c is moved by a predetermined amount from the lower end of the guide hole 413 in the enlarged view is illustrated by imaginary lines.

  When the drive gear 463 is rotated, the main body member 410 is vertically moved along the guide hole 452 with the movement of the leg member 440 meshed with the drive gear 463.

  As shown in FIGS. 28 and 29, the contact plate 421 d of the swing base member 421 of the shielding member 420 is supported by the decorative plate portion 418 of the base member 411 when the main body member 410 is located at the retracted position. Thus, the central portion in the left-right direction of the swing base member 421 is supported. In this state, the slide shaft portion 423e of the connecting member 423 is disposed at a laterally outer end of the guide hole 424b of the guide plate 424, and the insertion shaft portion 421c of the shielding member 420 is located at the lower end of the guide hole 413 of the main body member 410. And the wiring guide arm 480 is folded so that the extending directions of the respective guide arms are parallel to each other. Further, since the upper side surface of the slide lever 473 and the lower side surface of the holding portion 415 are in contact with each other, the downward movement of the main body member 410 is prevented.

  As shown in FIG. 28, at least a part of the mechanical portion such as the transmission gear 435 of the swinging member 430 is provided with a gap formed between the pair of decorative members 422 of the shielding member 420 (formed at the center in the left-right direction and downward). It is arranged in a gap that becomes wider as it goes (see FIGS. 28 and 34). Thus, in a state where the main body member 410 is disposed at the retracted position, the swing member 430 can be arranged vertically in the shielding member 420, and the width of the shielding member 420 and the swing member 430 in the vertical direction can be reduced. Can be suppressed. In this case, the area in front view formed by the main body member 410, the shielding member 420, and the swing member 430 can be reduced, so that the opening 211a (see FIG. 6) can be made larger.

  Here, for example, a mechanical part such as the transmission gear 435 of the swing member 430 may be provided on the front side of the main body member 410 in some cases. In this case, in order to increase the area of the overlapped portion P between the main body member 410 and the decoration member 422 (to move the main body member 410 and the decoration member 422 in the moving direction of the main body member 410), the decoration member 422 is moved by the mechanical part. It is conceivable to arrange them on the front side. On the other hand, in this case, since it is necessary to move the swing member 430 that accommodates the decorative member 422 to the front side (the direction away from the main body member 410), the space on the front side of the swing member 430 is suppressed, and It is difficult to form the swing member 430 three-dimensionally on the front side.

  On the other hand, according to the present embodiment, it is possible to accommodate at least a part (mechanical part such as the transmission gear 435) of the swing member 430 in a space generated by the pair of decorative members 422 being separated from each other. it can. Accordingly, for example, it is not necessary to move the decoration member 422 to the front side of the mechanical part of the oscillating member 430 in order to increase the area of the overlapping portion P between the main body member 410 and the decoration member 422. 430 can be located proximate to body member 410. Thus, the swing member 430 can be formed three-dimensionally on the front side.

  In FIG. 28, since the swing member 430 takes a posture in which the main body member 431 is tilted (see FIG. 34), the vertical width in a front view is suppressed as compared with the standing posture (see FIGS. 32 and 35). You. Therefore, even when the swing member 430 is viewed alone, the area of the swing member 430 formed in a front view can be suppressed.

  As shown in FIGS. 30 and 31, the contact plate 421 d of the swing base member 421 of the shielding member 420 is supported by the decorative plate portion 418 of the base member 411 in a state where the main body member 410 is disposed at the intermediate position. Thus, the central portion in the left-right direction of the swing base member 421 is supported (that is, the shielding member 420 has the same posture as the posture in FIGS. 28 and 29). In this state, the slide shaft 423e of the connecting member 423 is disposed at the left and right inner end of the guide hole 424b of the guide plate 424, and the insertion shaft 421c of the shielding member 420 is located at the lower end of the guide hole 413 of the main body member 410. Placed in The wiring guide arm 480 has a third guide arm 483 mounted on the upper side surface of the main body member 410, and the first guide arm 481 and the second guide arm 482 each take a posture inclined with respect to the left-right direction.

  Since the third guide arm 483 is formed shorter than the other guide arms 481 and 482, the state in which the third guide arm 483 is stably mounted on the upper side surface of the main body member 410 is referred to as the main body member. It can be maintained longer during the movement of 410. This makes it possible to further stabilize the wiring W provided inside the wiring guide arm 480 and prevent the wiring W from being disconnected.

  Here, when the main body member 410 is moved downward at a high speed and is located at the intermediate position, the slide shaft portion 423e of the connecting member 423 rebounds at the inner end of the guide hole 424b, and the swing base of the shielding member 420. The pivot position (the pivot rod 423c, see FIG. 23) of the member 421 and the connecting member 423 may jump upward, and the posture of the shielding member 420 may not be stabilized. On the other hand, in the present embodiment, the guide hole 413 for guiding the insertion shaft portion 421c of the swing base member 421 is formed to be inclined upward and inward in the left-right direction, and the guide for guiding the slide shaft portion 423e. A hole 424b is formed in the left-right direction.

  In other words, when the slide shaft part 423e reaches the inner end of the guide hole 424b, the insertion shaft part 421c is a component perpendicular to the direction in which the pivotal support position of the swing base member 421 and the connecting member 423 rebounds. Is guided so as to be movable in the direction having

  Therefore, a resistance F is applied downward from the upper side surface of the guide hole 413 to the insertion shaft portion 421c that is moved upward with the upward movement of the swing base member 421, and the upper portion of the insertion shaft portion 421c. Movement to is suppressed. In this case, the swing base member 421 is prevented from jumping upward, and the slide shaft portion 423e of the connecting member 423 is prevented from jumping back at the inner end of the guide hole 424b. In addition, even if the swing base member 421 jumps upward and the connecting member 423 jumps upward, the movement of the connecting member is suppressed because the slide shaft portion 423e is in contact with the upper and lower side surfaces of the guide hole 424b. Is done.

  Further, in the present embodiment, even if the bent portion 423b is formed in the connecting member 423, and the slide shaft portion 423e of the connecting member 423 rebounds at the inner end of the guide hole 424b, the bent portion 423b is still in the swing base member 421. (The bent portion 213b moves a distance X toward the center in the left-right direction). Therefore, when the slide shaft portion 423e of the connecting member 423 rebounds at the inner end in the left-right direction of the guide hole 424b, a sufficient interval can be formed between the connecting member 423 and the swing base member 421, and Collision with the swing base member 421 can be prevented. Thus, the degree of freedom in designing the swing base member 421 can be improved.

  In a state where the main body member 410 is disposed at the intermediate position, the connecting member 423 connected to the swing base member 421 suppresses the movement of the swing base member 421 in the left-right direction. That is, for example, when the swing base member 421 starts to move leftward in front view due to disturbance, the connecting member 423 inserted into the guide hole 424b on the right side in front view is located at the center in the left-right direction of the pair of guide holes 424b. The movement is stopped by the end, and the movement of the swing base member 421 in the left-right direction is suppressed. Therefore, the arrangement of the swing base member 421 can be stabilized.

  As shown in FIGS. 32 and 33, the swing base member 421 of the shielding member 420 is suspended and supported by the connecting member 423 in a state where the main body member 410 is disposed at the extended position. In this state, the slide shaft portion 423 e of the connecting member 423 is disposed at the left and right inner end of the guide hole 424 b of the guide plate 424, and the insertion shaft portion 421 c of the shielding member 420 is located at the upper end of the guide hole 413 of the main body member 410. Placed in In addition, the wiring guide arm 480 is in a posture in which the other bottom portion 481e2 of the first guide arm 481 (see FIG. 25) and the one bottom portion 482e1 of the second guide arm 482 (see FIG. 26) abut in the swing direction. Take.

  Here, when the main body member 410 moves from the intermediate position to the overhang position, the pair of left and right insertion shaft portions 421 c move upward along the guide holes 413 in the left and right directions along with the movement. That is, the forces applied to the pair of swing base members 421 from the pair of left and right guide holes 413 of the main body member 410 are directed in opposite directions to the left and right, and cancel each other. Therefore, the displacement of the pivot shaft hole 421b (see FIG. 33) formed on the central axis of the pair of pivot base members 421 in the left-right direction is suppressed, and the displacement of the shielding member 420 in the left-right direction is suppressed. Is suppressed.

  As shown in FIG. 33, in a state where the main body member 410 is located at the extended position, the pair of swing base members 421 and the pair of decorative members 422 of the shielding member 420 are in contact with each other. Thereby, for example, even if one of the swing base members 421 moves faster than the other swing base member 421 and the pair of swing base members 421 are displaced from each other (vertical displacement), the other swing base member 421 is shifted. The contact with the swing base member 421 can suppress the displacement. Thereby, the posture of the shielding member 420 at the extended position can be stabilized.

  The change in the area of the overlapping portion P will be described. The overlapping portion P means a portion where the main body member 410 and the shielding member 420 overlap in a front view. As shown in FIGS. 28 and 30, most of the main body member 410 corresponds to the overlapping portion P from the state where the main body member 410 is arranged at the retracted position to the state where the main body member 410 is arranged at the intermediate position. On the other hand, as shown in FIG. 32, in a state where the main body member 410 is disposed at the overhang position, the shielding member 420 is moved above the main body member 410, particularly in the central portion in the left-right direction, and the area of the overlapping portion P is increased. Is reduced. That is, the main body member 410 and the shielding member 420 are separately visible.

  Thereby, compared with the case where the main body member 410 is arranged at the retracted position, the area in the front view of the main body member 410 and the shielding member 420 is larger when the main body member 410 is arranged at the extended position. In particular, the width in the vertical direction at the center in the horizontal direction is increased. In this case, in the central portion of the third symbol display device 81 (see FIG. 2) that easily attracts the player's attention, the area change in the front view of the area formed by the main body member 410 and the shielding member 420 can be increased. The effect can be improved.

  In the present embodiment, the above-described change in the area of the overlapping portion P occurs after the main body member 410 and the shielding member 420 start to protrude to the front of the third symbol display device 81 (see FIG. 2). Thus, the effect can be performed as if the main body member 410 and the shielding member 420 expand, and the effect of the effect can be improved.

  Next, the operation of the swing member 430 of the combined operation unit 400 will be described with reference to FIGS. FIG. 34 is a partial cross-sectional view of the composite operation unit 400 along the line XXXIV-XXXIV in FIG. 28, and FIG. 35 is a partial cross-sectional view of the composite operation unit 400 along the line XXXV-XXXV in FIG. In FIG. 34, the state in which the main body member 431 of the swing member 430 is tilted is illustrated by a solid line, and the hanging portion 422b of the decorative member 422 is accommodated between the main body member 431 and the main body member 410 of the swing member 430. The illustrated state is shown. In FIG. 35, the state in which the main body member 431 of the swing member 430 is upright is illustrated by a solid line, and the state in which the swing member 430 is tilted is illustrated by an imaginary line for reference, and is arranged in an extended state. The moving member 540 of the swing operation unit 500 is shown in phantom lines.

  As shown in FIGS. 34 and 35, the drive gear 434 is rotated by the drive motor 433 (see FIG. 23), and the transmission gear 435 is rotated accordingly. When the connecting member 436 pivotally supported by the shaft 435c moves in the front-rear direction, the main body member 431 pivotally supported by the coupling member 436 swings about the shaft supporting portion 416 (see FIG. 23). In this case, the main body member 431 is moved in a direction approaching and separating from the decoration member 422b. The swing member 430 can be switched between an inclined state shown in FIG. 34 and an upright state shown in FIG. 35 at an arbitrary position, and can change its posture as long as it does not interfere with the shielding member 420.

  Since the shaft support 416 (see FIG. 23) is connected to the lower end of the oscillating member 430, when the oscillating member 430 is in a tilted state (see FIG. 34), the upper end side that is disposed to face the shielding member 420. The distance D between the main body member 410 and the main body member 410 can be made large. On the other hand, the movement width of the lower end portion of the oscillating member 430 on the opposite side of the shielding member 420 can be reduced, and the oscillating member 430 can slide compared to the case where the oscillating member 430 slides back and forth. The space required for arranging can be reduced.

  In other words, when securing the space for accommodating the shielding member 420 by sliding in the front-rear direction, the lower end of the oscillating member 430 on the opposite side of the shielding member 420 also moves by the distance D similarly to the upper end. Accordingly, a space for disposing the swing member 430 increases. On the other hand, in the present embodiment, since the swing member 430 is swung, the shielding member 420 is smoothly accommodated between the main body member 410 and the swing member 430, and the arrangement area of the swing member 430 is reduced. It is possible to achieve both suppression.

  In the present embodiment, the change width d of the outer shape of the lower portion on the front side of the main body member 431 is particularly small during the tilting operation of the swing member 430. Therefore, even if the main body member 431 is tilted in a state in which another member approaches or abuts below the main body member 431 (see FIG. 9), it is possible to suppress a load from being applied between the members.

  In the present embodiment, in the state of FIG. 9, the upper surface of the moving member 540 (see FIG. 40) arranged to face the main body member 431 has a downwardly curved surface, and the main body member 431 approaches the curved surface. The main body member 431 can be tilted at a position (a position where the main body member 431 and the moving member 540 partially overlap in a front view). Accordingly, the posture of the main body member 431 can be changed with a large width at the upper part of the main body member 431 while ensuring the effect of bringing the main body member 431 and the moving member 540 closer to each other at the lower part of the main body member 431 and visually confirming them integrally. it can.

  As shown in FIGS. 34 and 35, the decorative member 422 of the shielding member 420 is inclined downward (toward the shaft support 416 (see FIG. 23)) or rearward (toward the main body member 410). It is formed to be curved in a direction away from the swing member 430. In this case, when the decoration member 422 starts to be accommodated between the swing member 430 and the main body member 410, a distance between the decoration member 422 and the swing member 430 can be ensured, and the decoration member 422 and the neck can be secured. Collision with the swing member 430 can be avoided.

  In addition, the lower end of the decorative member 422 can be stored deeply (downward) in the gap formed between the main body member 410 and the swing member 430 while the upper end of the decorative member 422 extends toward the front. . Since no other member is disposed on the front side of the swing member 430, the degree of freedom in designing the shape of the front portion of the swing member 430 can be improved.

  As illustrated in FIG. 35, in a state where the swing member 430 is upright, the decorative member 422 is separated upward from between the swing member 430 and the main body member 410, and the body member 431 of the swing member 430 is moved upward. The upper end and the main body member 410 are arranged close to each other. Accordingly, a dead space in a case where the decoration member 422 is not accommodated between the main body member 410 and the swing member 430 can be filled. In addition, by making it possible to form a posture in which the main body member 431 of the swing member 430 is disposed close to the main body member 410, the movement width of the swing member 430 in the front-rear direction in the pachinko machine 10 in which the front-rear width is defined is increased. As a result, the effect of the swinging motion of the swing member 430 can be improved.

  Here, FIG. 34 illustrates a state where the swing member 430 is disposed above the third symbol display device 81 and the swing member 430 is tilted. In this case, the direction A1 of the effect surface on the front side of the swing member 430 is a direction inclined obliquely downward toward the front. On the other hand, in FIG. 35, the swing member 430 is arranged on the front side of the third symbol display device 81 (see FIG. 2), and the state in which the swing member 430 is erected is shown by a solid line. In this case, the direction A2 of the effect surface on the front side of the swing member 430 is directed to the front. That is, by adjusting the degree of swing of the swinging member 430, the directions A1 and A2 on the front side of the swinging member 430 are directed toward the eyes of the player (the center front side of the third symbol display device 81). Can be adjusted. Therefore, the attention power of the swing member 430 can be improved, and the effect can be improved.

  Further, a new rotating shaft is not provided to improve the attention power of the swing member 430, but the shaft supporting portion 416 (see FIG. 23) is used. That is, the shaft support 416 is used to secure the distance between the decoration member 422 and the swing member 430 when the decoration member 422 starts being housed between the swing member 430 and the main body member 410, This is also used for the purpose of adjusting the directions A1 and A2 on the front side of the member 430 to the direction toward the eyes of the player (the center front side of the third symbol display device 81).

  The degree of swing of the swing member 430 can be determined based on whether or not the sensor passage portion 435d passes through the photo sensor 417. That is, in the state shown in FIG. 34, the sensor passing portion 435d has not passed through the photosensor 417. On the other hand, in the state shown in FIG. 35, the sensor passage section 435 has passed through the photosensor 417. Therefore, in the present embodiment, a gap between the swing member 430 and the main body member 410 is ensured in a state where the sensor passage portion 435 does not pass through the photosensor 417.

  Therefore, by moving up the main body member 410 in a state where the sensor passage portion 435 does not pass through the photosensor 417, the shielding member 420 and the main body member 410 can be moved without interfering with the swing member 430 and the shielding member 420. It can be accommodated between the swinging member 430.

  Here, with reference to FIGS. 36 and 37, a description will be given of how the shape of the hanging portion 422b suppresses a malfunction of the combined operation unit 400. FIG. 36 is a front view of the combined operation unit 400, and FIG. 37 is a partial cross-sectional view of the combined operation unit 400 taken along the line XXXVII-XXXVII in FIG. FIGS. 36 and 37 show a state in which the main body member 431 of the swing member 430 is tilted by a predetermined angle from the standing state (see FIG. 35), and the back side of the main body member 431 is in contact with the hanging portion 422b. .

  As shown in FIGS. 36 and 37, the main body member 410 is moved up and down in a state where the main body member 431 of the swing member 430 is in the middle position between the upright state (see FIG. 35) and the inclined state (see FIG. 34). In some cases. This control is performed, for example, when the composite operation unit 400 is immediately changed from the state of FIG. 34 to the state of FIG.

  Here, the drive motor 462 (see FIG. 21) that drives the main body member 410 after confirming that the main body member 431 of the swing member 430 is tilted (see the broken line in FIG. 35) from the standing state shown in FIG. Is rotated, a state in which the back side of the main body member 431 contacts the hanging portion 422b cannot occur (see FIG. 34).

  However, in this case, the drive motor 462 (see FIG. 21) is rotated after the operation of the swing member 430 is completed. Therefore, as compared with the case where the drive motor 433 (see FIG. 23) for tilting the swing member 430 and the drive motor 462 for driving the main body member 410 are simultaneously rotated, the composite operation unit 400 is moved from the state of FIG. The period for changing to the state becomes longer. In other words, it is necessary to drive the drive motor 433 and the drive motor 462 simultaneously in order to immediately change the composite operation unit 400 from the state of FIG. 34 to the state of FIG. In this case, the main body member 410 is moved up and down while the main body member 431 of the swing member 430 moves from the upright state (see FIG. 35) to the inclined state (see FIG. 34). In this case, the main body portion 431 of the swing member 430 may come into contact with the hanging portion 422b, and the composite operation unit 400 may malfunction.

  On the other hand, in the present embodiment, the hanging portion 422b is formed to be curved (see FIG. 37). Therefore, as shown in FIG. 37, the contact of the swing member 430 with the back side (formed in a plane) of the main body member 431 is not a contact with a surface but with a point (line). And the frictional resistance at the contact position can be suppressed. Therefore, it is possible to prevent the composite operation unit 400 from malfunctioning due to the contact between the main body member 431 of the swing member 430 and the hanging portion 422b.

  For example, when the state of FIGS. 36 and 37 is a state in which the main body member 410 is moving upward from FIG. 35, the frictional resistance at the contact position between the main body member 431 of the swinging member 430 and the hanging portion 422b is reduced. If it is large, it causes a reduction in the moving speed of the main body member 410. On the other hand, in the present embodiment, since the frictional resistance at the contact position between the main body member 431 of the swing member 430 and the hanging portion 422b is suppressed, the moving speed of the main body member 410 can be increased. In addition, as the main body member 410 moves upward, the main body member 431 of the swing member 430 becomes inclined due to the curved shape of the hanging portion 422b, so that the hanging portion 422b applies a driving force to the main body member 431 of the swing member 430. Giving relationships arise. Thus, the burden of the drive motor 433 causing the swinging member 430 to tilt can be reduced.

  Further, for example, when the state of FIGS. 36 and 37 is a state where the main body member 410 is moving downward from FIG. 34, the friction at the contact position between the main body member 431 of the swinging member 430 and the hanging part 422b is determined. If the resistance is large, it causes a reduction in the moving speed of the main body member 410. On the other hand, in the present embodiment, since the frictional resistance at the contact position between the main body member 431 of the swing member 430 and the hanging portion 422b is suppressed, the moving speed of the main body member 410 can be increased. Further, since the hanging portion 422b is formed to be inclined downward and inclining backward and the back side of the main body member 431 is formed in a flat shape, even if the main body member 410 moves downward while making contact with each other, the hanging portion 422b is formed. The 422b and the main body member 431 do not catch on each other.

  Accordingly, it is possible to prevent the composite operation unit 400 from malfunctioning by moving the main body member 410 while the main body member 431 of the swing member 430 is tilted. Therefore, by moving the main body member 410 while the main body member 431 of the swing member 430 is tilted, the state of the composite operation unit 400 can be changed immediately.

  Next, the swing operation unit 500 will be described with reference to FIGS. FIG. 38 is a front perspective view of the swing operation unit 500, and FIG. 39 is a rear perspective view of the swing operation unit 500. FIGS. 38 and 39 show a state in which the moving member 540 is disposed at the retracted position.

  Although the swing operation unit 500 is constituted by a pair of left and right operation units (see FIG. 5), since their technical structures are common, in FIGS. 38 to 50, the left operation of the pair of left and right operation units is performed. The unit will be described as a swing operation unit 500.

  FIG. 40 is an exploded front perspective view of the swing operation unit 500, and FIG. 41 is an exploded rear perspective view of the swing operation unit 500. In FIG. 40, the fastening holes 527 are partially enlarged and in FIG. 41, the bridging members 528 are partially enlarged.

  As shown in FIGS. 40 and 41, the swing operation unit 500 includes a base member 510 having a rectangular plate shape, and shaft support holes 522 and 526 formed at both ends. The distance between the drive-side arm member 520 in the form of a long plate, which is pivotally supported so as to be able to swing, and the center axes of the shaft support holes 532, 533 formed at both ends is the shaft support hole 522 of the drive-side arm member 520. , 526 has a length equal to the distance between the central axes thereof, and one side end of one side shaft support hole 532 is pivotally supported by the base member 510 so as to be swingable. A horizontally long block-shaped moving member 540 which is swingably supported by the other side shaft support hole 526 of the drive side arm member 520 and the other side shaft support hole 533 of the driven side arm member 530, and a drive side arm member 520. Drive force to swing the A driving device 550 for generating the light, and a front plate member 560 disposed on the front side of the base member 510 with the driving arm member 520 and the driven arm member 530 interposed therebetween and to which the driving motor 551 is fastened and fixed. Prepare.

  The base member 510 includes a plate-shaped main body portion 511, a plurality of shaft support portions 512 projecting from the right side of the main body portion 511 in a front view to the front side, and a lowermost first of the shaft support portions 512. A drive gear receiving hole 513 formed on the left side of the triaxial portion 512c when viewed from the front, a photo sensor 514 disposed on the right side of the shaft support portion 512, and a rectangular shape from the left side of the main body portion 511 when viewed from the front to the front side. And a lower support 515 projecting from the shape.

  The main body portion 511 is formed such that the height of the upper end portion is different between the left side of the first shaft portion 512a when viewed from the front and the right side when viewed from the front. That is, a step-down portion 511a having an upper side surface lowered by one step is provided on the left side of the first shaft portion 512a in a front view.

  The step-down portion 511a has an effect of expanding the display area of the third symbol display device 81 in a state where the moving member 540 of the swing operation unit 500 is disposed at the extended position (see FIG. 8). Further, in a state where the moving member 540 is disposed at the retracted position, for example, when the driven arm member 530 falls backward, the area where the driven arm member 530 may come into contact with the main body 511 in the front-rear direction is reduced. It can be reduced (see FIG. 39). Accordingly, when the moving member 540 moves from the retracted position to the extended position, or when the moving member 540 moves from the extended position to the retracted position, the driven arm member 530 and the main body 511 are connected. The area that may be rubbed can be reduced, and the moving member 540 can be moved smoothly.

  The shaft support portion 512 is formed of three bar members that are arranged vertically apart from each other and whose axes are parallel to each other, and a first end on which one end of the driven arm member is supported in order from the top. A shaft portion 512a, a second shaft portion 512b on which one end of the drive side arm member is supported, and a third shaft portion 512c on which a transmission gear 553 meshed with the drive gear 552 is supported. Prepare mainly.

  The drive gear receiving hole 513 is a through-hole in which a stepped portion that projects to the rear side of the drive gear 552 is fitted.

  The lower support portion 515 is in contact with the lower side of the lower surface of the other end of the drive-side arm member 520 when the drive-side arm member 520 is located at the retracted position, and the other end of the drive-side arm member 520. The part is prevented from swinging further downward.

  The drive-side arm member 520 is a member formed of a resin material, and has a main body plate portion 521 formed in a long plate shape and one end of the main body plate portion 521 (the right end in front view). ), A one-side shaft support hole 522 formed in the front-rear direction and through which the second shaft portion 512b is inserted, and a semicircle centered on the one-side shaft support hole 522 formed below the one-side shaft support hole 522. A gear portion 523 in which gear teeth are engraved on the outer periphery of the sensor portion, a sensor passage plate 524 fastened and fixed to a raised portion 521a raised near the outer periphery of the gear portion 523 to the front side, and a one-side shaft support hole 522. A collar member 525 having a coaxially disposed through hole and fastened and fixed to the rear side of the main body plate portion 521, and a collar member 525 formed in the other end portion (the left end portion in front view) of the main body plate portion 521 in the front-rear direction. The second shaft portion 542b of the moving member 540 is pivotally supported via a collar. A pair of fastening holes 527 including a pair of fastening holes 527a1 and 527b1 that are arranged near the other end of the main body plate portion 521 and are drilled in the front-rear direction. And a bridging member 528 through which the insertion portions 528a2 and 528b2 are inserted and fastened and fixed.

  The main body plate portion 521 includes, at one end (the right end in FIG. 40), a raised portion 521a that is inserted into the guide hole 563 and fastens and fixed to the sensor passage plate 524 at the tip.

  The gear portion 523 is a portion that meshes with the second gear portion 553b of the transmission gear 553 of the driving device 550 (see FIG. 48), and includes an umbrella portion 523a that is covered on the front side.

  In the present embodiment, the umbrella portion 523a is formed so as to cover the entire gear teeth 523 (see FIG. 48). However, the umbrella portion 523a does not necessarily need to cover the entire gear teeth 523, and is formed so as to cover at least the gear teeth of the second gear portion 553b of the transmission gear 553. 553b can be contacted, and wobble of the drive side arm member 520 can be prevented.

  The sensor passage plate 524 is a member disposed on the front side of the front plate member 560 in an assembled state (see FIG. 42), and is a fastening portion which is raised and fastened to one end of the main body plate portion 521. 524a and a sensor passing plate portion 524b extending radially from the fastening portion 524a around the one-side shaft support hole 522 in the assembled state.

  The sensor passage plate portion 524b is a member that is disposed to face the front side surface of the front plate member 560 and that passes through the inside of the photosensor 514. Here, the sensor passage plate portion 524b can be brought into contact with the front side surface of the front plate member 560, and the sensor passage plate portion 524b is brought into contact with the front plate member 560. Shaft tilting with respect to the two shaft portions 512b is suppressed. On the other hand, the sensor passing plate portion 524b is a member that can detect that the driving side arm member 520 has been set to the retracted position by passing through the inside of the photo sensor 514. That is, the sensor passage plate portion 524b can be used for both increasing the resistance to the deformation (shaft tilting) of the driving arm member 520 and detecting the posture of the driving arm member 520.

  The collar member 525 is a plate-shaped member whose outer shape is formed in a substantially rhombic shape with rounded corners, and has a main body portion 525a having a circular outer shape whose diameter is the end in the short direction of the outer shape. An outer fitting hole 525b formed at the center of the portion 525a, and a pair of fastening portions 525c disposed on the left and right sides of the main body portion 525a and formed with a tapered tip and fastened and fixed to the main body plate portion 521; Mainly equipped.

  The pair of fastening holes 527 includes a first fastening hole 527a to which the first bridging member 528a is fixed, and a second fastening hole 527b to which the second bridging member 528b is fixed.

  As shown in FIG. 40, since the pair of fastening holes 527 are formed on the other shaft support portion 526 side (the side on which the moving member 540 is provided) of the driving arm member 520, the fastening holes 527 and one side shaft are formed. A long distance from the support hole 522 can be ensured. Therefore, as described later, even when the driven arm member 530 contacts the bridging member 528 and there is a possibility that the driving arm member 520 may be torsionally deformed, the deformation is determined by the fastening hole 527 and the one-side shaft support hole 522. And a long distance can be used at the portion between them (the torsion angle per a predetermined length in the longitudinal direction can be reduced). In this case, it is possible to suppress a load (a load in a direction in which the second shaft portion 512b is folded and folded) from the one shaft support hole 522 to the second shaft portion 512b, and improve the durability of the second shaft portion 512b. be able to.

  The first fastening hole portion 527a is provided with a first fastening hole 527a1 to which the first bridging member 528a is fastened and fixed, and is formed adjacent to the first fastening hole 527a1 and the auxiliary protrusion 528a3 is inserted therethrough. And a first pinning hole 527a2 to which the first bridge member 528a is non-rotatably fixed.

  The first fastening holes 527a1 and the first pin fastening holes 527a2 are arranged along a line forming a predetermined angle θ1 (θ1 <90 degrees) with respect to the short direction of the drive side arm member 520 (see FIG. 43). .

  The second fastening hole 527b is provided with a second fastening hole 527b1 to which the second bridging member 528b is fastened and fixed, and is formed adjacent to the second fastening hole 527b1 and the auxiliary projection 528b3 is inserted therethrough. A second pinning hole 527b2 to which the second bridging member 528b is non-rotatably fixed, and a base 527b3 formed in such a manner that the outer edges of the second fastening hole 527b1 and the second pinning hole 527b2 are raised to the front side. , Is provided.

  The second fastening holes 527b1 and the second pin fastening holes 527b2 are arranged along a line that forms a predetermined angle θ2 (θ2 <90 degrees) with respect to the short direction of the driving arm member 520 (see FIG. 43). . That is, when the second bridging member 528b is bent and deformed toward the near side in FIG. 43, the load applied to the driving arm member 520 is determined by the twist direction (the direction of rotation about the longitudinal direction of the driving arm member 520). It can be divided in the bending direction (the direction in which the drive side arm member 520 bends to the front side). Thus, when the second bridge member 528b receives a load from the driven side arm member 530 and bends and deforms, it is possible to suppress the drive side arm member 520 from being twisted and deformed around the longitudinal direction.

  The bridging member 528 is provided on a first bridging member 528a disposed on a side closer to the other-side shaft support portion 526, and on a side opposite to the other-side shaft support portion 526 across the first bridge member 528a. And a second bridging member 528b formed larger (longer and wider in the lateral direction) than the first bridging member 528a.

  The first bridging member 528a has a main body 528a1 formed in a long plate shape, an insertion portion 528a2 inserted into the first fastening hole 527a1 and fastened and fixed, and a projecting portion adjacent to the insertion portion 528a2. An auxiliary protruding portion 528a3, a rib portion 528a4 formed along a side edge of the main body portion 581a1 close to the other shaft support hole 526, and protruding toward the rear side, and an end portion of the rib portion 528a4. And an inclined portion 528a5 inclined with respect to the projecting direction.

  The main body 528a1 has a length that covers the driven arm member 530 in a front view in an assembled state (see FIG. 48).

  The auxiliary projection 528a3 is a portion that is inserted into a first pin hole 527a2 formed adjacent to the first fastening hole 527a1 of the main body plate portion 521, so that the bridging member 528 is connected to the main body plate portion 521. Are supported at two points. Therefore, the bridging member 528 can be fixed to the main body plate portion 521 so as not to rotate relatively.

  Since the rib 528a4 is not formed up to the tip of the main body 528a1, the rib 528a4 prevents contact with the driven arm member 530 at the retracted position (see FIG. 48), and the driven arm at the extended position (see FIG. 50). It is formed in such a manner that it can easily come into contact with the member 530. The details will be described later.

  The second bridging member 528b is formed in a long plate shape, an insertion portion 528b2 inserted into the second fastening hole 527b1 and fastened and fixed, and protrudes adjacent to the insertion portion 528b2. An auxiliary protruding portion 528b3, a rib portion 528b4 formed along a side edge of the main body portion 581b1 close to the other shaft support hole 526, and protruding toward the rear side, and an end portion of the rib portion 528b4. And an inclined portion 528b5 inclined with respect to the projecting direction.

  The main body portion 528b1 is formed to have a length that covers the driven arm member 530 in a front view in an assembled state (see FIG. 48).

  The auxiliary projecting portion 528b3 is a portion that is inserted into a second pin fastening hole 527b2 formed adjacent to the second fastening hole 527b1 of the main body plate portion 521, whereby the bridging member 528 is connected to the main body plate portion 521. Are supported at two points. Therefore, the bridging member 528 can be fixed to the main body plate portion 521 so as not to rotate relatively.

  Since the rib portion 528b4 is not formed up to the tip of the main body portion 528b1, the contact with the driven arm member 530 is suppressed at the retracted position (see FIG. 48), and the driven arm is set at the extended position (see FIG. 50). It is formed in such a manner that it can easily come into contact with the member 530. The details will be described later.

  As shown in FIG. 43, the second bridge member 528b has a width of a portion overlapping with the driven arm member 530, rather than a width of a portion of the main body 528b1 (see FIG. 41) fastened to the drive arm member 520. It is formed narrower. Accordingly, when the driven arm member 530 abuts on the second bridging member 528b, it is possible to suppress the second bridging member 528b from being twisted about the longitudinal direction (flexing along the longitudinal direction). Can be easier).

  Therefore, the contact between the driven arm member 530 and the second bridging member 528b can prevent the second bridging member 528b from being twisted and deformed, and the mode of deformation can be limited. In this case, the arrangement position of the portion (the second pin hole 527b2) for preventing the second bridging member 528b from being turned up can be limited, so that the configuration of the second bridging member 528b can be simplified. . That is, it is not necessary to form the auxiliary projection 528b3 (see FIG. 41) in the short direction of the second bridge member 528b with respect to the insertion portion 528b2 (see FIG. 41).

  The driven arm member 530 is a member formed of a resin material, and includes a main body plate portion 531 formed in a long plate shape and one end of the main body plate portion 531 (the right end portion in front view). ), One side shaft support hole 532 in which the first shaft portion 512a is inserted in the front-rear direction, and the other end (the left end in front view) of the main body plate portion 531 is formed in the front-rear direction. And a second shaft support hole 533 in which the first shaft portion 542a of the moving member 540 is supported via a collar.

  The front side surface of the main body plate portion 531 is formed on the same plane as the front side surface of the drive arm member 520.

  The moving member 540 includes a main body 541 that is formed in a block shape that is long in the left and right direction and that has an upper surface formed by a curved surface that is convex downward, and a cylindrical shape that projects rearward on the right side of the main body 541 when viewed from the rear. It mainly includes a pair of shaft support portions 542 provided and an alignment portion 543 protruding from the right side surface of the main body portion 451.

  In the present embodiment, the moving member 540 is formed so as to be thicker toward the side where the pair of moving members 540 abut (the right side in FIG. 42A). The member 540 is formed on the side where it contacts, and is formed at a position separated from the driven arm member 530 toward the front side (see FIG. 42).

  The shaft support portion 542 is formed with the same inter-axis distance as the inter-axis distance between the first shaft portion 512a and the second shaft portion 512b, and the relative arrangement of a pair of shafts in the state shown in FIG. The shaft portion 512a and the second shaft portion 512b are formed from a pair of shafts formed in the same manner as the arrangement of the shafts, and mainly include a first shaft portion 542a and a second shaft portion 542b in order from the top.

  The first shaft portion 542a is a portion inserted into the other shaft support hole 533 of the driven arm member 530, and the second shaft portion 542b is inserted through the other shaft support hole 526 of the drive arm member 520. Part.

  Here, as described above, the axial distance between the shaft support holes 522 and 526 at both ends of the drive side arm member 520 and the axial distance between the shaft support holes 532 and 533 at both ends of the driven arm member 530 are different. It is the same. Further, the relative positions of the first shaft portion 512a and the second shaft portion 512b provided on the base member 510 and the first shaft portion 542a and the second shaft portion 542b provided on the moving member 540 are different. The relationship (the direction and distance of a straight line connecting the axes) is the same. Therefore, a parallel link is formed by the driving side arm member 520 and the driven side arm member 530, and the posture of the moving member 540 is not changed during the swing of the driving side arm member 520 (FIGS. 48 to 50).

  The positioning part 543 is a part for adjusting the relative positional relationship between the pair of moving members 540 when the moving member 540 is arranged at the overhang position. Note that a recess is formed in the moving member 540 on the right side (see FIG. 8) in front view so as to be able to receive the alignment portion 543 of the left moving member 540.

  The drive device 550 includes a drive motor 551 fastened and fixed to the front side of the front plate member 560 with the drive shaft facing the rear side, a drive gear 552 supported by the drive motor 551, and one drive gear 552. The transmission gear 553 mainly meshes with the first gear portion 553a of the second stage and the second gear portion 553b of the second stage meshes with the gear portion 523 of the driving arm member 520.

  The transmission gear 553 is a member in which two-stage gear teeth having different diameters are formed coaxially. The transmission gear 553 includes a first gear portion 553a formed of a large-diameter gear disposed to face the base member 510, and a first gear portion 553a. A second gear portion 553b formed from a gear smaller in diameter than the first gear portion 553a disposed on the front side of the gear portion 551a, and a hole is formed at the center of the first gear portion 553a and the second gear portion 553b. And a shaft support hole 553c supported by the third shaft portion 512c of the base member 510.

  The front plate member 560 includes a main body portion 561 formed in a horizontally long plate shape, a holding portion 562 recessed in the same arrangement as that of the shaft support portion 512 of the base member 510, and a fastening portion 524a of the sensor passage plate 524. And a guide hole 563 that is formed in an arc shape along the movement locus.

  The holding portion 562 is recessed with a diameter equal to the diameter of each column of the shaft support 512, and the tip of each shaft of the shaft support 512 is fitted and fixed therein. Thus, the shaft support 512 can be supported at both ends, so that the shaft can be stabilized. Accordingly, the operations of the driving arm member 520, the driven arm member 530, and the transmission gear 553 can be stabilized.

  The guide hole 563 is an arc-shaped long hole through which a raised portion 521a protruding from the drive-side arm member 520 toward the sensor passage plate 524 is inserted, and extends in the front-rear direction at a lower end. And a stopper wall portion 563a. Thus, even if the drive side arm member 520 is displaced in the radial direction with respect to the second shaft portion 512b, the raised portion 521a of the drive side arm member 520 comes into contact with the guide hole 563 to restrict the movement. Thus, the position of the drive-side arm member 520 can be stabilized.

  The stopper wall portion 563a is a wall portion for preventing the movable member 540 from swinging beyond its movable range when the movable member 540 is moved toward the extended position (see FIG. 43). is there. When moving member 540 moves to the right from the state shown in FIG. 43, stopper wall portion 563a and sensor passage plate 524 and raised portion 521a to which sensor passage plate 524 is fastened and fixed (see FIG. 40) come into contact. You. The stopper wall 563a extends not only on the front side but also on the back side. Thus, the contact area between one end of the drive-side arm member 520 and the stopper wall 563a can be increased, and the sensor passage plate 524 and the raised portion 521a to which the sensor passage plate 524 is fastened and fixed at the time of contact. Can be reduced.

  With reference to FIG. 42 and FIG. 43, the end of the movable range of the swing operation unit 500 will be described. 42 (a) and 43 are front views of the swing operation unit 500, and FIG. 42 (b) is a side view of the swing operation unit 500 as viewed in the direction of the arrow XXXXIIb in FIG. 42 (a). FIG. 42 illustrates a state in which the moving member 540 is disposed at the retracted position, and FIG. 43 illustrates a state in which the moving member 540 is disposed at the extended position.

  As shown in FIGS. 42 and 43, when the moving member 540 swings from the retracted position to the extended position, the posture of the moving member 540 is not changed. Therefore, when the pair of left and right moving members 540 (see FIG. 6) are close to each other (both are rocked to the overhang position), the opposed side surfaces (the right side surface in FIG. 43) remain parallel. Since they are brought close to each other, it is possible to easily combine the pair of moving members 540 by fitting the positioning portions 543 together.

  In a state where the moving member 540 is located at the overhang position, the bridging member 528 is put on the front side surface of the driven arm member 530. Further, since the distance between the drive side arm member 520 and the driven side arm member 530 is reduced, the drive side arm member 520 and the driven side arm member 530 can be brought into contact when swinging beyond the extended position. Thus, the swing of the drive-side arm member 520 can be stopped.

  As shown in FIGS. 42 (a) and 42 (b), the center of gravity G of the moving member 540 is formed on the side (the right side in FIG. 42) where the pair of moving members 540 is abutted in the left-right direction. In the direction, it is formed separately from the driving side arm member 520 and the driven side arm member 530.

  As shown in FIG. 43, a bridging member 528 fastened and fixed to the front side of the drive side arm member 520 is extended so as to cover the front side of the driven side arm member 530.

  Here, with reference to FIG. 44, a difference in a fastening position between the first bridge member 528a and the second bridge member 528b will be described. Due to the difference between the fastening portions, the ease with which the first bridge member 528a and the second bridge member 528b are turned from the drive-side arm member 520 differs.

  Here, “turning up” means that the bridging member 528 receives a force from the driven arm member 530 upward in FIG. 44 and is separated from the driving arm member 520.

  FIG. 44A is a cross-sectional view of the driving arm member 520, the driven arm member 530, and the first bridging member 528a taken along the line XXXXIVa-XXXIVa in FIG. 43, and FIG. It is sectional drawing of the drive side arm member 520, the driven side arm member 530, and the 2nd bridge member 528b in the -XXXIVb line.

  First, as a first difference, as shown in FIG. 44B, the second fastening holes 527b1 and the second pin fastening holes 527b2 for receiving the second bridging members 528b are different from the first fastening holes 527a. A platform 527b3 is formed. Thereby, the second embedding width Wb1, which is the embedding width of the insertion portion 528b2 in the second fastening hole 527b1, is longer than the first embedding width Wa1, which is the embedding width of the insertion portion 528a2 in the first fastening hole 527a1. Is done. Therefore, the second bridging member 528b can be fixed more firmly than the first bridging member 528a (the second bridging member 528b is harder to bend than the first bridging member 528a).

  As a second difference, the first overhang width Wa2, which is the overhang width of the insertion portion 528b2 from the main body plate portion 521 in the fastened and fixed state, is the overhang width of the insertion portion 528a2 from the main body plate portion 521. It is shorter than the second overhang width Wb2. Therefore, the second bridging member 528b can suppress deformation near the fastening position as compared with the first bridging member 528a (the second bridging member 528b has a smaller shape than the first bridging member 528a). It is hard to turn up compared).

  As a third difference, the first fastening hole 527a1 is formed on the opposite side of the driven arm member 530 with respect to the first pinning hole 527a2 (see FIG. 44A), but the second fastening hole 527b1 is The two-pin fastening hole 527b2 is formed on the side close to the driven arm member 530 as a reference (see FIG. 44B).

  In this case, the driven arm member 530 moves (bends and falls down) in a direction (upward in FIG. 44) approaching the bridging member 528, and is fastened when a load is applied from the driven arm member 530 to the bridging member. There is a difference in how to bear in the part.

  That is, when the first bridging member 528a is pushed by the driven arm member 530 and the main body 528a1 bends with the insertion portion 528a2 as a starting point, the auxiliary protrusion 528a3 separates from the driving arm member 520 (FIG. 44 (a)). Therefore, a frictional resistance between the side surface of the auxiliary protrusion 528a3 and the inner surface of the first pin hole 527a2 generates a resisting force against the turning of the main body 528a1.

  On the other hand, when the second bridging member 528b is pushed by the driven arm member 530 and the main body 528b1 bends from the insertion portion 528b2 as a starting point, the seating surface of the auxiliary projection 528b3 is pressed against the driving arm member 520. (See FIG. 44 (b)). Therefore, in addition to the frictional resistance between the side surface of the auxiliary protrusion 528b3 and the inner surface of the second pin hole 527b2, the seat surface of the auxiliary protrusion 528b3 is located on the front side (upper side in FIG. 44B) of the main body plate portion 521. , A resistance to turning of the main body 528b1 is generated.

  Accordingly, the resistance of the second bridging member 528b to turning can be increased as compared to the resistance of the first bridging member 528a to turning.

  The distance between the axes of the second fastening hole 527b1 and the second pinning hole 527b2 is longer than the distance between the axes of the first fastening hole 527a1 and the first pinning hole 527a2.

  Due to the first to third differences described above, a similar load is applied from the driven side arm member 530 to either the first bridging member 528a or the second bridging member 528b toward the front side (upward in FIG. 44). In this case, the second bridging member 528b has a stronger resistance at the root to the turning (a force to resist turning at the fastening position with the driving arm member 520) than the first bridging member 528a. growing.

  With reference to FIG. 45, a description will be given of an aspect of contact between the driven arm member 530 and the bridging member 528 when the driven arm member 530 is bent and deformed. FIG. 45 (a) is a partial side view of the swing operation unit 500 as viewed in the direction of the arrow XXXXVa in FIG. 43. FIGS. 45 (b) and 45 (c) show the state of FIG. FIG. 10 is a partial side view of the swing operation unit 500 illustrating a state in which an arm member 530 flexes to the front side in time series.

  Note that FIG. 45 (a) illustrates a state in which the longitudinal directions of the drive side arm member 520 and the driven side arm member 530 are parallel, and FIG. 45 (b) illustrates that the driven side arm member 530 is on the front side (FIG. 45). FIG. 45 (b) shows a state in which the driven arm member 530 is bent toward the front side from the state shown in FIG. 45 (b) in FIG. 45 (c). A state in which it is in contact with the bridging member 528b is illustrated. Further, in FIG. 45, the base member 510, the moving member 540, and the front plate member 560 are illustrated virtually by imaginary lines.

  As shown in FIG. 45, the first bridging member 528a is disposed closer to the moving member 540 than the second bridging member 528b. Therefore, when the upper end of the driven arm member 530 is bent to the front side (the left side in FIG. 45) due to factors such as the weight of the moving member 540 and the contact with other members, the first bridge is started first when the amount of bending is small. The driven arm member 530 abuts on the bridging member 528a (see FIG. 45B). Thereafter, when the amount of bending of the driven side arm member 530 increases, the first bridging member 528a bends and deforms, and the second bridging member 528b abuts on the driven side arm member 530 (see FIG. 45 (c)).

  That is, since the displacement of the driven arm member 530 is greater in the portion that abuts on the first bridge member 528a, a larger load is applied to the first bridge member 528a than in the second bridge member 528b. Can be

  Here, when the resistance of the first bridging member 528a to the bending deformation is as large as that of the second bridging member 528b, the first bridging member 528a bends and deforms even if the amount of bending of the driven arm member 530 increases. (The drive side arm member 520 may bend instead). In this case, the driven arm member 530 and the second bridging member 528b do not come into contact with each other, and only the first bridging member 528a receives the load from the driven side arm member 530 alone. The durability of the member 528a decreases.

  On the other hand, in the present embodiment, as described above, the first bridging member 528a is fastened to the drive-side arm member 520 in a manner that the first bridging member 528b is more easily turned at the root portion than the second bridging member 528b. Therefore, before the driven side arm member 530 contacts the second bridging member 528b, the first bridging member 528a is easily turned up (is deformed in the vicinity of the root with respect to the driving side arm member 520).

  In addition, the width of the first bridging member 528a in the lateral direction is smaller than that of the second bridging member 528b, and the plate thickness is formed to be equal (see FIG. 44). That is, the section modulus of the second bridge member 528b in the same direction is larger than that of the first bridge member 528a in the direction of the load applied to the bridge member 528 from the driven arm member 530. Is done. Therefore, the first bridging member 528a is more likely to bend in the short vertical direction (the left and right direction in FIG. 45A) than the second bridging member 528b.

  This allows the pair of bridging members 528 to contact the driven arm member 530 and receive the load (see FIG. 45 (c)), and distribute the load to the pair of bridging members 528 to bear the load. As a result, the durability of the first bridge member 528a and the second bridge member 528b can be improved.

  Note that the method of receiving the load from the driven arm member 530 by the pair of bridging members 528 is not limited to bending the first bridging member 528a. For example, by making the first overhang width Wa2 (see FIG. 44) of the first bridging member 528a longer than that of the present embodiment, the driven arm member 530 and the first bridge can be bent at the bending amount shown in FIG. The bridging member 528a may not be brought into contact, and the pair of bridging members 528 may start to come into contact with the driven arm member 530 at the same time with the amount of bending shown in FIG. In this case, both the first bridging member 528a and the second bridging member 528b can receive the load from the driven arm member 530, and the load is applied to the first bridging member 528a and the second bridging member 528b. Can be distributed and paid.

  On the other hand, when the amount of bending is small (see FIG. 45 (b)), the driven arm member 530 does not abut on any of the pair of bridging members 528, so it is difficult to suppress the bending of the driven arm member 530. (The bending is suppressed only by the rigidity of the driven arm member 530 until the bending amount of FIG. 45C is reached).

  In contrast, in the present embodiment, while the amount of bending of the driven side arm member 530 is small, bending can be suppressed by bringing the driven side arm member 530 into contact with the first bridge member 528a (FIG. 45). (B)). In addition, as described above, when the amount of bending of the driven side arm member 530 increases, the first bridging member 528a bends and deforms, and the driven side arm member 530 and the second bridging member 528b abut. Thereby, the load from the driven arm member 530 can be received by the pair of bridging members 528, and the load can be distributed to the pair of bridging members 528 and borne, so that the first bridging members 528a and The durability of the second bridge member 528b can be improved.

  Next, with reference to FIG. 46, a description will be given of the front-rear relationship of the driving arm member 520, the driven arm member 530, and the bridging member 528. FIG. 46 is a cross-sectional view of the drive-side arm member 520 and the driven-side arm member 530 along the line XXXXIV-XXXXXIV in FIG. Note that FIG. 46 shows only a cross-sectional view of a long portion of the drive-side arm member 520 and the driven-side arm member 530 for easy understanding, and the shapes of the ends of the arm members 520 and 530 are omitted. I do.

  As shown in FIG. 46, the drive-side arm member 520 and the driven-side arm member 530 have front side surfaces (upper side surfaces in FIG. 46) formed substantially in the same plane, and the bridging member 528 is connected to the driven-side arm member 530. It is put on the front side of. Accordingly, the driven arm member 530 moves to the front side along the arrow B1 (bending deformation and falling deformation), and the driving side arm member 520 moves to the back side along the arrow B2 (deflecting deformation and falling deformation). Or rotation (twist deformation) of the drive-side arm member 520 along the arrow B3 can be suppressed. That is, the relative movement (deformation) between the drive side arm member 520 and the driven side arm member 530 can be suppressed by abutting the bridge member 528 and the driven side arm member 530.

  Here, the moving member 540 (see FIG. 43) is disposed on the front side of the driving arm member 520 and the driven arm member 530, and the center of gravity G of the moving member 540 is formed on the front side of each arm member 520, 530. (See FIG. 42). As described above, the center of gravity G of the moving member 540 is formed closer to the side where the pair of moving members 540 abut (the right side in FIG. 43), so that the driven arm member 530 is There is a great risk of falling. On the other hand, when the driven side arm member 530 falls forward, the driven side arm member 530 is supported (contacted) from the front side of the bridge member 528. Accordingly, it is possible to prevent the driven arm member 530 from moving to the front side (the front side in FIG. 43), and to move the moving member 540 to the front side.

  Since the driving side arm member 520 is a member to which the driving force is transmitted, there is a possibility that the driving side arm member 520 may fluctuate in the swing axis direction (vertical direction in FIG. 46) depending on the degree of the transmission. The wobble can be suppressed by abutment of the bridge member 528 and the driven arm member 530.

  On the other hand, when the drive side arm member 520 moves to the front side along the arrow B1 (bending deformation or falling deformation) or rotates clockwise (twisting deformation) in the opposite direction to the arrow B3, the bridge Since the bridging member 528 is moved in a direction away from the driven arm member 530, it is difficult to suppress the movement of the driving arm member 520. Therefore, it is preferable to have a mechanism for preventing these movements. Next, referring to FIG. 47, it is possible to prevent the drive-side arm member 520 from moving forward (bending movement or falling down) along the arrow B1, or to set the drive-side arm member 520 in the direction opposite to the arrow B3. A mechanism for suppressing clockwise rotation (twist deformation) will be described.

  FIG. 47 is a partial cross-sectional view of the swing operation unit 500 along the line XXXXV-XXXXXV in FIG. As shown in FIG. 47, one end of the driving arm member 520 is in contact with the transmission gear 553 from the front side (the upper side in FIG. 47). That is, the gear portion 523 is abutted from the front side of the first gear portion 553a of the transmission gear 553, and the umbrella portion 523a is abutted from the front side of the second gear portion 553b. Here, regardless of the arrangement of the driving arm member 520, the transmission gear 553 is disposed on the opposite side of the driven arm member 530 with respect to the straight line connecting the shaft support holes 522 and 526 formed at both ends of the driving arm member 520. (See FIGS. 48 to 50).

  Therefore, when the side of the drive side arm member 520 that is close to the driven side arm member 530 moves to the front side (torsion deformation in the direction opposite to the arrow B3 in FIG. 46), the gear portion 523 is pressed against the first gear portion 553a. Is moved in a direction in which the umbrella portion 523a is pressed against the second gear portion 553b. In this case, the deformation resistance of the drive-side arm member 520 increases. Therefore, the movement (twisting deformation) of the driving side arm member 520 in the direction opposite to the arrow B3 in FIG. 46 can be suppressed.

  As shown in FIG. 47, a sensor passage plate 524 is disposed at the front end of one end of the drive-side arm member 520, in front of the front plate member 560. Accordingly, when the other end (the right side in FIG. 47) of the drive-side arm member 520 moves to the front side along the arrow B1 (bending deformation or falling deformation), one end sandwiching the second shaft 512b. The deformation resistance of the drive-side arm member 520 can be increased by contacting the sensor passage plate 524 with the front plate member 560 in the portion. Therefore, it is possible to suppress the other end of the drive-side arm member 520 from moving in the arrow B1 direction (bending deformation or falling deformation).

  As shown in FIG. 47, the collar member 525 is formed with a thickness substantially equal to the thickness of the first gear portion 553a of the transmission gear 553. As shown in FIG. 41, the collar member 525 is formed in a shape smaller than the outer shape of one end of the drive-side arm member 520 in a front view, so that the base member 510 and the drive-side arm member are formed by the collar member 525. 520 can be reduced in contact area. Therefore, the contact resistance when the drive side arm member 520 is swung can be suppressed, and the size of the drive motor 551 can be reduced.

  Next, the swing operation of the driving arm member 520 and the driven arm member 530 will be described with reference to FIGS. 48 to 50 are front views of the driving arm member 520 and the driven arm member 530. In FIG. 48, a state in which the driving arm member 520 and the driven arm member 530 are disposed at the retracted position as in FIG. 42, and in FIG. 49, the driving arm member 520 and the driven arm member 520 are changed from the state in FIG. FIG. 50 shows a state in which the member 530 has been swung by a predetermined amount, and FIG. 50 shows a state in which the drive-side arm member 520 and the driven-side arm member 530 are disposed at the extended positions, respectively. 48 to 50, the outer shape of the moving member 540 is illustrated by imaginary lines, the sensor passing plate 524 is not illustrated, and a part of the first gear portion 553a of the collar member 525 and the transmission gear 553 is indicated by a hidden line. As shown, the umbrella portion 523a of the gear portion 523 is partially omitted so that the gear teeth are visible.

  As shown in FIGS. 48 to 50, the distance between the drive side arm member 520 and the driven side arm member 530 is reduced from the retracted position to the extended position. Therefore, the area where the bridging member 528 covers the driven side arm member 530 increases from the retracted position to the overhanging position, and the driven side arm member 530 moves to the front side, and when the bridge member 528 comes into contact with the bridging member 528, The resistance generated from the bridging member 528 can be increased.

  As shown in FIG. 48, the rib portion 528a4 of the first bridging member 528a and the rib portion 528b4 of the second bridging member 528b are formed by the one side shaft support hole 532 and the other side shaft support hole of the driven arm member 530. 533 is formed below the straight line. Therefore, at the retracted position, the driven side arm member may change its posture in such a manner that a portion above a straight line connecting the one-side shaft support hole 532 and the other-side shaft support hole 533 falls forward (toward the front in FIG. 48). The distance between 530 and bridge member 528 can be kept large. Thereby, when the drive side arm member 520 and the driven side arm member 530 start from the retracted position, the driven side arm member 530 falls forward and comes into contact with the bridge member 528, so that the drive side arm member 520 and the driven side It is possible to prevent the swing resistance of the arm member 530 from increasing.

  On the other hand, as shown in FIG. 50, the rib portion 528a4 of the first bridging member 528a and the rib portion 528b4 of the second bridging member 528b are disposed at intermediate positions in the longitudinal direction of the driven arm member 530. . Therefore, at the overhang position, the distance between the driven arm member 530 and the bridging member 528, which may change in posture in a state of falling and deforming starting from the one shaft support portion 532, can be reduced. Thus, at the overhang position, the driven arm member 530 and the bridging member 528 can be brought into contact with each other since the amount of deformation of the driven arm member 530 falling down is small.

  That is, the rib portions 528a4 and 528b4 suppress the swing resistance when the driving arm member 520 and the driven arm member 530 start from the retracted position, and the driven arm member 530 is disposed at the extended position. In this state, the contact between the driven arm member 530 and the bridging member 528 can be made compatible from within a small amount of the tilt deformation of the driven arm member 530.

  Also, while the drive-side arm member 520 moves from the retracted position to the extended position, the bridge member 528 is at least partially disposed on the front side of the driven arm member 530. . Accordingly, while the bridging member 528 is not disposed on the front side of the driven arm member 530, the driven arm member 530 moves in the axial direction, and the side surface of the driven arm member 530 facing the driving arm member 520. And the bridge member 528 can be prevented from coming into contact with each other. Further, since the driven arm member 530 can always contact the bridging member 528, the effect of suppressing the axial displacement of the driven arm member 530 can be improved.

  As shown in FIG. 50, in a state where the moving member 540 is disposed at the extended position, the driving arm member 520 and the driven arm member 530 are on the side where the pair of moving members 540 abut (right side in FIG. 50). Take a posture inclined to the opposite side of the. Therefore, there is a possibility that it is necessary to keep operating the drive motor 551 in order to maintain the arrangement of the moving member 540 (to prevent the drive side arm member 520 from rotating counterclockwise in front view).

  On the other hand, in the present embodiment, the center of gravity G of the moving member 540 is formed on the side where the pair of moving members 540 abut (the right side in FIG. 50). Therefore, in a state where the moving member 540 is located at the extended position, the driving arm member 520 and the driven arm member 530 receive a load from the moving member 540 in the clockwise direction when viewed from the front. This can prevent the drive-side arm member 520 from rotating counterclockwise in front view, so that it is not necessary to keep the drive motor 551 operating while the moving member 540 is located at the extended position. Thus, power consumption of the drive motor 551 can be reduced.

  The transmission gear 553 and the gear portion 523 formed at one end of the drive-side arm member 520 are in contact in the front-rear direction as described above. As shown in FIGS. 48 to 50, the contact surfaces of the transmission gear 553 and the gear portion 523 are moved in substantially the same direction (leftward in FIG. 48) during the swinging operation of the driving arm member 520.

  That is, the driving force required for the rotation of the gear portion 523 is generated not only from the engagement of the transmission gear 553 with the second gear portion 553b, but also from the front side (the front side in FIG. 48) of the first gear portion 553a. It can also be transmitted by contact with the rear side surface of the portion 523. This can be said that the swing resistance of the drive-side arm member 520 has been reduced. Thus, the driving force required for the drive motor 551 can be reduced, and the size of the drive motor 551 can be reduced.

  As shown in FIG. 48, the collar member 525 has a longitudinal direction connecting the pair of fastening portions 525c and a short direction that is a direction perpendicular to the longitudinal direction, and the longitudinal direction is in a posture along the longitudinal direction of the driving arm member 520. The driving side arm member 520 is fastened and fixed. Thus, the collar member 525 and the base member 525 extend along the longitudinal direction of the drive side arm member 520 as compared with the range in which the collar member 525 and the base member 510 contact with each other along the lateral direction of the drive side arm member 520. The range of contact with 510 is increased.

  Therefore, the other end (the end on the left side in FIG. 48) of the drive-side arm member 520 starts from the second shaft portion 512b (see FIG. 40) inserted through the one-side shaft support hole 522, and starts in the front-rear direction (see FIG. 48). When deforming to bend in the direction perpendicular to the paper surface, the range in which the collar member 525 is pressed against the base member 510 (see FIG. 40) can be increased. Thus, the deformation resistance of the driving arm member 520 can be increased.

  The straight line L connecting the central axis of the collar member 525 and the central axis of the transmission gear 553 always intersects the circular outer shape of the main body 525a of the collar member 525. That is, it does not intersect with the outer shape of the fastening portion 525c. Thus, the center distance between the collar member 525 and the transmission gear 553 can be reduced to a minimum length.

  In other words, there is no need to insert the fastening portion 525c arranged in the longitudinal direction of the collar member 525 between the central axis of the collar member 525 and the central axis of the transmission gear 553, and therefore, the central axis of the collar member 525 and the transmission gear The center-to-center distance between the 553 and the central axis can be reduced. This inter-axis distance is a distance at which the main body 525a of the collar member 525 and the transmission gear 553 can be arranged to face each other. Thus, the degree of freedom in the arrangement of the collar member 525 can be improved, and the degree of freedom in the arrangement of the drive side arm member 520 can be improved.

  Further, even when the center distance between the center axis of the collar member 525 and the center axis of the transmission gear 553 is the same, when the fastening portion 525c enters between the center axis of the collar member 525 and the center axis of the transmission gear 553. In comparison, the contact area in the axial direction between the first gear portion 553a of the transmission gear 553 and the driving arm member 520 can be increased.

  Next, a swing operation unit 2500 according to the second embodiment will be described with reference to FIG. In the first embodiment, the case where the end of the bridging member 528 of the oscillating operation unit 500 is not fixed has been described. However, the oscillating operation unit 2500 according to the second embodiment is configured such that the main body 2561 of the front plate 2560 has It is provided with a thickened portion 2561a for accommodating the tip of the bridging member 2528. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIGS. 51A and 51B are partial front views of the swing operation unit 2500 in the second embodiment. Note that FIG. 51A illustrates a state in which the moving member 540 is disposed at the retracted position, and FIG. 51B illustrates a state in which the moving member 540 is disposed at the extended position. 51 (a) and FIG. 51 (b), the moving member 540 is illustrated by imaginary lines.

  As shown in FIGS. 51A and 51B, the main body 2528a of the bridging member 2528 is formed over the width direction of the driven arm member 530. Accordingly, when the driven arm member 530 moves toward the front side (downward in FIG. 51), the area of the main body 2528a contacting the driven arm member 530 is reduced to the first embodiment. It is possible to enlarge in comparison, and it is possible to suppress the movement of the driven arm member 530.

  The main body 2561 of the front plate member 2560 has a thickened portion 2561a formed by increasing the thickness in the front-rear direction (the direction perpendicular to the paper surface of FIG. 51) at the upper end thereof, and a concave portion provided downward from the upper end surface of the thickened portion 2561a. Accommodating portion 2561b.

  The accommodation portion 2561b is a depression that is recessed in a state where the four sides are closed when viewed from above, and in a state where the moving member 540 is disposed at the extended position, the depression where the distal end portion of the bridging member 2528 is accommodated. It is. The inner side surface of the accommodation portion 2561b includes a mode in which the movement trajectory of the tip portion (the upper end portion in FIG. 51A) of the bridging member 2528 is included (the tip portion of the bridging member 2528 is moved while the moving member 540 is moving). (A form that does not come into contact with the inner side surface of the housing portion 2561b). This prevents the bridging member 2528 from abutting on the rotation-side inner surface of the drive-side arm member 2520 of the inner surface of the storage portion 2561b while moving the moving member 540 from the retracted position to the extended position. can do.

  As shown in FIG. 51B, the end of the bridging member 2528 is housed in the housing part 2561b in a state where the moving member 540 is arranged at the overhang position. Therefore, for example, when the driven arm member 530 moves to the front side (for example, falls down) to apply a load to the bridging member 2528, the resistance to the load can be improved.

  That is, when the tip of the bridging member 2528 is not accommodated in the accommodating portion 2561b, the bridging member 2528 is cantilevered and resists a load from the driven arm member 530 (a load facing the front side in FIG. 51). (The bridging member 2528 is fastened to the driving arm member 2520). On the other hand, when the distal end of the bridging member 2528 is housed in the housing portion 2561b, it is possible to generate a resisting force by supporting both ends with respect to the load from the driven arm member 530 (fastening with the driving arm 2520). Position and the receiving portion 2561b). Accordingly, it is possible to prevent the driven arm member 530 from moving to the front side.

  Further, since the bridging member 2528 is fastened and fixed to the driving arm member 2520, the front end of the bridging member 2528 is housed in the housing part 2561b, so that the positioning of the driving arm member 2520 in the front-rear direction is performed. be able to.

  In this case, the positioning of the moving members 540 of the swinging operation unit 2500 formed in a pair on the left and right can be performed in the front-rear direction, and the pair of moving members 540 are arranged at the extended position (see FIG. 8). In this case, it is possible to suppress the occurrence of relative displacement between the pair of moving members 540 in the front-rear direction. The accommodation portion 2561b is disposed at a position closer to the abutment position (see FIG. 8) between the pair of moving members 540 than the driving side arm member 2520, so that the moving members 540 generated from the accommodation portion 2561b as a starting point. Can be reduced.

  Thereby, the effect of correcting the displacement between the pair of moving members 540 can be ensured, and the effect of rendering the pair of moving members 540 integrally visible in a state where the pair of moving members 540 are arranged at the extended position. Can be improved.

  Next, a swing operation unit 3500 in the third embodiment will be described with reference to FIG. In the first embodiment, the case where the outer surface of the umbrella portion 523a of the drive side arm member 520 is formed in an arc shape has been described, but the swing operation unit 3500 in the third embodiment extends outward from the umbrella portion 523a. An overhang portion 3523b is provided. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIGS. 52A to 52C are front views of the swing operation unit 3500 in the third embodiment, and FIG. 52D shows the swing along the line Ld-Ld in FIG. 52B. It is sectional drawing of operation unit 3500. In FIG. 52, for ease of understanding, only the base member 3510, the driving arm member 3520, and the driving device 550 are illustrated, and other members are not illustrated, and the photo sensor 514 and the driving of the base member 3510 are not illustrated. Illustration of the sensor passage plate 524 of the side arm member 3520 is omitted.

  FIG. 52A shows a state in which the driving arm member 3520 and the moving member 540 (see FIG. 7) are arranged at the retracted position. In FIG. 52B, the driving arm member 3520 and the moving member 540 are shown. FIG. 52 (c) shows a state in which the drive side arm member 3520 and the moving member 540 (see FIG. 7) are arranged at the extended position. Is illustrated.

  As shown in FIG. 52, the drive-side arm member 3520 includes a projecting portion 3523b extending from the umbrella portion 523a outward in the axial direction. The overhang portion 3523b is disposed below the second shaft portion 512b regardless of the posture of the drive-side arm member 3520, and has a width between the outer peripheral wall 3516 and the second gear portion 553b of the transmission gear 553. It is formed with the above width (see FIG. 52B). That is, during the swinging operation of the drive-side arm member 3520, one of the outer peripheral wall 3516 and the second gear portion 553b of the transmission gear 553 is disposed on the rear side of the overhang portion 3523b.

  The base member 3510 includes an outer peripheral wall 3516 that is curved and formed along the outer circumference of the umbrella portion 523a on the outer side in the axial direction of the umbrella portion 523a. The outer peripheral wall 3516 protrudes from the front side of the main body 511 of the base member 3510 to the same height as the front side surface of the second gear portion 553b of the transmission gear 553 (see FIG. 52D).

  As a result, it is possible to prevent the drive-side arm member 3520 from moving forward (falling or bending) starting from the second shaft portion 512b of the shaft support portion 512 as a starting point. That is, the drive-side arm member 3520 moves (falls down or bends) to the front side above the second shaft portion 512b due to the weight of the moving member 540 (see FIG. 43), and moves below the second shaft portion 512b. Moves to the back side (falling down or bending). In this case, in addition to the umbrella portion 523a contacting the front side surface of the transmission gear 553, the overhang portion 3523b contacts the front end surface of the outer peripheral wall 3516. Thereby, the movement (tilting deformation or bending deformation) of the driving side arm member 3520 can be suppressed by contact at two positions.

  Further, as shown in FIG. 52 (c), when the drive side arm member 3520 is arranged at the extended position, the drive side arm member 3520 is compared with the case where the drive side arm member 3520 is arranged at another position. The contact position between the transmission shaft 3520 and the transmission gear 553 in the front-rear direction can be set at a position separated from the second shaft portion 512b in the shaft radial direction.

  That is, when the drive-side arm member 3520 is located at the overhang position, the umbrella portion 523a is opposed to the front side surface of the gear tooth portion of the second gear portion 553b, while the overhang portion 3523b is located at the second gear portion. 553b is disposed opposite to the front side surface of the main body. In this case, the overhang portion 3523b can abut on the main body portion of the second gear portion 553b in the front-rear direction. Such an arrangement is not seen in FIGS. 52 (a) and 52 (b).

  Further, the state in which the drive side arm member 3520 is disposed at the overhang position is such that the longitudinal direction of the drive side arm member 3520 runs along the up and down direction. This is a state in which movement in the front-rear direction (tilting deformation or bending deformation) tends to occur with a large width. In the present embodiment, as described above, the contact position between the drive-side arm member 3520 and the transmission gear 553 in the front-rear direction can be set at a position separated from the second shaft portion 512b in the shaft radial direction. The resistance to the movement of the 3520 in the front-rear direction can be increased, and the movement can be suppressed.

  Next, a composite operation unit 4400 according to the fourth embodiment will be described with reference to FIGS. In the first embodiment, the case has been described where the guide hole 424b of the guide plate 424 is a smooth long hole without being caught. However, the combined operation unit 4400 in the fourth embodiment has a concave portion on the upper side surface of the guide hole 4424b. 4424c is formed. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 53 is a front view of the combined operation unit 4400 according to the fourth embodiment in a state where the main body member 410 is disposed at the intermediate position. 53 and 54, the illustration of the collar member of the slide shaft portion 423e is omitted, and the shaft portion is made visible.

  As shown in FIG. 53, when the main body 410 of the combined operation unit 4400 moves down from the retracted position and is located at the intermediate position, the slide shaft 423e of the connecting member 423 contacts the inner end of the guide hole 4424b. Touch A recess 4424c, which is a recess capable of accommodating a part of the slide shaft portion 423e, is formed on the upper side surface of the guide hole 4424b disposed right above the contact position. The concave portion 4424c is formed in an arc shape, and the radius of curvature of the concave portion 4424c is formed to be equal to or larger than the radius of the slide shaft portion 423e.

  Here, when the main body member 410 moves downward from the retracted position, the shaft support hole 423d arranged at the end of the connecting member 423 opposite to the slide shaft 423e moves in the vertical direction. Therefore, when the slide shaft portion 423e of the connecting member 423 comes into contact with the inner end of the guide hole 4424b and rebounds, the shaft support hole 423d rebounds in the vertical direction. Therefore, the slide shaft portion 423e also rebounds upward due to the upward rebound momentum.

  With reference to FIG. 54, the effect of the concave portion 4424c will be described. FIGS. 54A and 54B are partial front views of the composite operation unit 4400. FIG. FIG. 54A shows a state immediately before the slide shaft 423e of the connecting member 423 comes into contact with the inner end of the guide hole 4424b. In FIG. 54B, the slide shaft 423e of the connecting member 423 is The state immediately after contacting the inner end of the guide hole 4424b is illustrated. In FIG. 54, the slide lever 473, the solenoid 474, the wiring guide arm 480, and the like are omitted for easy understanding, and the slide shaft 423e and the direction of movement of the opposite end of the slide shaft 423e. Are shown by arrows C41 to C44.

  As shown in FIG. 54 (a), when the main body member 410 is moved downward and the opposite end of the connecting member 423 on the opposite side of the slide shaft 423e is moved downward along the arrow C42, the slide shaft is moved. 423e contacts the lower side surface of the guide hole 4424b and slides along the arrow C41. Therefore, the slide shaft portion 423e is not accommodated in the recessed portion 4424c.

  On the other hand, as shown in FIG. 54 (b), the slide shaft 423e abuts against the inner end of the guide hole 4424b and rebounds, and the end of the connecting member 423 on the side opposite to the slide shaft 423e follows the arrow C44. In the case of bouncing upward, the slide shaft 423e is also pressed upward. In this case, the slide shaft portion 423e contacts the upper side surface of the guide hole 4424b and tries to slide along the arrow C43. Therefore, the slide shaft portion 423e is housed in the concave portion 4424c.

  Therefore, the slide shaft portion 423e and the concave portion 4424c can be brought into contact with each other in the left-right direction that is the long direction of the guide hole 4424b. In this case, a large resistance can be generated for the slide shaft portion 423e that is moving in the long direction of the guide hole 4424b.

  Accordingly, it is possible to prevent the slide shaft portion 423e from moving along the left and right directions of the guide hole 4424b. Therefore, the rebound width of the slide shaft portion 423e can be reduced, and the arrangement of the shielding member 420 can be stabilized. By moving the main body member 410 (see FIG. 21) upward by the driving device 460, the slide shaft 423e is driven inside the guide hole 4424b in the left-right direction.

  Next, a composite operation unit 5400 in the fifth embodiment will be described with reference to FIGS. In the first embodiment, the case where the end on the slide shaft 423e side of the connecting member 423 is in contact with only the guide plate 424 has been described. A leaf spring member 5425, which is a plate-shaped spring member, which is in contact with the end on the shaft portion 423e side, is formed. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 55 is a rear view of the combined operation unit 5400 according to the fifth embodiment in a state where the main body member 410 is located at the retracted position. As the main body member 410 moves downward from the retracted position, the slide shaft 423e of the connecting member 5423 moves in the left and right direction inside the guide hole 424b of the guide plate 5424.

  The connecting member 5423 includes a protruding portion 5423f that protrudes from an end of the rod member 423a on the slide shaft portion 423e side. The protruding portion 5423f is protruded vertically upward in a state where the slide shaft portion 423e of the connecting member 5423 is disposed at an inner end portion of the guide hole 424b, and also has a right side in rear view (FIG. 56 (c)). The right corner is rounded and the left corner in rear view is formed at a right angle.

  The guide plate 5424 is provided with a grip portion 5424c projecting in a U-shape on the rear side of the base plate 424a at the upper outer ends of the pair of guide holes 424b. The holding portion 5424c is formed in such a manner that the open side of the U-shaped portion is directed inward in the left-right direction, and one end of the leaf spring member 5425 is sandwiched by the inner surface of the U-shaped portion.

  The details of the leaf spring member 5425 will be described with reference to FIG. FIGS. 56A to 56C are partial rear views of the composite operation unit 5400. FIG. 56 (a) to 56 (c), the movement of the connecting member 5423 is illustrated in chronological order, and the periphery of the guide hole 424b on the left side in rear view is partially illustrated. ) Shows a state in which the main body member 410 (see FIG. 55) is arranged at the retreat position, and FIG. 56B shows a state in which the main body member 410 has moved a predetermined distance from the retreat position to the intermediate position. In c), the state in which the main body member 410 is disposed at the intermediate position is illustrated.

  56, only the decorative member 422, the connecting member 5423, the guide plate 5424, and the leaf spring member 5425 are illustrated in FIG. 56, and other members are not illustrated. Further, only the outer shape of the decorative member 422 and the connecting member 5423 is illustrated, and illustration of the internal pattern and the like is omitted.

  As shown in FIG. 56 (a), the leaf spring member 5425 is disposed in a posture in which the elongate direction is directed to the left and right, and one end portion is a fixed portion 5425a having a shape of a straight plate that is gripped by the grip portion 5424c. And a curved portion 5425b which is connected to the other end of the fixed portion 5425a and protrudes toward the connecting member to form a curved portion, and from the end inside the curved portion 5425b (the right side in FIG. 56 (a)) in the left-right direction. And a fall prevention part 5425c extended to the main part.

  The curved portion 5425b is formed such that the first inclined surface 5425b1 formed on the outside in the left-right direction and the second inclined surface 5425b2 formed on the inside in the left-right direction have different inclination angles with respect to the left-right direction. That is, the first inclined surface 5425b1 is gently inclined from the left and right direction (the inclination angle is reduced), and the second inclined surface 5425b2 is rapidly inclined from the left and right direction (the inclination angle is increased to near a right angle).

  The fall prevention portion 5425c is in contact with the upper end of the protruding portion 5423f in a state where the slide shaft portion 423e of the connecting member 5423 is disposed at the inner end (right side in FIG. 56A) of the guide hole 424b. Accordingly, even if the end of the leaf spring member 5425 on the opposite side to the gripping portion 5424c may drop downward due to aging or the like, in the state of FIG. 56 (c), the protruding portion 5423f causes the leaf spring member 5425 to move. By lifting, the positional relationship between the leaf spring member 5425 and the protruding portion 5423f can be maintained. That is, it is possible to prevent the end of the leaf spring member 5425 on the opposite side of the grip portion 5424c from hanging downward.

  Here, a change in the direction of the force generated between the projecting portion 5423f and the leaf spring member 5425 during the movement of the connecting member 5423 will be described. When the slide shaft portion 423e of the connecting member 5423 is disposed at the left end of the guide hole 424b, the projecting portion 5423f and the leaf spring member 5425 are separated from each other. No force is generated (see FIG. 56 (a)).

  As the slide shaft portion 423e of the connecting member 5423 moves inward in the left-right direction of the guide hole 424b (the right side in FIG. 56 (a)), the posture of the connecting member 5423 changes, and the protruding portion 5423f is attached to the leaf spring member 5425. It gradually approaches and comes into contact soon (see FIG. 56 (b)). Subsequently, the connecting member 5423 moves inward in the left-right direction, and the upper end of the protruding portion 5423f is gradually moved upward, so that the free end side of the leaf spring member 5425 (the right end side in FIG. 56B). The edge gradually moves upward.

  When the projecting portion 5423f and the first inclined surface 5425b1 of the curved portion 5425b of the leaf spring member 5425 are in contact with each other, the force F51 applied to the leaf spring member 5425 from the projecting portion 5423f is applied to the first inclined surface 5425b1 of the curved portion 5425b. It propagates in the normal direction of. That is, the force F51 is directed to the thickness direction of the leaf spring member 5425, that is, the direction in which the leaf spring member 5425 is bent. In this case, of the force applied to the connecting member 5423 as a reaction of the force F51, the component directed to the left and right is small, so that when the slide shaft portion 423e of the connecting member 5423 moves to the right, the leaf spring member 5425 The hindrance of the movement of the connecting member 5423 is suppressed. Thus, while the main body member 410 (see FIG. 55) reaches the intermediate position, the insertion shaft portion 421c (see FIG. 55) is maintained at the lower end of the guide hole 413 (see FIG. 55). can do.

  When the slide shaft portion 423e of the connecting member 5423 reaches the inner end in the left-right direction of the guide hole 424b (the right end in FIG. 56 (c)) and rebounds, the projecting portion 5423f becomes the curved portion 5425b of the leaf spring member 5425. (See FIG. 56 (c)).

  In this case, the force F52 applied from the protruding portion 5423f to the leaf spring member 5425 is transmitted in the normal direction of the second inclined surface 5425b2 of the curved portion 5425b. That is, the force F52 has a large component directed in the longitudinal direction of the leaf spring member 5425, that is, in the longitudinal direction of the leaf spring member 5425.

  Here, the leaf spring easily undergoes elastic deformation in the thickness direction, but elastic deformation in the longitudinal direction of the leaf spring hardly occurs. In the present embodiment, the direction of the force F52 can be directed to the longitudinal direction of the leaf spring member 5425 by increasing the inclination angle of the right side surface of the curved portion 5425b to near a right angle to the left-right direction. Thus, the resistance of the leaf spring member 5425 to the rebound of the connecting member 5423 can be increased, and the movement of the connecting member 5423 can be prevented. Therefore, the connecting member 5423 can be maintained at the inner end (the right side in FIG. 56 (c)) of the guide hole 424b.

  Further, as described above, the protruding portion 5423f is formed such that the corner on the right side in the rear view (the right side in FIG. 56 (c)) is rounded and the corner on the left side in the rear view is formed at a right angle. Thereby, when the right corner of the protruding portion 5423f in rear view comes into contact with the leaf spring member 5425 (see FIG. 56 (b)), the protruding portion 5423f contacts smoothly (without biting) the left side of the protruding portion 5423f in rear view. When the corner comes into contact with the leaf spring member 5425 (see FIG. 56C), the projecting portion 5423f bites into the leaf spring member 5425. That is, the left-side corner of the protruding portion 5423f is fitted between the second inclined surface 5425b2 of the leaf spring member 5425 and the fall prevention portion 5425c.

  By moving the main body member 410 (see FIG. 55) upward by the driving device 460 (see FIG. 21), the slide shaft 423e is driven inside the guide hole 4424b in the left-right direction. In this case, the projecting portion 5423f moves by pushing the curved portion 5425b of the leaf spring member 5425.

  Next, a composite operation unit 6400 according to the sixth embodiment will be described with reference to FIGS. In the first embodiment, the case where the wiring guide arm 480 that guides the wiring is expanded and contracted by folding is described. However, the composite operation unit 6400 according to the sixth embodiment can expand and contract the wiring guide slide 6480 that guides the wiring by sliding movement. Formed. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 57 is a partial front view of the combined operation unit 6400 according to the sixth embodiment in a state where the main body member 410 is located at the extended position. In FIG. 57, the extended state of the wiring guide slide 6480 is illustrated. In the extended state of the wiring guide slide 6480, the wiring W provided inside the wiring guide slide 6480 has almost no bent portions and is formed substantially linearly. Therefore, the required length of the wiring W can be suppressed.

  The wiring guide slide 6480 is pivotally supported about a shaft support 472 and supported by a first guide slide 6481 through which the wiring W is inserted, and a sliding elongated hole 6481b of the first guide slide 6481 in the extending direction. A second guide slide 6482 that slides along and has a wire W inserted therein, and a third guide that slides along the extending direction of the elongated slide hole 6482b of the second guide slide 6482 and has the wire W inserted therein. And a slide 6483.

  The first guide slide 6481 has a rectangular cylindrical main body 6481a in which a substantially rectangular through hole 6481a1 is formed in the longitudinal direction, and a pair of side surfaces (front and rear) which are opposed to each other among the side surfaces of the main body 6481a. And a pair of slide long holes 6481b formed in the longitudinal direction of the main body 6481a, and a shaft support 472 penetrated in the front-rear direction at the end of the main body 6481a. It mainly includes a shaft support hole 6481c, and a cylindrical column portion 6481d that is bridged in the front-rear direction at the lower end of the through hole 6481a1 of the main body portion 6481a.

  The extending direction of the slide elongated hole 6481b and the lower side surface (the left side surface in FIG. 57) of the main body 6481a are formed in parallel. The wiring W is wound around the cylindrical portion 6481d from below.

  The second guide slide 6482 has a rectangular cylindrical main body 6482a in which a substantially rectangular through hole 6482a1 is formed in a slidable manner inside the through hole 6481a1 of the first guide slide 6481, and the main body 6482a. A pair of sliding long holes 6482b formed facing the pair of side surfaces (side surfaces arranged front and rear) facing each other among the side surfaces of the main body portion 6482a, and a main body portion 6482a And a pair of projecting portions 6482c that are projected outward from the front and rear side surfaces of the first guide slide 6481 and inserted into the elongated slide holes 6481b of the first guide slide 6481.

  The extending direction of the slide elongated hole 6482b and the lower side surface (the left side surface in FIG. 57) of the main body 6482a are formed in parallel. The protruding portion 6482c is formed in a cylindrical shape having a diameter slightly smaller than the width of the slide elongated hole 6481b.

  The second guide slide 6482 has a protruding portion 6482c formed so as to be slidable inside the elongated slide hole 6481b of the first guide slide 6481. During the movement, the outer surface of the second guide slide 6482 is connected to the main body 6481a. Of the through hole 6481a1. That is, the distance from the central axis of the slide elongated hole 6481b of the first guide slide 6481 to the inner surface of the lower side surface (the left side surface in FIG. 57) of the main body 6481a is equal to the distance from the central axis of the projecting portion 6482c to the main body portion 6482a. It is formed substantially equal to the distance from the lower side surface to the outer side surface. Accordingly, when the second guide slide 6482 is slid with respect to the first guide slide 6481, the posture of the second guide slide 6482 can be stabilized.

  The third guide slide 6483 is fitted inside the through hole 6482a1 of the second guide slide 6482 so as to be slidable and has a substantially rectangular through hole 6483a1 formed in the longitudinal direction. And a pair of projecting portions 6483b projecting outward from the front and rear side surfaces of the portion 6483a and inserted through the elongated slide hole 6482b of the second guide slide 6482.

  The third guide slide 6483 has a projecting portion 6483b formed so as to be slidable inside the elongated slide hole 6482b of the second guide slide 6482. During the movement, the outer surface of the third guide slide 6483 is connected to the main body 6482a. Of the through hole 6482a1. That is, the distance from the central axis of the slide elongated hole 6482b of the second guide slide 6482 to the inner surface of the lower side surface (the side surface on the left side in FIG. 57) of the main body portion 6482a is equal to the distance from the central axis of the protruding portion 6483b to the main body portion 6483a. It is formed substantially equal to the distance from the lower side surface to the outer side surface. Accordingly, when the third guide slide 6483 is slid with respect to the second guide slide 6482, the posture of the third guide slide 6482 can be stabilized.

  Here, while the inner surface of the first guide slide 6481 and the outer surface of the second guide slide 6482 are formed as smooth surfaces, the inner surface of the second guide slide 6482 and the outer surface of the third guide slide 6483 are different from each other. It is formed with a rough surface. In this case, the frictional resistance of the sliding movement of the second guide slide 6482 with respect to the first guide slide 6481 is formed smaller than the frictional resistance of the sliding movement of the third guide slide 6483 with respect to the second guide slide 6482.

  As a result, the second guide slide 6482 slides prior to the third guide slide 6483. That is, when the main body member 410 moves upward from the state of FIG. 57, the second guide slide 6482 is first stored in the first guide slide 6481, and after the storage is completed, the second guide slide 6482 is moved in the third guide slide 6482. 6483 are stored.

  FIGS. 58A and 58B are partial front views of the composite operation unit 6400. FIG. 58A illustrates a state where the main body member 410 is disposed at the intermediate position (see FIG. 30), and FIG. 58B illustrates a state where the main body member 410 is disposed at the retracted position. You.

  As shown in FIG. 58, the wiring guide slide 6480 does not include a portion where the wiring W may be pinched, so that the wiring W can be prevented from being disconnected. Further, since there is no possibility of sandwiching the wiring W, the arrangement interval between the wiring W and the inner surface of each guide slide 6481, 6482, 6483 can be reduced. Thereby, the width of the wiring guide slide 6480 in the short direction can be suppressed.

  In a state where the main body member 410 is arranged at the intermediate position, the wiring W remains inside the wiring guide slide 6480 (see FIG. 58A). Therefore, it is possible to temporarily remove the tension applied to the wiring W.

  Next, a swing operation unit 7500 according to a seventh embodiment will be described with reference to FIG. In the first embodiment, the case where the pair of bridging members 528 is fixed to the drive-side arm member 520 has been described. However, the swing operation unit 7500 according to the seventh embodiment includes the first bridge of the pair of bridging members 7528. The bridging member 7528a is formed to be swingable with respect to the driving arm member 7520. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIGS. 59A and 59B are partial front views of the swing operation unit 7500 in the seventh embodiment. Note that FIG. 59 (a) illustrates a state where the moving member 540 is arranged at the retracted position, and FIG. 59 (b) illustrates a state where the moving member 540 is arranged at the extended position. Is illustrated by imaginary lines.

  As shown in FIG. 59 (a), the first bridging member 7528a, which is the smaller side of the pair of bridging members 7528, is inserted into a shaft support hole 7529 formed in the main body plate portion 7521 of the driving arm member 7520. It is pivotally supported and is urged clockwise in a front view by a torsion spring (not shown). Note that the main body plate portion 521 is different from the main body plate portion 521 in the first embodiment except that the formation of the first fastening holes 527a1 corresponding to the first bridging members 7528a is omitted and a shaft support hole 7529 is formed instead. It is formed similarly. The second bridging member 7528b, which is the larger side of the pair of bridging members 7528, is fastened and fixed to the main body plate portion 7521 of the driving arm member 7520.

  The driven arm member 7530 has a projecting portion 7534 projecting from the front side of the main body plate portion 531 and abutting on the first bridging member 7528a in the swing direction.

  Here, when the driving side arm member 7520 and the driven side arm member 7530 are disposed at the retracted position and at the extended position, the relative position of the projecting portion 7534 with respect to the shaft support hole 7529 is determined. The position changes (the position changes similarly to the relative movement of the other-side shaft support hole 526 and the other-side shaft support hole 533 along the longitudinal direction of the drive-side arm member 7520).

  By swinging the first bridging member 7528a along the projecting portion 7534, the distance between the first bridging member 7528a and the second bridging member 7528b at the extended position (see FIG. 59B) is increased. Can be spread. Accordingly, when the driven-side arm member 7530 bends to the front side, the distance between the positions where the bridge member 7528 can abut (the end of the first bridge member 7528a and the end of the second bridge member 7528b). Can be expanded. In this case, the length in the longitudinal direction in which the driven side arm member 7530 can flex freely without being in contact with the bridging member 7528 can be divided into shorter portions, and the amount of bending of the driven side arm member 7530 (in the longitudinal direction) Movement amount) can be suppressed.

  As shown in FIG. 59, the distance between the first bridging member 7528a and the other-side shaft support hole 533 can be maintained regardless of whether the moving member 540 is located at the retracted position or the extended position. it can. Here, the displacement of the driven-side arm member 7530 with respect to the drive-side arm member 7520 is likely to occur in the other-side shaft support hole 533 which is the connection position with the moving member 540, and the displacement width is likely to be large. In the present embodiment, the first bridge member 7528a can be prevented from separating from the other-side shaft support hole 533, and the effect of suppressing the displacement of the driven arm member 7530 with respect to the drive arm member 7520 can be increased. Can be.

  When the drive-side arm member 7520 and the driven-side arm member 7530 are disposed at the retracted position (see FIG. 59A), the first bridge member 7528a is biased by a torsion spring (not shown). It swings in the direction approaching the second bridge member 7528b. As a result, the drive-side arm member 7520 is moved to the retracted position while the distance between the first bridge member 7528a and the second bridge member 7528b is increased, and the first bridge member 7528a and the other-side shaft support hole 533 are moved. Can be prevented from interfering with each other.

  Next, a game board 8013 according to the eighth embodiment will be described with reference to FIGS. In the first embodiment, the case where light is irradiated from the light irradiation device 331c to the specific winning opening 65a has been described. However, the game board 8013 according to the eighth embodiment has an outer rail formed by being planted on the base plate 8060. Light is radiated to the vicinity of the upper half of 62. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 60 is a front view of a game board 8013 according to the eighth embodiment. As shown in FIG. 60, since the light irradiation device 8610 is disposed outside the outer rail 62, the degree of freedom of decoration of the game area is reduced by a shielding member for partially hiding the light irradiation device 8610. Can be prevented. In addition, since the light irradiation device 8610 is provided in the embedding hole 8013a formed in the game board 8013, it is possible to prevent the light irradiation device 8610 from increasing the thickness of the game board 8013 in the front-rear direction.

  The light irradiating device 8610 irradiates light inside the game area through the back side of the outer rail 62. A mechanism for changing the traveling direction of the irradiated light to the front side (the front side in FIG. 60) will be described with reference to FIG.

  FIG. 61 is a partial sectional view of the game board 8013 taken along the line LXI-LXI in FIG. As shown in FIG. 61, the light irradiation device 8610 mainly includes a main body 8611 fixed to the embedding hole 8013a, and a light irradiation unit 8612 disposed on a side surface of the main body 8611.

  The game board 8013 is formed of a light-transmissive resin material, and has a buried hole 8013a in which the light irradiation device 8610 is provided, and a lower portion (from the buried hole 8013a along the back surface of the game board 8013 and beyond the outer rail 62). A light projecting passage 8013b, which is a concave portion extending to the inside of the game area, and a mode formed at an extended end of the light projecting path 8013b, the closer to the front side as it goes downward (inward of the game area). And a direction change portion 8013c formed in an inclined manner.

  The embedding hole 8013a, the light projecting passage 8013b, and the direction changing portion 8013c can be formed by processing such as cutting and drilling, or by forming a protrusion having an appropriate shape in a resin mold.

  The path E81 of the light emitted from the light irradiating section 8612 is formed inside the light projecting path 8013b, reaches the direction changing section 8013c and is reflected, so that the traveling direction of the light is from the path E81 to the front side (FIG. 61). The route changes to the route E82 (to the left). Here, since the direction change portion 8013c for changing the traveling direction of light is formed by the game board 8013 formed of a light-transmissive resin material, the direction change portion 8013c is inconspicuous and may have a small effect on the decoration of the game area. it can. Thus, the degree of freedom in designing the game area can be improved.

  As shown in FIG. 61, the light traveling on the route E82 is applied from below to a nail implanted in front of the game board 8013. Thereby, the shadow formed below the nail by the illumination of the hall can be brightened. Therefore, it is possible to improve the performance ability in the area below the nail, and to make it easier to see the ball when the ball passes through the area below the nail, thereby reducing the burden felt by the player due to the difficulty in viewing the ball. be able to.

  In particular, the nails implanted on the upper part of the game board 8013 are arranged at positions where the nails are looked up from the player, so that light is radiated from below the nails to direct the light reflected by the nails to the player. be able to. In this way, the nail that defines the flow path of the sphere can be used as a member for producing light.

  The lower part (lower half) of the nail is less likely to collide with the ball, so that even if it is processed, the influence on the flow of the ball is small. For example, by processing the lower part (lower half) of the nail in a crystal shape, light can be reflected in a plurality of directions, and the performance of the nail can be enhanced.

  Further, by setting the color of the light emitted from the light irradiating unit 8612 to a color (for example, red) different from the color of the nail (for example, yellow), it is possible to distinguish between the nail that has been irradiated and other nails. Can be made easier.

  In this case, for example, a plurality of light irradiation devices 8610 (six in this embodiment, see FIG. 60) may be arranged on the game board 8013, and light may be irradiated in order. That is, after the light is irradiated from the light irradiation device 8610 at the left end in front view, the light is irradiated from the light irradiation device 8610 on the right (the second from the left end in front view), and then the light is irradiated on the right (front) Light may be emitted from the light irradiation device 8610 (third from the left end when viewed), and may continue thereafter.

  According to this, the nails implanted in the game board 8013 glow in order along the curved arrow R81 by the light emitted from the light irradiation device 8610. For example, in a case where it is more advantageous for the player to perform right-handing, the nails implanted in the game board 8013 are sequentially illuminated along the curved arrow R81 so that the player performs right-handing. Can be signaled. Thereby, the nail that forms the flow path of the ball is given an effect of telling the player where to hit the ball, so that the attention power of the nail can be improved.

  Note that the light irradiated from the light irradiation device 8610 is not necessarily limited to the nail. For example, light may be applied to a windmill provided on the game board 8613, the through gate 67 (see FIG. 60), or the like.

  Next, a wiring guide arm 9480 in the ninth embodiment will be described with reference to FIGS. In the first embodiment, the case where the first guide arm 481 and the second guide arm 482 of the wiring guide arm 480 do not overlap in the front-rear direction except for the pivot portion, but the wiring guide arm 9480 in the ninth embodiment is different from the first embodiment. The second front arm 9482f disposed on the second guide arm 9482 overlaps the first guide arm 9481 in the front-rear direction. The same parts as those in the above-described embodiments are denoted by the same reference numerals, and description thereof will be omitted. 62 to 64, illustration of the enlarged diameter portion 481c1 and the reduced diameter portion 482b1 is omitted for easy understanding.

  FIG. 62 (a) is a front view of the first guide arm 9481 in the ninth embodiment, FIG. 62 (b) is a bottom view of the first guide arm 9481, and FIG. It is a perspective view of locking member 9481f. In FIG. 62A, the detachable front locking member 9481f is partially viewed in cross section, and the fitting portion between the attachment portion 9481d and the removable front locking member 9481f can be visually recognized.

  As shown in FIG. 62 (a), the first guide arm 9481 includes a detachable front locking member 9481f formed so as to be detachable from the attachment portion 9481d, and a plate-like arm portion 9481a from both ends of the linear portion of the attachment portion 9481d. It mainly includes a plate-shaped non-slip plate portion 9481g extending toward the rear side and an other-side auxiliary bottom portion 9481h extending from the back side of the other-side bottom portion 481e2.

  The notch 481a1 (see FIG. 25A) of the plate-shaped arm 9481a is omitted. In the present embodiment, since the detachable front locking member 9481f is molded separately from the attachment portion 9481d as described later, the notch portion 481a1 is unnecessary. Thereby, the strength of the plate-shaped arm portion 9481a can be secured.

  As shown in FIG. 62A, the attachment portion 9481d includes a fitting recess 9481d1 which is a semicircular recess extending in the front-rear direction.

  The fitting dent 9481d1 is a semicircular dent into which a cylindrical fitting arm 9481f2 of a detachable front locking member 9481f described later is fitted, and has a short side direction of the attachment part 9481d (FIG. 62 (a) perpendicular to the sheet surface). Direction). Thus, a shape for the fitting recess 9481d1 is added to the molding die of the fitting portion 9481d, and the fitting portion 9481d1 is pulled out in one direction (the direction perpendicular to the paper surface of FIG. 62A), whereby the fitting recess 9481d1 is formed. 9481d can be easily manufactured.

  The fitting recess 9481d1 is formed in a semicircular shape having a radius equal to or slightly smaller than the radius of the fitting arm 9481f2. Thereby, the fitting arm portion 9481f2 can be fitted into the fitting recess 9481d1, and the sliding movement of the detachable front locking member 9481f in the longitudinal direction of the attachment portion 9481d can be suppressed.

  In this case, the contact area with respect to the thickness of the fitting arm 9481f2 can be increased as compared with the case where the attachment portion 9481d and the fitting arm 9481f2 abut on each other, and the frictional force can be increased. Can be. Accordingly, it is possible to prevent the detachable front locking member 9481f from dropping off from the attachment portion 9481d.

  As shown in FIG. 62 (c), the detachable front locking member 9481f includes a long plate-shaped main body plate 9481f1 and a plurality of columns extending vertically from the side in the thickness direction of the main body plate 9481f1. And a fitting arm 9481f2.

  Since the detachable front locking member 9481f can be detached from the attachment portion 9481d, when the wiring W is replaced, for example, when the wiring W is disconnected, the detachable front locking member 9481f is detached to allow the detachable front locking. The trouble of replacing the wiring W while avoiding the member 9481f can be omitted, and the replacement of the wiring W can be facilitated.

  The plurality of fitting arms 9481f2 are portions for fixing the detachable front locking member 9481f to the attachment portion 9481d by sandwiching the attachment portion 9481d, and are juxtaposed at intervals slightly shorter than the plate thickness of the attachment portion 9481d. A pair of bar-shaped members are continuously provided in two sets. When the detachable front locking member 9481f is fixed to the attachment portion 9481d, the pair of rod-shaped members of the plurality of fitting arms 9481f2 are elastically deformed by being pushed from the attachment portion 9481d, and the attachment portion is elastically restored by the elastic recovery force. 9481d.

  Note that the length of the fitting arm 9481f2 is formed slightly longer than the length of the attachment portion 9481f in the width direction, and the tip of the fitting arm 9481f2 is directed toward the mating arm 9481f2 of the mating side that sandwiches the attachment 9481f. A protruding portion 9481f3 is formed. Since the projecting portion 9481f3 is hooked on the attachment portion 9481f, it is possible to prevent the detachable front locking member 9481f from coming off the attachment portion 9481f to the front side (the front side in FIG. 62A).

  In this case, since the fitting arm 9481f2 is formed in a columnar shape and the fitting recess 9481d1 is formed as a recess having a semicircular cross section, when the fitting arm 9481f2 holds the attachment portion 9481d with elastic recovery force. The axial center of the fitting arm 9481f2 is moved to the center of the fitting recess 9481d1. This facilitates positioning when the detachable front locking member 9481f is attached to the attachment portion 9481d, and shortens the time required for attachment.

  The non-slip plate portion 9481g is a portion for holding the wiring W between the plate-like arm portion 481a and is formed continuously over the width direction of the attachment portion 9481d (the vertical direction in FIG. 62B). The attachment portion 9481d and the plate-shaped arm portion 481a can be elastically deformed in the thickness direction. The gap between the tip end of the anti-slip plate portion 9481g and the plate-shaped arm portion 481a is usually formed so as to have a thickness equal to or less than the thickness of the wiring W, and the anti-slip plate portion 9481g is inserted by inserting the wiring W therethrough. The wire W is elastically deformed, and the elastic recovery force suppresses the wiring W from sliding with respect to the plate-shaped arm portion 481a.

  The direction of the non-slip plate portion 9481g is elastically deformable along the longitudinal direction of the attachment portion 9481d. Thereby, the wiring W can be sandwiched between the non-slip plate portion 9481d and the plate-shaped arm portion 481a in the width direction, and the wiring W can be suppressed from moving and rubbing in the longitudinal direction of the attachment portion 9481d. The durability of the wiring W can be improved.

  The directions of the pair of non-slip plate portions 9481g are opposite to each other at both ends of the attachment portion 9481d. Thereby, regardless of the moving direction of the wiring W, it is possible to suppress the attachment portion 9481d and the wiring W from moving in the longitudinal direction of the attachment portion 9481d. The non-slip plate portion 9481g is arranged to face the rib portion N. Accordingly, the wiring W can be suppressed not at the tip end of the anti-slip plate portion 9481g but at the middle part (antinode), so that the resistance applied to the wiring W can be increased (see FIG. 64).

  The other-side auxiliary bottom portion 9481h is a plate-shaped portion having the same outer peripheral shape as the other-side bottom portion 481e2. The other-side auxiliary bottom portion 481c2 extends in the circumferential direction of the other-side cylindrical portion 481c from the back surface of the other-side bottom portion 481e2. And about 120 degrees, and has an inclined side surface 9481h1 at the extension end. As shown in FIG. 64 (a), the extending distal end of the other-side auxiliary bottom 9481h and the end of the one-side bottom 482e1 of the second guide arm 9482 overlap in a front view. Accordingly, it is possible to prevent the wiring W from dropping to the back side (the back side in FIG. 64A).

  The inclined side surface 9481h1 is inclined to the rear side (downward in FIG. 62 (b)) as the distance from the other side bottom portion 481e2 increases.

  FIG. 63 (a) is a front view of the second guide arm 9482, FIG. 63 (b) is a bottom view of the second guide arm 9482, and FIG. 63 (c) is LXIIIc of FIG. 63 (a). It is sectional drawing of the 2nd guide arm 9482 in the -LXIIIc line.

  As shown in FIG. 63 (a), the second guide arm 9482 includes a projecting front locking portion 9482f extending from the front end of the attachment portion 482d in both directions in the thickness direction of the attachment portion 482d, and an attachment portion. 482d and a non-slip plate portion 9482g extending from the end of the linear portion of the plate-shaped arm portion 482a to the plate-shaped arm portion 482a and the attachment portion 482d that are arranged to face each other.

  The overhanging front locking portion 9482f is attached to the extension end portion extending on the opposite side of the plate-like arm portion 482a with the attachment portion 482d interposed therebetween, and the rear side (FIG. 63) as the extension tip approaches the attachment portion 482. (C) An inclined side surface 9482f1 inclined to the right side is provided.

  Since the technical idea of the anti-slip plate portion 9482g is the same as the technical idea of the anti-slip plate portion 9481g, the description is omitted here.

  FIGS. 64 (a) and 64 (b) are front views of the first guide arm 9481 and the second guide arm 9482 of the wiring guide arm 9480, and FIG. 64 (c) is the LXIVc- of FIG. 64 (a). It is sectional drawing of the 1st guide arm 9481 and the 2nd guide arm 9482 of the wiring guide arm 9480 in the LXIVc line. FIG. 64A illustrates a state where the first guide arm 9481 and the second guide arm 9482 are folded, and FIG. 64B illustrates a state where the first guide arm 9481 and the second guide arm 9482 are pivoted and opened. The state where it was put is illustrated. 64 (a) and 64 (b) show the wiring W, and FIG. 64 (c) does not show the wiring W.

  Here, in order to secure an arrangement area for other movable members, it is desirable to suppress the arrangement area of the wiring guide arm 9480. Therefore, it is difficult to provide a margin in a region for accommodating the wiring W (for example, between the plate-shaped arm portion 481a and the attachment portion 9481d of the first guide arm 9481). In this case, when the wiring guide arm 9480 is folded or opened, each time the state changes, the wiring W rubs against the inner side surface of the wiring guide arm 9480, and the wiring W deteriorates early, and the durability of the wiring W decreases. May drop.

  On the other hand, in the wiring guide arm 9480 according to the present embodiment, the wiring W is sandwiched between the non-slip plates 9481g and 9482g and the plate-shaped arms 481a and 482a, so that the wiring W is connected to the plate-shaped arms 481a. , 482a and attachment portions 9481d, 482d. Thereby, the durability of the wiring W can be ensured.

  Further, when the second guide arm 9482 is deformed in a twisted manner with respect to the first guide arm 9481, the wiring W may be twisted, and the durability of the wiring W may be reduced.

  On the other hand, in the wiring guide arm 9480 according to the present embodiment, when the first guide arm 9481 and the second guide arm 9482 are opened (see FIG. 64B), the other side auxiliary bottom portion 9481h is connected to the second guide arm. 9482 overlaps with one side bottom portion 482e1 in the front-rear direction. Here, the other-side auxiliary bottom portion 9481h extends in the circumferential direction of the other-side cylindrical portion 481c along the back surface of the other-side bottom portion 481e2 (see FIG. 62B).

  Therefore, in a state where the first guide arm 9481 and the second guide arm 9482 are opened (see FIG. 64B), the other side auxiliary bottom portion 9481h and the one side bottom portion 482e1 are in a positional relationship in which they can abut in the front-rear direction. It is formed. That is, when the second guide arm 9482 is twisted and deformed against the first guide arm 9481 in a direction of pressing the one bottom 482e1 against the other auxiliary bottom 9481h, the one bottom 482e1 and the other auxiliary bottom 9481h are abutted. In addition, the deformation resistance of the torsional deformation increases. In this case, the first guide arm 9481 and the second guide arm 9482 can be suppressed from being twisted. Therefore, the wire W can be prevented from being twisted and deformed, and the durability of the wire W can be ensured.

  In the present embodiment, in a state where the first guide arm 9481 and the second guide arm 9482 are folded (see FIG. 64 (a)), the overhanging front locking portion 9482f moves forward and backward with the attachment portion 9481d of the first guide arm 9481. It overlaps in the direction and is formed in a positional relationship capable of abutting in the front-rear direction (see FIG. 64C). That is, when the second guide arm 9482 is twisted and deformed with respect to the first guide arm 9481 in a direction of pressing the overhanging front locking portion 9482f against the attachment portion 9481d, the overhanging front engagement portion 9482f and the attachment portion 9481d come into contact with each other. And the deformation resistance of the torsional deformation increases. In this case, the first guide arm 9481 and the second guide arm 9482 can be suppressed from being twisted. Therefore, the wire W can be prevented from being twisted and deformed, and the durability of the wire W can be ensured.

  When the other auxiliary bottom portion 9481h is further extended in the circumferential direction from the present embodiment, the second guide arm 9481 and the second guide arm 9482 are folded in the second state (see FIG. 64A). The guide arm 9482 and the other side auxiliary bottom part 9481h are in contact, and the first guide arm 9481 and the overhanging front locking part 9482f are in contact.

  In this case, the rear side of the second guide arm 9482 and the other side auxiliary bottom portion 9481h are in contact with each other, so that the front side of the second guide arm 9482 can be prevented from falling down. On the other hand, since the front side of the first guide arm 9481 is in contact with the overhanging front locking portion 9482f, it is possible to prevent the rear side of the second guide arm 9482 from falling down. Therefore, in a state where the first guide arm 9481 and the second guide arm 9482 are folded (see FIG. 64A), the second guide arm 9482 is twisted relative to the first guide arm 9481 regardless of the direction. Can be suppressed.

  The same effect can be obtained by adding the overhanging front locking portion 9482f to the rear side of the second guide arm 9482. Since the guide arm 9482 is sandwiched between the first and second guide arms 9481 and 9482, the positioning accuracy of the first and second guide arms 9481 and 9482 needs to be increased.

  On the other hand, in the present embodiment, since the portion for suppressing the twist of the second guide arm 9482 is formed so as to be shifted in the longitudinal direction of the second guide arm 9482, the alignment of the first guide arm 9481 and the second guide arm 9482 is performed. The degree required for the precision of the image can be reduced.

  In the present embodiment, the first guide arm 9481 and the second guide arm 9482 are opened (see FIG. 64A), and the first guide arm 9481 and the second guide arm 9482 are opened (FIG. 64). Before reaching (b), there is a possibility that the extended distal end of the other-side auxiliary bottom portion 9481h may come into contact with the end surface of the one-side bottom portion 482e1 of the second guide arm 9482.

  On the other hand, the inclined side surface 9481h1 (see FIG. 62 (a)) is formed at the extension end of the other side auxiliary bottom portion 9481h, so that the extension end of the other side auxiliary bottom portion 9481h comes into contact with the end surface of the one side bottom portion 482e1. Even in the case of contact, the other-side auxiliary bottom portion 9481h can ride on the back side of the one-side bottom portion 482e1 (the back side in FIG. 64B). This makes it easy to form the first guide arm 9481 and the second guide arm 9482 in an open state (see FIG. 64A).

  In addition, the first guide arm 9481 and the second guide arm 9482 are folded from the state where the first guide arm 9481 and the second guide arm 9482 are opened (see FIG. 64B) (FIG. 64A). (See Reference), there is a possibility that the extended distal end of the overhanging front locking portion 9482f may come into contact with the side surface of the attachment portion 9481d.

  On the other hand, since the inclined side surface 9482f1 (see FIG. 63 (c)) is formed at the extending end of the overhanging front locking portion 9482f, the extending end of the overhanging front locking portion 9482f is attached to the attachment portion 9481d. Even in the case of contact with the side surface, the overhanging front locking portion 9482f can be made to ride on the front side of the attachment portion 9481d (the front side of the drawing in FIG. 64A) (see FIG. 64C). This makes it easy to form the first guide arm 9481 and the second guide arm 9482 in a folded state (see FIG. 64A).

  In the present embodiment, the case where the projecting front locking portion 9482f that abuts on the attachment portion 9481d is formed on the front side is described, but the present invention is not necessarily limited to this. For example, the overhanging front locking portion 9482f may be formed as a pair of a front side and a back side. Thus, regardless of the direction of the torsional deformation of the second guide arm 9482, the overhanging front locking portion 9482f can be brought into contact with the attachment portion 9481d, and the first guide arm 9481 and the second guide arm 9482 are twisted and deformed. Can be suppressed.

  As described above, the present invention has been described based on the above embodiments. However, the present invention is not limited to the above embodiments, and various modifications and improvements can be easily made without departing from the gist of the present invention. It can be inferred.

  In each of the above embodiments, some or all of the configuration in one embodiment may be combined with or replaced by part or all of the configuration in another embodiment to form another embodiment.

  In each of the above embodiments, the case where the gap is formed by the pair of decorative members 422 of the combined operation unit 400 swinging has been described, but the present invention is not necessarily limited to this. For example, the decoration member 422 may be guided to be slidable in the left-right direction, and the pair of decoration members 422 may be slid in the direction away from each other to form a gap for accommodating the swing member 430. In this case, the width of the gap formed between the pair of decorative members 422 can be secured in the vertical direction.

  In the above embodiments, the case where the movable upper cover member 332 of the lower panel unit 300 slides in the front-rear direction has been described, but the present invention is not necessarily limited to this. For example, a pair of left and right long plate-shaped movable members are pivotally supported on the inner side surfaces of the pair of step portions 324a, and the movable members are in the direction in which the pair of step portions 324a are continuously provided. In a closed state in which the ball is positioned along the longitudinal direction to prevent passage of the ball to the specific winning opening 65a, and an opening that swings upward or downward from that state to allow the ball to pass to the specific winning opening 65a. And the state may be formed. Further, the second winning port 640 may be configured instead of the specific winning port 65a with the same configuration.

  In each of the above embodiments, the case where the light irradiated from the light irradiation device 331c is reflected to the front side when the movable upper cover member 332 of the lower panel unit 300 is in the retracted state has been described, but it is not necessarily limited to this. Not something. For example, a portion that reflects the light emitted from the light irradiation device 331c to the front side when the movable upper lid member 332 is in the extended state may be formed below the movable upper lid member 332. In this case, the light reflected by the movable upper lid member 332 is not blocked by the sphere, and the light effect can be improved.

  In each of the above-described embodiments, the case where the positioning unit 543 is combined with the moving member 540 of the swing operation unit 500 by the concave-convex fitting has been described, but the present invention is not necessarily limited to this. For example, a magnet may be provided at a position where a pair of moving members 540 are arranged close to each other, and the moving members 540 may be united by magnetic force. In this case, the moving members 540 can be attracted to each other by the magnetic force, and it becomes unnecessary for the driving device 550 to generate a holding force when the moving members 540 are arranged at the extended position. Therefore, power consumption of the driving device 550 can be suppressed.

  In each of the above embodiments, the case where the guide hole 413 of the combined operation unit 400 is formed in a straight line has been described, but the present invention is not necessarily limited to this. For example, the guide hole 413 may be formed in a curved shape. In this case, even if the moving speed of the main body member 410 is the same, the swing speed of the shielding member 420 can be made slower or faster.

  In the above embodiments, the case where the main body member 431 of the swing member 430 of the combined operation unit 400 swings has been described, but the present invention is not necessarily limited to this. For example, the swing member 430 may include a slide member that slides in a direction away from the main body member 410, and the decoration member 422 may be accommodated between the slide member and the main body member 410.

  In each of the above embodiments, the case where the respective guide arms of the wiring guide arms 480 of the combined operation unit 400 are vertically stacked has been described, but the present invention is not necessarily limited to this. For example, each guide arm of the wiring guide arm 480 may be stacked in the front-rear direction. In this case, since the vertical width of the wiring guide arm 480 can be reduced, the width of the bottom wall portion 211 necessary for housing the wiring guide arm 480 outside the opening 211a can be reduced. Thereby, the arrangement area of the third symbol display device 81 can be increased.

  In each of the above embodiments, the case where the moving member 540 is supported by the pair of arm members of the drive side arm members 520, 2520, 3520, 7520 and the driven side arm members 530, 7530 has been described, but is not necessarily limited to this. is not. For example, the moving member 540 may be supported by three or more arm members. In this case, for example, the bridge members 528, 2528, and 7528 are fastened and fixed to the intermediate arm members, and are disposed so as to cover the front sides of the arm members at both ends, thereby suppressing the positional deviation between the arm members. Can be improved. That is, when one of the arm members at both ends pushes one end of the bridging members 528, 2528, 7528, and the bridging members 528, 2528, 7528 bend, the other end becomes the other end. It moves toward the arm member and is supported by the other arm member. As described above, the arm members at both ends act to suppress the bending of the bridging members 528, 2528, and 7528. As a result, displacement of the plurality of arm members can be suppressed, and the posture of the moving member 540 can be stabilized. Can be done.

  In the first to fifth embodiments and the seventh embodiment described above, each of the guide arms 481 to 483 of the wiring guide arm 480 includes a columnar portion (for example, one side support portion 482b) and a cylindrical portion ( For example, although the case where it is pivotally supported by the other cylindrical portion 481c) has been described, it is not necessarily limited to this. For example, the portion supporting the columnar portion may be formed by an elongated hole extending in the longitudinal direction of each of the guide arms 481 to 483. In this case, in addition to expansion and contraction in the vertical direction in which the guide arms 481 to 483 are bent, expansion and contraction in the horizontal direction in which the guide arms 481 to 483 slide in the extending direction of the elongated hole can be performed.

  In the first to fifth embodiments and the seventh embodiment, the lower side surface (for example, the plate-shaped arm portion 481a) of each arm member (for example, the first guide arm 481) constituting the wiring guide arm 480. Has described the case where the width is shorter than the upper side surface (for example, the attachment portion 9481d), but the present invention is not necessarily limited to this. For example, the lower side surface (for example, the plate-shaped arm portion 481a) of each arm member (for example, the first guide arm 481) may be wider than the upper side surface (for example, the attachment portion 9481d). In this case, it is possible to suppress the wiring W from slipping down from the lower side surface (for example, the plate-shaped arm portion 481a) due to gravity.

  In the above-described first to fifth embodiments, the seventh embodiment and the ninth embodiment have described the case where the width of the wiring W is shorter than the attachment portions 481d and 9481d. However, the present invention is not necessarily limited to this. . For example, the formation of the front locking portion 481f may be omitted, and the width of the wiring W may be longer than the width of the plate-shaped arm portion 481a and the attachment portions 481d and 9481d. In this case, since a part of the wiring W protrudes from the plate-shaped arm portion 481a and the attachment portions 481d and 9481d, the protruding portion can be pinched (fingered by a finger) to easily take out the wiring W. Thereby, maintenance of the wiring W can be easily performed.

  In the above-described first to fifth embodiments, the seventh embodiment and the ninth embodiment have described the case where the widths of the attachment portions 481d and 9481d are constant. However, the present invention is not necessarily limited to this. For example, portions of the attachment portions 481d and 9481d other than the portion where the front locking portion 481f is fixed may be formed with the same width as the plate-shaped arm portion 481a. In this case, by making the width of the wiring W longer than the plate-shaped arm portion 481a, a part of the wiring W can protrude from the plate-shaped arm portion 481a and the attachment portions 481d and 9481d. Therefore, the protruding portion can be picked up with a finger (and hooked with a finger) to easily take out the wiring W. Thereby, maintenance of the wiring W can be easily performed.

  In the fourth embodiment, the case where the concave portion 4424c is formed on the upper side surface of the guide hole 4424b has been described, but the present invention is not necessarily limited to this. For example, the thickness of the upper surface of the guide hole 4424b may be thicker than the thickness of the lower surface. In this case, the friction generated between the upper surface of the guide hole 4424b and the connecting member 423 can be larger than the friction generated between the lower surface of the guide hole 4424b and the connecting member 423. The rebound of the connecting member 423 that occurs when the connecting member 423 is moved can be suppressed.

  In the fourth embodiment, the case where the concave portion 4424c is formed on the upper side surface of the guide hole 4424b has been described, but the present invention is not necessarily limited to this. For example, a recess capable of accommodating the slide shaft portion 423e may be formed on the upper side surface of the lower end portion of the guide hole 413 of the main body member 410. In this case, when the insertion shaft 421c is disposed at the lower end of the guide hole 413, the resistance F applied to the insertion shaft 421c from the side surface of the guide hole 413 can be increased.

  In the above-described eighth embodiment, the case where the direction changing portion 8013c is provided only at the extending end of the light projecting passage 8013b has been described, but the present invention is not necessarily limited to this. For example, a direction changing portion 8013c may be additionally provided in the middle of the light projecting passage 8013b. In this case, the light reflected to the front side from the direction changing portion 8013c disposed in the middle of the light projecting passage 8013b and the light reflected through the direction changing portion 8013c and disposed at the extending end of the light projecting passage 8013b. The light can be divided into light reflected from the direction changing unit 8013c and light reflected frontward. That is, since the light emitted from the light irradiation device 8610 can be divided into a plurality of light components, the number of light beams visible in a front view can be larger than the number of light irradiation device 8610. Thus, the number of light irradiation devices 8610 can be reduced while maintaining the effect of the light irradiation device 8610.

  The present invention may be implemented in a pachinko machine or the like of a type different from the above embodiments. For example, once a jackpot has been hit, a pachinko machine (commonly known as a twice-rights item or a three-times right item) can increase the jackpot expectation value until a jackpot state occurs a plurality of times (for example, two or three times). ). Further, after the big hit symbol is displayed, the game may be implemented as a pachinko machine that generates a special game for giving a predetermined game value to a player on condition that a ball is won in a predetermined area. Further, a prize winning device having a special area such as a V zone may be provided, and the pachinko machine may be put into a special game state on condition that a ball is awarded in the special area. Further, in addition to the pachinko machine, the present invention may be implemented as various game machines such as areaches, sparrow balls, slot machines, so-called game machines in which a so-called pachinko machine and a slot machine are combined.

  In the slot machine, for example, a symbol is changed by operating an operation lever in a state where a coin is inserted and a symbol valid line is determined, and the symbol is stopped and determined by operating a stop button. Things. Therefore, the basic concept of the slot machine is as follows: "a display device for variably displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information is provided. The variable display of the identification information is started, and the variable display of the identification information is stopped and confirmed and displayed due to the operation of the stop operation means (for example, a stop button) or after a predetermined time has elapsed. A slot machine that generates a special game that gives a predetermined game value to a player on the condition that the combination of the identification information at the time is a specific one, and in this case, coins, medals, etc. are representative of game media. As an example.

  Further, as a specific example of a gaming machine in which a pachinko machine and a slot machine are integrated, a display device for variably displaying a symbol row including a plurality of symbols and then displaying the symbols in a fixed manner is provided, and a handle for hitting a ball is provided. Not included. In this case, after throwing in a predetermined amount of balls based on a predetermined operation (button operation), for example, the fluctuation of the symbol is started due to the operation of the operation lever, for example, due to the operation of the stop button, or By the passage of time, the fluctuation of the symbol is stopped, and a special game that gives a predetermined game value to the player is generated on the condition that the confirmed symbol at the time of the stop is a so-called big hit symbol, and the player is given a special game. Is a method in which a large amount of balls are paid out to a lower saucer. If such a gaming machine is used in place of a slot machine, only balls can be treated as a game value in a game hall, and thus a game value seen in a current game hall where pachinko machines and slot machines are mixed. Problems such as the burden on equipment due to the separate handling of medals and balls and restrictions on the location of gaming machines can be solved.

<First control example>
Next, display contents of the third symbol display device 81 in the first control example will be described with reference to FIGS. 65 to 78. FIG. 65 is a diagram showing a display screen of the third symbol display device 81.

  The symbol, which is a type of symbol displayed on the third symbol display device 81, is composed of nine types of main symbols, each of which has a number from "1" to "9", and a sub symbol composed of a shell-shaped symbol. It is configured. More specifically, nine types of character designs such as an octopus are numbered "1" to "9" to form a main design.

  As shown in FIG. 65 (a), on the display screen (display area) of the third symbol display device 81, three symbol rows Z1, Z2, Z3 of an upper row, an interruption, and a lower row are set as a plurality of display areas. ing. In the lower symbol row Z3, nine types of main symbols "1" to "9" are arranged in ascending numerical order, and one sub symbol is arranged between each main symbol.

  That is, the upper symbol row Z1 and the lower symbol row Z3 are composed of 18 symbols. On the other hand, in the middle symbol row Z2, nine types of main symbols “1” to “9” are arranged in ascending numerical order, and the main symbol “9” and the main symbol “1” are arranged. , A main symbol of “4” is additionally arranged, and one sub symbol is arranged between these main symbols. That is, only the middle symbol row Z2 is composed of 20 symbols with 10 main symbols arranged. Then, on the display screen, the symbols in each of the symbol rows Z1 to Z3 are variably displayed so as to scroll in a predetermined direction with a periodicity.

  As shown in FIG. 65 (b), on the display screen, three symbols are stopped and displayed for each symbol row, and as a result, a total of 9 symbols of 3 × 3 are stopped and displayed. It has become. Further, five effective lines, that is, a left line L1, a middle line L2, a right line L3, a right-down line L4, and a right-up line L5 are set on the display screen. Then, the variable display is stopped in the order of the upper symbol row Z1 → the lower symbol row Z3 and the middle symbol row Z2, and all the symbol rows Z1 are formed in a state in which a combination of the symbols having the same number assigned to any of the activated lines is formed. When the variable display of .about.Z3 is finished, it is determined that a big hit has occurred and a big hit moving image is displayed.

  In this pachinko machine 10, the main symbols with odd numbers (1, 3, 5, 7, 9) correspond to “probable symbols”, and jackpot A, which is a 16R variable jackpot, or jackpot B, which is a 4R variable jackpot. If it occurs, the same combination of probable symbols is stopped and displayed. In addition, the main symbol with an even number (2,4,6,8) corresponds to a “normal symbol”, and when a jackpot C that is a 16R normal jackpot or a jackpot D that is a 4R normal jackpot occurs. , The same combination of normal symbols is stopped and displayed.

  In addition, the mode of the variable display of the symbol in the third symbol display device 81 is not limited to the above, and is arbitrary. The number of symbol columns, the direction of the variable display of the symbol in the symbol column, and the The number of symbols and the like can be changed as appropriate. Further, the pattern variably displayed on the third symbol display device 81 is not limited to the above-described symbol, and for example, a configuration in which only numbers are variably displayed as a symbol may be employed.

  Further, if a ball enters the first winning opening 64 while the variable display is being performed on the third symbol display device 81 (the first symbol display device 37), the number of entered balls is suspended up to four times. The number of retained balls is indicated by the first symbol display device 37 and also by the third symbol display device 81. The third symbol display device 81 displays one reserved ball number symbol per reserved ball number, and displays the number of reserved balls according to the number of displayed reserved ball number symbols. That is, when one reserved ball number symbol is displayed on the third symbol display device 81, it indicates that the number of reserved balls is one ball, and when four reserved ball number symbols are displayed, the reserved ball number symbol is reserved. Indicates that the number of balls is four. In addition, when the number-of-retained-balls symbol is not displayed on the third symbol display device 81, it indicates that the number of reserved balls is 0, that is, there is no reserved ball.

  In the present control example, although the ball entering the first winning port 64 is configured to be held up to four times, the maximum number of held balls is not limited to four, and is not more than three. Alternatively, the number may be set to 5 or more times (for example, 8 times). Further, instead of displaying the number of reserved balls on the third symbol display device 81, the number of retained balls is replaced by a numeral on a part of the third symbol display device 81, or the area divided into four is divided by the number of retained balls. However, the display may be performed in a different form (for example, a color or a lighting pattern). Further, since the number of reserved balls is indicated by the first symbol display device 37, the number of reserved balls may not be displayed on the third symbol display device 81. Further, the variable display device unit 80 may be provided with four holding lamps indicating the number of reserved balls for the maximum reserved number, and displaying the number of reserved balls according to the number of the reserved lamps in the lighting state.

  Next, with reference to FIG. 66 and FIG. 67, a description will be given of a super background announcement effect which is one of the effects executed in the pachinko machine 10 of the present control example. This super background announcement effect is an effect in which a player can operate the scroll direction of the background by using the selection switch 270. When a specific image (an image in which the door blinks in the present control example) is displayed in the background image of the super background notice, by operating the determination switch 270e, it is expected whether or not there is a big hit in the hold. A background image (background inside the door) indicating the value is displayed. Therefore, a player who wants to know information about whether or not there is a big hit in the hold plays a game by paying attention to the appearance of the specific image in the background image of the super background notice. As a result, the interest of the player can be improved.

  In addition, the background image of the super background notice can be scrolled and displayed in an arbitrary direction of the player by operating the switch, so that it is possible to give the player an impression as if searching in the background image. . Thereby, the interest of the player can be improved.

  FIG. 66A is a diagram illustrating an example of the background image of the super background notice effect. If the right switch 270b is pressed, for example, when the background image of the super background announcement effect is displayed, the background image is scrolled to the right. Here, in the present control example, the background image is set to be scrolled to the right based on the pressing of the right switch 270b, and then the scroll is continued until the selection switch 270 in another direction is operated. Have been. However, the present invention is not limited to this configuration, and the background image may be scrolled according to the pressing time of the selection switch 270. As a result, it is possible to flexibly respond to the operation of the player, and the interest of the player can be improved.

  FIG. 66B shows a case where the background image of the above-described super background notice effect is displayed (see FIG. 66A), and the rear image is scrolled to the right based on the pressing of the right switch 270b. FIG. By scrolling the rear image to the right, the image of the door, which is only partially displayed at the right end of the screen in FIG. 66A, can be visually recognized in the center of the screen in FIG. 66B. It is displayed in the state.

  The image of the door is data that blinks at regular intervals. As a result, when a certain period of time has passed while the door is visible as shown in FIG. 66 (b), the door blinks and is displayed as shown in FIG. 67 (a). In this case, when the enter button 270e is pressed, an effect indicating the display of the background inside the door, which is a special image, is displayed. Specifically, as shown in FIG. 67 (b), an image in which the door is opened is displayed, and the character “Enter next time!” Is displayed. Here, in the present control example, the blinking display of the door is configured to be performed at regular time intervals. However, the present invention is not limited to this, and the blinking interval may be irregular. Further, in the present control example, data that blinks at regular intervals is prepared in advance, and the blinking display of the door is configured. However, the present invention is not limited to this. It may be configured to change to.

  Note that the background inside the door (not shown), which is a special image, indicates the degree of expectation as to whether or not there is a big hit in the hold, as described above. Although the detailed processing will be described later, the background in the door is displayed from the time it is displayed until the end of the 20 changes. When the 20 changes are completed, it is determined again whether or not there is a big hit in the hold, and the background image is changed based on the determination result. Specifically, if it is determined that there is a jackpot in the hold, the same image of the background in the door as the previous time is displayed with a high probability, otherwise, the display of the background in the door is terminated. It becomes. Next, with reference to FIG. 68 to FIG. 71, a description will be given of the super reach A effect, which is one of the super reach effects executed in the pachinko machine 10 of the present control example. The effect of the super reach A is an effect executed during the fluctuation period of the third symbol, and is an effect in which a stop symbol is displayed based on the pressing of the frame button 22.

  In Super Reach A, the loose-eye display mode is displayed and a small bubble is displayed. Here, the staggered eye display mode is, for example, as shown in FIG. 68 (a), a sixth design in which the main design of the anglerfish has a number "6" attached to the left line L1 of the upper design row Z1. The symbol, the middle symbol L2, the sub symbol shell symbol, the right line L3, the main symbol of the whale, and the symbol with the number "7" are stopped and displayed, and the lower symbol row Z3 has five symbols on the left line L1, This is a display mode in which the shell pattern is stopped and displayed on the middle line L2 and the four symbols are stopped and displayed on the right line L3, and no reach is achieved on any of the lines (L1 to L5).

  Next, the character "Bubble Chance" is displayed, and the loose eye display mode is changed to the double reach display mode. Here, the double-reach display mode means that, for example, as shown in FIG. 68 (b), the same symbol as that of FIG. 68 (a) is stopped and displayed in the upper symbol column Z1, and is displayed in the left line L1 of the lower symbol column Z3. The seven symbols are a shell symbol on the middle line L2, the six symbols are stopped and displayed on the right line L3, a reach display mode of six symbols on the downward line L4, and a reach display mode of seven symbols on the upward line L5. It is an aspect.

  Then, as shown in FIG. 69 (a), a character indicating “please stop bubbles by touch!” Is displayed together with the display that a plurality of bubbles rotate, and thereafter, the bubbles rotate as shown in FIG. 69 (b). A display is displayed in which a symbol (6 symbols, 7 symbols, and a special symbol) which will be a big hit is entered in the bubble.

  Next, as shown in FIG. 70 (a), the color of the bubble containing the symbol that becomes a big hit changes, and the character "Colored bubble hit!" Is displayed. At the lower right of the screen, an indicator for displaying the remaining time during which the button can be pressed is displayed.

  Then, if the frame button 22 is pressed within the remaining time in which the button can be pressed, colored bubbles or non-colored bubbles are stopped and displayed. FIG. 70B is a diagram exemplifying a screen on which the colored bubbles are stopped and displayed.

  When the colored bubbles are stopped and displayed, as shown in FIG. 71, the colored bubbles change to a symbol (seven symbols) that becomes a big hit, and the big hit is notified. On the other hand, when the non-colored bubbles are stopped, the non-colored bubbles change to a symbol (for example, five symbols) that is detached, and the detachment is notified (not shown).

  As described above, in Super Reach A in the present control example, the symbols to be a big hit (6 symbols, 7 symbols, and the special symbol in the above example) are unified into colored bubbles, and the outlying symbols (6 symbols, 7 symbols) (The symbols other than the symbol and the special symbol) are unified as uncolored bubbles. This allows the player to press the button only by paying attention to the presence or absence of the color, thereby providing an easy-to-understand gaming machine.

  Next, with reference to FIGS. 72 to 74, a description will be given of the jackpot effect performed in the pachinko machine 10 of the present control example. In this jackpot effect, a map in which squares like sugoroku are arranged is displayed, and the square of the map can be selected based on an operation of the selection switch 270 or the like. An event is set for each of the selected cells, and a round effect during a jackpot effect is performed based on the event. The mass event is set based on the jackpot type, the number of continuations of the jackpot, the value of the display effect counter 233o, and the like.

  In addition, when the jackpot continues (when the jackpot becomes a big hit in the probable change state or the time saving state), an effect continued from the square selected in the previous jackpot effect is executed. Further, there is provided a continuum which is not the cell selected in the previous jackpot effect but can start (restart) a continuous effect. It is determined whether or not the restart from the continuum can be executed based on the history of the cells that have passed. Also, if all the squares on the map have been passed, a new map will be displayed from the next jackpot effect. Furthermore, at the end (ending) of the jackpot effect, the mass event may be changed depending on whether or not there is a jackpot in the hold.

  FIG. 72 (a) shows a case in which the first cell has been selected from the start point in the previous jackpot effect, and thereafter the jackpot effect is started continuously (a jackpot occurs during probable change or during working hours). FIG. In addition, the square in which "S" was written in the figure means the starting point, and the area starts from here at the time of the first big hit. In addition, “G” in the figure means a goal point, and the operation when reaching the goal point will be described later with reference to FIG. 73 (b).

  As shown in FIG. 72 (a), when the continuous jackpot effect is started, the effect is continuously started from the cell selected in the previous jackpot effect. When the jackpot effect is started, the cell (the previously selected cell), which is the current operation start point, is displayed in a different color from the other cells, and a dog character is displayed. Thus, the player can easily recognize where the current operation start point is. The mode in which the player can recognize the operation start point is not limited to this. For example, a form in which the cell at the operation start point blinks may be displayed, or the cell is indicated by a symbol such as an arrow. It may be something.

  An arrow indicating an operable direction is displayed near the square at the operation start point. Thus, the player can easily recognize in which direction the player can operate. In this control example, an arrow indicating that the operation can be performed in the right direction and the downward direction is displayed. Here, when the right switch 270b is pressed, the square immediately to the right of the square at the operation start point (that is, the square two points away from the start point) is lit, and a dog character is displayed.

  On the other hand, when the selection switch 270 corresponding to a direction not shown as an operable direction is operated, it is considered that the switch operation has not been performed, and the display is not changed. In the above case, a display may be performed on the screen or a sound may be output to indicate that the switch operation is invalid.

  Here, when the decision switch 270e is pressed in a state in which the cell on the right of the cell at the operation start point (that is, the cell two ahead of the start point) is selected, the cell responds to the cell event set in the cell. Is performed.

  FIG. 72 (b) shows a jackpot effect (see FIG. 72 (a)) in the case where the cell immediately after the start point is the operation start point (see FIG. 72 (a)). After the right switch 270b is pressed, the decision switch 270e is It is a figure which shows an example of the effect when pressed. In FIG. 72 (b), when it is determined based on the operation of the decision switch 270e that a cell two points ahead of the start point has been selected, an effect corresponding to the cell event set for the cell is performed. Specifically, a display indicating the content of the mass event, "The number of available backgrounds has increased!" Is displayed at the upper left of the third symbol display device 81. Thereby, the player can easily recognize the contents of the mass event.

  Further, when the continued big hit effect is started, the previous map and mass event are read, and a new mass event is read based on the value of the display effect counter 233o of the display control device 114. When a new mass event is set by comparing the previous mass event with the new mass event, for example, as shown in FIG. 73 (a), the character “Continue mass has increased!” Is displayed. Is done.

  Thereby, the player can easily recognize that the mass event has changed. On the other hand, the present invention is not limited to this, and the mass event may be changed so that the player cannot recognize it. As a result, it is possible to provide an unexpected effect for the player, and it is possible to improve the interest of the player.

  With reference to FIG. 73 (b), a description will be given of a display in the case where the jackpot effect is continuously executed after passing the continuum. In the jackpot effect of the present control example, when passing through a continuum provided on the map of the jackpot effect, it is possible to execute an effect (restart) continued from the passing cell in the next continuous jackpot effect. Become. Specifically, when there is a route (one or a plurality of squares) that has passed the continuum and has not been passed, the route is restarted from the continuum that has the unpassed route closest to the start point. You. In this case, as shown in FIG. 73 (b), the character "Restart point is here" is displayed, and a cell corresponding to the restart point is indicated by an arrow.

  Thereby, it is possible to make the player easily recognize that the continuous big hit effect is started from the cell. It should be noted that the squares that have passed are marked with “Exit” and are hatched, and the squares that have not passed are marked with “Not”. This makes it possible for the player to easily recognize which square has not passed. By this restart, it is possible to restart from not only the cell selected last time but also a continuum where there is a route that has not passed, so that it is easy to pass a cell that has not passed.

  When all the cells have passed, a new map is displayed. In this case, as shown in FIG. 74 (a), a new map is displayed, and characters "New map found!" Are displayed. This allows the player to easily recognize that the new map has been displayed.

  When it is determined that there is a big hit in the hold at the end (ending) of the big hit effect, a mass event is set based on the big hit. Specifically, as shown in FIG. 74 (b), a cell two cells ahead of the cell at the current point (that is, a cell that can be reached by generating two jackpots) is set as a special cell. By setting the two squares as the special squares, the player expects at least two more jackpots to continue the game. As a result, the interest of the player can be improved.

  Next, the effect of the super reach B in the present control example will be described with reference to FIGS. 75 to 78. FIGS. 75 and 76 are schematic diagrams schematically showing the production timing of the super reach B, and FIGS. 77 and 78 are diagrams illustrating the production of the super reach B.

  The production of Super Reach B is based on the operation of the frame button 22 by operating the frame button 22 (see FIG. 77 (a)), in which the character (girl) on the screen holds the pattern (shark, shrimp, etc.) An effect to be thrown (see FIG. 77 (b)) or an effect not to be thrown is executed. When this throwing effect is performed, the symbol in hand is changed to the next symbol. Then, if the same symbol as the reach symbol appears, the effect is to notify the big hit (see FIG. 78 (b)).

  In addition, in the case of the super-reach B effect of the jackpot, the effect of throwing until the same symbol as the reach symbol appears can be executed based on the operation of the frame button 22. If there is, based on the operation of the frame button 22, throwing is not possible until the same symbol as the reach symbol appears.

  In this control example, if the throwing effect (see FIG. 77 (a)) is executed three times, an effect for notifying the big hit (see FIG. 78 (b)) is executed. Specifically, when the reach is achieved with the symbol 7, the effect is started by throwing the symbol 4. When the effect of throwing the symbol of 4 is executed based on the operation of the frame button 22, the process then shifts to the effect of throwing the symbol of 5. Similarly, when the effect of throwing the symbol 5 is executed, the process shifts to the effect of throwing the symbol 6, and when the effect of throwing the symbol 6 is executed, the symbol 7 appears.

  On the other hand, if the frame button 22 is not pressed in the super-reach B effect of the jackpot, the jackpot will be a jackpot even though the throwing effect has not been performed. Is a different effect (replacement effect). Here, in super reach B, it is necessary to operate the frame button 22 a plurality of times before the effect for notifying the big hit is executed. Therefore, at the timing (replacement timing) when it is considered that the operation of the frame button 22 is insufficient until the performance of reporting the jackpot, the normal production is replaced with the replacement production in advance. This replacement timing is variable according to the number of times the frame button 22 is operated, and will be described later in detail.

  First, with reference to FIG. 75 (a), a description will be given of a case where the frame button 22 has never been pressed in the effect of Super Reach B. When the fluctuation of the super reach B is started, the fluctuation of the symbol (normal effect) is started. Then, the upper symbol row Z1 and the lower symbol row Z3 are stopped in the display mode of reaching, and the reach effect is started. The reach effect period is a frame SW effective period in which an effect based on pressing of the frame button 22 is executed. If there is no pressing of the frame button 22 during the frame SW valid period, the effect for notifying the big hit is replaced with the replacement effect at the replacement timing. Thereby, even if there is no pressing of the frame button 22 and there is no effect to throw, there is a big hit, and it is possible to execute a big hit notification without a sense of incongruity for the player.

  Next, with reference to FIG. 75 (b), a description will be given of a case where the frame button 22 is pressed only once in the super reach B effect. When the fluctuation of the super reach B is started, the upper symbol row Z1 and the lower symbol row Z3 are stopped in the display mode of reaching, as in the case of FIG. 75 (a) described above, and the reach effect is started. . Then, based on the fact that the frame button 22 has been pressed during the frame SW valid period, an effective effect that is an effect of throwing a symbol is executed. Here, the effect of throwing a symbol (effective effect) or the effect of not throwing a symbol (false effect), which is executed based on the button operation, is a lottery based on the effect counter 223i of the audio lamp control device 113. is there.

  When the effective effect is executed, the timing (replacement timing) at which the operation of the frame button 22 is considered to be insufficient changes before the effect for notifying the jackpot, so the replacement timing is delayed by the delay time dt. You. Thereby, even if the operation of the frame button 22 is in time by the execution of the effect for notifying the jackpot, it is possible to prevent the effect for notifying the jackpot from being replaced.

  In FIG. 75 (b), since the frame button 22 is not pressed after the frame button 22 is pressed once, the jackpot is notified at the replacement timing (after the change) delayed by the delay time dt as described above. The effect will be replaced with a replacement effect.

  Next, with reference to FIG. 76 (a), a description will be given of a case where the effect of Super Reach B is such that the frame button 22 is depressed, and the effect of notifying the jackpot is replaced with the jackpot.

  When the fluctuation of the super reach B is started, the upper symbol row Z1 and the lower symbol row Z3 are stopped in the display mode in which the symbol reaches 7 in the same manner as in the case of FIGS. 75 (a) and (b) described above. And the reach production is started. Then, based on the pressing of the frame button 22 during the frame SW valid period, an effective effect or a false effect is executed. In FIG. 76 (a), a false effect, which is an effect in which the symbol 4 cannot be thrown by the first press, is executed. Then, an effective effect is executed by the second and third presses, and the symbol possessed by the character is changed to the symbol 6. When the frame button 22 is pressed during the stoppable period in a state where the symbol 6 is displayed, a stop display effect as an effective effect is executed, and a stop display in which the symbol 7 appears is executed.

  On the other hand, even if the frame button 22 is pressed during the non-stoppable period, an effective effect is not executed, and a fake effect is executed. Thereby, it is possible to prevent the effect of the stop display from being executed at an early timing when the display period of the stop display is insufficient.

  Next, with reference to FIG. 76 (b), a description will be given of a case where the frame button 22 is depressed in the effect of Super Reach B, and the effect of notifying the jackpot is reported without replacement.

  In FIG. 76 (b), similarly to FIG. 76 (a) described above, in the frame SW valid period, a false effect and two valid effects are executed based on the operation of the frame button 22 three times. The symbol appears. Here, in FIG. 76 (a), when the frame button 22 is pressed during the stoppable period, a stop display effect, which is an effective effect, is executed, and the symbol 7 appears. On the other hand, in FIG. 76 (b), when the frame button 22 is pressed during the stoppable period, a stop display effect that is a false effect is executed, and the symbol 7 does not appear. Thereby, it is possible to prevent a symbol that is a big hit from being displayed even when the display mode of the out-of-reach super reach B is being executed.

  As shown above, FIG. 77 (a) illustrates a screen in which an effective effect based on the frame button 22 is not executed when the reach is reached with the symbol 7 in the super reach B. At the upper left of the screen, 7 symbols are displayed to indicate that the reach has been reached with 7 symbols. In addition, the character at the center of the screen has a symbol of 4 and the effective effect is executed three times, so that the symbol changes from symbol 5 to symbol 6 → symbol 7 and is a reach symbol 7. Will be displayed. In the lower right part of the screen, an indicator indicating the effective period of the frame SW is displayed.

  FIG. 77 (b) illustrates a screen in which an effective effect is executed based on the operation of the frame button 22 when the symbol 4 is displayed in the frame SW valid period of the super reach B as described above. It was done. An effect in which the character in the center of the screen throws the symbol 4 based on the operation of the frame button 22 is displayed.

  FIG. 78 (a) is a diagram illustrating an example of a screen that has a jackpot due to the above-described replacement effect. The notification of the jackpot by the replacement effect is executed when the jackpot has been achieved even though the operation of the frame button 22 has not been executed. In this case, since the operation of the frame button 22 has not been executed, the stop display is performed in an out of form. Therefore, in the present control example, after the stop display, an effect for notifying the big hit in which the character “Resurrection big hit” is displayed as shown in FIG. 78A is executed. This allows the player to recognize that it is a jackpot effect that appears to be off. As a result, the jackpot is notified in spite of the stop display in the off state, so that the uncomfortable feeling felt by the player can be reduced.

  FIG. 78 (b) is a diagram exemplifying an effect in which a big hit is notified by a normal effect in which replacement is not performed. This effect is a diagram in a case where the frame button 22 is pressed a specified number of times during the frame SW valid period and a big hit symbol appears as shown in FIG. 76 (a). In FIG. 78 (b), based on the pressing of the frame button 22 during the stoppable period, the effect of throwing the symbol 6 to the upper right of the screen is achieved.

<Electrical Configuration in First Control Example>
Next, the RAM 203 provided in the main control device 110 will be described with reference to FIGS. In the main control device 110, a special symbol lottery, a normal symbol lottery, a display setting on the first symbol display device 37, a display setting on the second symbol display device 83, and a display setting on the third symbol display device 81 are set. The main processing of the pachinko machine 10 is executed. The RAM 203 is provided with various counters for controlling these processes. Here, a counter and the like provided in RAM 203 of main controller 110 will be described with reference to FIG. These counters and the like are used for special symbol lottery, ordinary symbol lottery, display setting on the first symbol display device 37, display setting on the second symbol display device 83, and display setting on the third symbol display device 81. It is used by the MPU 201 of the main control device 110 to perform such operations.

  In order to select the special symbol lottery and the display setting of the first symbol display device 37 and the third symbol display device 81, the first random number counter C1 used for the special symbol lottery and the special symbol big hit type are selected. , A first type random number used for setting an initial value of a first random number counter C1, a stop type selection counter C3 used for selecting an outage type of stop in a special symbol, A counter CINI1 and a variation type counter CS1 used for variation pattern selection are used. In addition, the second random number counter C4 is used for the lottery of the normal symbols, and the second initial value random number counter CINI2 is used for setting the initial value of the second random number counter C4. Each of these counters is a loop counter that adds 1 to the previous value and returns to 0 after reaching the maximum value each time the counter is updated.

  Each counter is updated, for example, at an interval of 2 milliseconds, which is the execution interval of the timer interrupt process (see FIG. 92), and some counters are updated irregularly in the main process (see FIG. 100). Then, the updated value is appropriately stored in the counter buffer 203h of the RAM 203. The RAM 203 is provided with a special symbol reserved ball storage area 203a including one execution area and four reserved areas (reserved first to fourth areas), and each of these areas has a first winning port 64. Alternatively, the respective values of the first random number counter C1, the first hit type counter C2, and the stop type selection counter C3 are stored in synchronization with the timing of entering the second winning opening 640. Further, the RAM 203 is provided with a normal symbol holding sphere storage area 203b including one execution area and four holding areas (holding first to fourth areas). The value of the second random number counter C4 is stored in synchronization with the timing of passing through the symbol starting port (through gate) 67.

  Each counter will be described in detail. The first random number counter C1 is incremented by one in order within a predetermined range (for example, 0 to 399), and reaches 0 after reaching the maximum value (for example, 399 in the case of a counter that can take a value of 0 to 399). The configuration is returned to. In particular, when the first random number counter C1 makes one round, the value of the first initial value random number counter CINI1 at that time is read as the initial value of the first random number counter C1.

  In addition, the first initial value random number counter CINI1 is configured as a loop counter that is updated in the same range as the first random number counter C1. That is, for example, when the first random number counter C1 is a loop counter that can take a value of 0 to 399, the first initial value random number counter CINI1 is also a loop counter in the range of 0 to 399. The first initial value random number counter CINI1 is updated once each time the timer interrupt process (see FIG. 92) is executed, and is repeatedly updated within the remaining time of the main process (see FIG. 100).

  The value of the first random number counter C1 is, for example, updated periodically (once for each timer interrupt processing in the present control example), and the RAM 203 is updated at the timing when the ball wins the first winning opening 64 or the second winning opening 640. Is stored in the special symbol holding ball storage area 203a. Then, the value of the random number to be the special symbol jackpot is set by the first random number table 202a stored in the ROM 202 of the main control device 110, and the value of the first random number counter C1 is set to the first random number table. If the value matches the value of the random number which becomes the jackpot set by 202a, it is determined that the special symbol is a jackpot. In addition, the first random number table 202a includes a special symbol for a low probability (a period during which the special symbol is in a low probability state) and a high symbol for a special symbol having a higher probability of being a big hit than the low probability. For the special symbol high-probability state). That is, in each state, the number of jackpot random numbers included in the table is different. In this way, by making the number of random numbers which are big hits different, the probability of big hits is changed between a low probability of a special symbol and a high probability of a special symbol.

  The first hit type counter C2 determines the display mode of the first symbol display device 37 when a special symbol hits, and adds one by one in a predetermined range (for example, 0 to 99). Then, after reaching the maximum value (for example, 99 in the case of a counter that can take a value of 0 to 99), it returns to 0. The value of the first hit type counter C2 is, for example, updated periodically (once every timer interrupt processing in the present control example), and at the timing when the ball wins the first winning opening 64 or the second winning opening 640. It is stored in the special symbol holding ball storage area 203a of the RAM 203.

  Here, the value of the first random number counter C1 stored in the special symbol holding ball storage area 203a or the special symbol 2 holding ball storage area 203b is not a random number which is a big hit of the special symbol, that is, the special symbol is out. If the random number is, the display mode corresponding to the stop symbol displayed on the first symbol display device 37 is the one when the special symbol is removed.

  On the other hand, if the value of the first random number counter C1 stored in the special symbol holding ball storage area 203a is a random number that is a special symbol jackpot, the value corresponding to the stop symbol displayed on the first symbol display device 37 is displayed. The display mode is that at the time of the special symbol jackpot. In this case, the specific display mode at the time of the big hit is the display mode indicated by the value of the first hit type counter C2 stored in the same special symbol holding ball storage area 203a.

  The first random number counter C1 in the pachinko machine 10 of this control example is configured as a 2-byte loop counter in the range of 0 to 299. In the first random number counter C1, when the special symbol has a low probability, there are three random numbers which are the big hits of the special symbol, and the random numbers "0 to 2" are the first random numbers for the low probability. This is stored in the table 202a (see FIG. 81 (b)). As described above, when the special symbol has a low probability, the total number of random numbers is 400 out of the total number of random numbers, and the total number of random numbers to be a jackpot is 3, so the probability of the special symbol to be a jackpot is “3/400”.

  On the other hand, when the special symbol has a high probability, there are thirty random number values which are the big hits of the special symbol, and the values “0 to 29” are stored in the first random number table 202a for the high probability time (FIG. 81 (b)). ) See). As described above, when the special symbol has a high probability, the total number of random number values is 30 out of 400, and the total number of random number values to be a jackpot is 30, so the probability of a special symbol to be a jackpot is “3/40”.

  Further, the value of the first hit type counter C2 in the pachinko machine 10 of this control example is configured as a loop counter in the range of 0 to 99, and is provided in the ROM 202 with the value of the first hit type counter C2. The big hit type is determined based on the first hit type selection table 202b (see FIG. 81 (c)). As shown in FIG. 81 (c), in the case of a special symbol jackpot, the jackpot type when the random value is “0 to 24” is “big hit A” in the first hit type counter C2. If the random number is “25 to 49”, the jackpot type is “jackpot B”. When the random number is “50 to 74”, the jackpot type is “big hit C”, and when the random number is “75 to 99”, the jackpot type is “big hit D”.

  The stop type selection counter C3 is configured to be incremented by one in order within a range of 0 to 99, for example, and to return to 0 after reaching the maximum value (that is, 99). In this control example, the stop type at the time of disconnection displayed on the third symbol display device 81 is selected by the stop type selection counter C3, and after the reach occurs, the final stop symbol is shifted by one before and after the reach symbol. "Reach out of front and rear" (e.g., 98, 99), and "reach other than front and rear out" (e.g., in a range of 90 to 97) in which the final stop symbol stops at positions other than before and after the reach symbol after reaching. Three stop (effect) patterns of "completely out of range" (for example, in the range of 0 to 89) where no reach occurs are selected. The value of the stop type selection counter C3 is updated, for example, periodically (once for each timer interrupt process in the present control example), and the value of the RAM 203 at the timing when the ball wins the first winning opening 64 or the second winning opening 640. It is stored in the special symbol holding ball storage area 203a.

  The random number value for determining the special symbol stop type from the value of the stop type selection counter C3 (random value) is set by a stop type selection table (not shown). It is provided in the ROM 202 of the device 110. Also, in this control example, this table is divided into a special symbol for the high probability case and a special symbol for the low probability case. Is changing. This is because the selection ratio of the stop type is changed according to whether the pachinko machine 10 is in the special symbol high-probability state or the special symbol low-probability state.

  For example, in the high-probability state, the jackpot is likely to occur, so that the reach effect is not selected more than necessary. Is selected, and it becomes easier to select “completely off”. In this table, the "reach out of front and rear" is narrowed to 98 and 99, and the "reach other than front and rear out" is also narrowed to 90 to 97, so that it is difficult to select "reach out of front and rear" and "reach other than front and rear out". In the low probability state, the range of the random value corresponding to the stop type of “completely out of range” is 0 to 79 in order to secure the ball entry time to the first winning opening 64 or the second winning opening 640. And a narrow low probability table is selected, and it is difficult to select “completely out of place”. In the low-probability state, the range of the random number value corresponding to the stop type of “reach other than front and rear out” is widened to 80 to 97, and “reach other than front and back out” is easily selected. Therefore, in the low probability state, it is possible to perform many reach displays with a long production time, so that the ball entry time to the first winning opening 64 or the second winning opening 640 can be secured, and the fluctuation by the third symbol display device 81 can be ensured. The display is easily performed continuously. Also in the latter table, the range of the random number value corresponding to the stop type of “out-of-reach reach” is set to 98,99.

  The variation type counter CS1 is configured to be incremented by one, for example, in the range of 0 to 198, and to return to 0 after reaching the maximum value (that is, 198). A rough display mode such as a so-called normal reach and a super reach is determined by the variation type counter CS1. The determination of the display mode is, specifically, the determination of the variation time of the symbol variation. Here, the fluctuating time refers to the time from the start of the change of the special symbol until the symbol is stopped and displayed and the symbol is fixed. For example, if a symbol is stopped and displayed for 0.4 seconds after the symbol variation of 9.6 seconds is executed and the symbol is determined, the variation time is 10 seconds (9.6 seconds + 0.4 seconds). It is written as Based on the fluctuation time, the reach type and the fine symbol fluctuation mode of the third symbol displayed on the third symbol display device 81 are determined by the sound lamp control device 113 and the display control device 114. The value of the variation type counter CS1 is updated once each time a main process (see FIG. 100) described below is executed once, and is repeatedly updated even within the remaining time in the main process. The fluctuation pattern selection table 202d (see FIGS. 82 (a) to (d)) which stores a random number value for determining one fluctuation time of the symbol fluctuation from the value (random number value) of the fluctuation type counter CS1 is the main control. It is provided in the ROM 202 of the device 110 (see FIG. 82A).

  The variation pattern selection table 202d (see FIGS. 82 (a) to (d)) includes, for example, “out (for a long time)”, “out (for a short time)”, “out of Various types of "Normal reach", various types of "Super-reach", various types of "Special out-of-reach" are specified, and the fluctuation patterns for jackpots include various types of "Normal hit", "Super-reach", and "Special". ing. Then, from the various variation patterns defined in the variation pattern selection table 202d, a variation pattern is selected according to a lottery result and a stop type (in the case of a big hit, a big hit type). The variation time of the variation pattern effect of 5 seconds to 30 seconds specified in the variation pattern selection table 202d is, for example, a variation time of 5 seconds to 30 seconds.

  Here, the types of super reach will be described. In the present control example, “super reach A”, “super reach B”, and various other super reach are defined as types of super reach. “Super reach A” is a reach effect that performs an effect based on the player pressing the frame button 22 as an example of the effect screens of FIGS. 68 to 71 described above, and “super reach B” This is a reach effect in which an effect based on the player pressing the frame button 22 is given by taking the effect screens of FIGS. 77 and 78 as an example.

  The second random number counter C4 is configured as, for example, a loop counter that is incremented by one in the range of 0 to 239, and returns to 0 after reaching the maximum value (that is, 239). When the second random number counter C4 makes one round, the value of the second initial value random number counter CINI2 at that time is read as the initial value of the second random number counter C4. In the present control example, the value of the second random number counter C4 is updated, for example, periodically at each timer interrupt processing, and is acquired when it is detected that the ball has passed the normal symbol starting port (through gate) 67. Are stored in the ordinary symbol holding ball storage area 203b of the RAM 203.

  Then, the value of the random number which is the hit of the ordinary symbol is set by the second random number table (FIG. 81 (d)) stored in the ROM 202 of the main control device, and the value of the second random number counter C4 is If it matches the value of the random number as a win set by the second random number table, it is determined that the hit is a normal symbol. In addition, the second random number table is used for a low probability of a normal symbol (a period during which the symbol is in a normal state) and for a high probability (a normal symbol is more likely to be hit) than the low probability. ), And the number of jackpot random numbers contained therein is set differently. As described above, by making the number of winning random numbers different, the probability of winning is changed between a low probability of a normal symbol and a high probability of a normal symbol.

  At the time of the low probability of the ordinary symbol, there are 24 random numbers which are the hits of the ordinary symbol, and the range is "5-28". These random numbers are stored in a second random number table for low probability. As described above, when the normal symbol has a low probability, the total number of random number values to be a big hit is 24 out of a total of 240 random numbers, so that the probability of a special symbol to be a big hit is “1/10”.

  When the pachinko machine 10 is in the low probability state of the ordinary symbol, when the ball passes through the ordinary symbol starting port 67, the value of the second random number counter C4 is acquired, and the second symbol display device 83 displays the value of the ordinary symbol. The fluctuation display is executed for 30 seconds. If the acquired value of the second random number counter C4 is in the range of “5 to 28”, it is determined that the winning has occurred, and after the variable display on the second symbol display device 83 has been completed, the stop symbol (the second symbol) ), The symbol of “」 ”is illuminated and displayed, and the second winning opening 640 is opened for“ 0.2 seconds × 1 time ”. In the present control example, when the pachinko machine 10 is in the low probability state of the ordinary symbol, the second winning opening 640 is opened only for “0.2 seconds × 1 time” when the ordinary symbol is hit. The opening time and the number of times may be set arbitrarily. For example, “0.5 seconds × 2 times” may be opened.

  On the other hand, when the ordinary symbol has a high probability, there are 200 random numbers which are the jackpots of the ordinary symbol, and the range is "5 to 204". These random numbers are stored in a random number table per symbol for high probability. As described above, when the special symbol has a low probability, the total number of random number values to be a big hit is 200 out of a total of 240 random numbers, and thus the probability of a special symbol to be a big hit is “1 / 1.2”.

  When the pachinko machine 10 is in the high probability state of the ordinary symbol, when the ball passes the ordinary symbol starting port 67, the value of the second random number counter C4 is obtained and the second symbol display device 83 displays the normal symbol. The fluctuation display is executed for 3 seconds. If the acquired value of the second random number counter C4 is in the range of “5 to 204”, it is determined that the winning has occurred, and after the variable display on the second symbol display device 83 has been completed, the stop symbol (the second symbol) ), The symbol of “」 ”is illuminated and displayed, and the second winning opening 640 is opened“ 1 second × 2 times ”. As described above, when the normal symbol has a high probability, the time of the variable display becomes very short as “30 seconds → 3 seconds” as compared with when the normal symbol has a low probability, and the opening period of the second winning opening 640 is further reduced. Is extremely long, such as “0.2 seconds × 1 time → 1 second × 2 times”, so that the ball easily enters the second winning opening 640. The ROM 202 stores a table (not shown) that stores a random number value for determining whether or not a normal symbol has been hit based on the value of the second random number counter C4 (random number value). In the present control example, when the pachinko machine 10 is in the high probability state of the ordinary symbol, the second winning opening 640 is opened by “1 second × 2 times” when the ordinary symbol is hit. And the number of times may be set arbitrarily. For example, “3 seconds × 3 times” may be opened.

  The second initial value random number counter CINI2 is configured as a loop counter that is updated in the same range as the second random number counter C4 (value = 0 to 239), and is updated once every timer interrupt processing (see FIG. 92). At the same time, it is repeatedly updated within the remaining time of the main processing (see FIG. 100).

  As described above, the RAM 203 is provided with various counters and the like, and the main control device 110 performs the jackpot lottery and the display of the first symbol display device 37 and the third symbol display device 81 in accordance with the values of the counters and the like. The main processing of the pachinko machine 10 such as setting and lottery of the display result on the second symbol display device 83 can be executed.

  Returning to FIG. 80, the description will be continued. The RAM 203 includes, in addition to the various counters shown in FIG. 79, a stack area in which the contents of internal registers of the MPU 201 and a return address of a control program executed by the MPU 201 are stored, various flags and counters, I / Os, and the like. And a work area (work area) in which the value is stored.

  The RAM 203 has a configuration in which a backup voltage is supplied from the power supply 115 to retain data (backup) even after the power of the pachinko machine 10 is cut off, and all data stored in the RAM 203 is backed up. .

  When the power is shut down due to the occurrence of a power failure or the like, the stack pointer and the value of each register at the time of the power shutdown (including when a power failure occurs; the same applies hereinafter) are stored in the RAM 203. On the other hand, when the power is turned on (including turning on the power by turning off the power, the same applies hereinafter), the state of the pachinko machine 10 is returned to the state before the power was turned off based on the information stored in the RAM 203. The writing to the RAM 203 is executed when the power is turned off by the main process (see FIG. 100), and the restoration of each value written to the RAM 203 is executed in the startup process when the power is turned on (see FIG. 99). The power failure signal SG1 from the power failure monitoring circuit 252 is input to the NMI terminal (non-maskable interrupt terminal) of the MPU 201 when the power is cut off due to a power failure or the like, and the power failure signal SG1 is output to the MPU 201. , An NMI interrupt process (see FIG. 98) as a power failure process is immediately executed.

  In addition, as shown in FIG. 50, the RAM 203 stores a special symbol retaining ball storage area 203a, a normal symbol retaining ball storage area 203b, a special symbol retaining ball number counter 203c, and a normal symbol retaining ball number counter 203d. It has a flag 203e, a time saving counter 203f, a prefetch certainty changing flag 203g, a counter buffer 203h, and a memory area 203z.

  The special symbol holding ball storage area 203a is a storage area for the first winning opening 64 and the second winning opening 640, and includes one execution area and four holding areas (first holding area to fourth holding area). Each of these areas stores a value of a first random number counter C1, a first type counter C2, and a stop type selection counter C3.

  More specifically, at the timing when the ball wins the first winning opening 64 or the second winning opening 640 (start winning), each value of each of the counters C1 to C3 is acquired, and the acquired data is four times. Of the vacant areas of the reserved areas (the first reserved area to the fourth reserved area), the areas are stored in order from the area having the smallest area number (first to fourth). That is, the data corresponding to the winning in time is stored in an area having a smaller area number, and the data corresponding to the winning in time is stored in the reserved first area. If data is stored in all four holding areas, nothing is newly stored.

  Thereafter, when a special symbol lottery is performed in the main control device 110, the values of the counters C1 to C3 stored in the reserved first area of the special symbol reserved ball storage area 203a are shifted to the execution area. Then, based on each value of each of the counters C1 to C3 stored in the execution area, a determination such as a lottery of a special symbol is made.

  When data is shifted from the reserved first area to the execution area, the reserved first area becomes empty. Therefore, there is a shift process of packing the winning data stored in the other reserved areas (the reserved second area to the reserved fourth area) into the reserved area having the smaller area number (the reserved first area to the reserved third area). Done. In the present control example, in the special symbol reserved ball storage area 203a, data shift is performed only for the reserved areas (second reserved area to fourth reserved area) in which winning data is stored.

  In the pachinko machine 10, the ball wins (starts winning) in the first winning opening 64 or the second winning opening 640, and as soon as each value of each of the counters C1 to C3 is obtained in accordance with the starting winning, the ball is turned on. A winning information command including the value is transmitted to the sound lamp control device 113. When the winning information command is received by the sound lamp control device 113, the sound lamp controlling device 113 extracts each value of each of the counters C1 to C3 from the winning information command, and uses them as winning information as a winning information storage area of the RAM 233. 223a.

  The normal symbol holding ball storage area 203b has one execution area and four holding areas (first holding area to fourth holding area), similarly to the special symbol holding ball storage area 203a. Each of these areas stores a second random number counter C4.

  More specifically, the value of the counter C4 is acquired at the timing when the ball has passed the ordinary symbol starting port 67, and the acquired data is stored in the four holding areas (first holding area to fourth holding area). Among the vacant areas, the area numbers (first to fourth) are stored in order from the smallest area. That is, similarly to the special symbol reserved ball storage area 203a, the data corresponding to the winning is stored while the winning order is maintained. If data is stored in all four holding areas, nothing is newly stored.

  Thereafter, in the main control device 110, when the lottery for the normal symbol is performed, the value of the counter C4 stored in the first reserved area of the ordinary symbol reserved ball storage area 203b is shifted to the execution area ( Is moved), and based on the value of the counter C4 stored in the execution area, a determination such as a lottery for a normal symbol is made.

  Note that when the data is shifted from the reserved first area to the execution area, the reserved first area becomes empty, so that the prize winning data stored in the other reserved areas is stored in the same manner as the special symbol reserved ball storage area 203a. , A shift process is performed to fill the reserved area with the smaller area number. The data shift is also performed only for the reserved area in which the winning data is stored.

  The special symbol holding ball number counter 203c is a variable display of a special symbol (first symbol) performed by the first symbol display device 37 based on a ball (start winning) into the first winning port 64 or the second winning port 640. This is a counter for counting the number of reserved balls (the number of times of standby) of (variable display performed by the third symbol display device 81) up to four times. The special symbol reserved ball count counter 203c has an initial value set to zero, and each time a ball enters the first winning port 64 or the second winning port 640 and the number of reserved balls in the variable display increases, One is added to the maximum value 4 (see S404 in FIG. 95). On the other hand, the special symbol reserved ball number counter 203c is decremented by one each time a new variable display of the first special symbol is executed (see S205 in FIG. 93).

  The value of this special symbol reserved ball number counter 203c (the number of times N of the variable display in the special symbol is retained) is notified to the sound lamp control device 113 by a reserved ball number command (see S206 in FIG. 93 and S405 in FIG. 95). The reserved ball count command is a command transmitted from the main control device 110 to the sound lamp control device 113 each time the value of the special symbol reserved ball count counter 203c is changed.

  Each time the value of the special symbol reserved ball number counter 203c is changed, the sound ramp control device 113 uses the reserved ball number command transmitted from the main control device 110 to display the variable display reserved ball retained in the main control device 110. You can get the value of the number itself. As a result, the number of retained balls of the variable display, which is managed by the special symbol reserved ball number counter 223b of the audio lamp control device 113, is changed to the actual number of retained balls of the variable display retained by the main control device 110 due to noise or the like. Even if it has shifted, the shift can be corrected by the next received ball count command.

  The voice lamp control device 113 manages the number of reserved balls based on the reserved ball number command, and displays the reserved ball number for notifying the display control device 114 of the reserved ball number every time the reserved ball number changes. Send the ball count command. The display control device 114 displays the reserved ball count symbol on the third symbol display device 81 based on the reserved ball count notified by the display reserved ball count command.

  The ordinary symbol holding ball number counter 203d maximizes the number of waiting balls (the number of waiting times) of the variable display of the ordinary symbol (second symbol) performed by the second symbol display device 83 based on the passage of the ball at the ordinary symbol starting port 67. This is a counter that counts up to four times. The normal symbol reserved ball number counter 203d has an initial value set to zero, and each time a ball passes through the regular symbol start port 67 and the number of retained balls of the variable display increases, one is added to the maximum value of four. (See S604 in FIG. 97). On the other hand, the normal symbol holding ball number counter 203d is decremented by one each time a new variable display of the normal symbol (second symbol) is executed (see S505 in FIG. 96).

  When the ball passes through the ordinary symbol starting port 67, if the value of the ordinary symbol retaining ball number counter 203d (the number of times M of the variable display in the ordinary symbol is retained) is less than 4, the value of the second random number counter C4 is increased. The acquired data is stored in the ordinary symbol holding ball storage area 203b (S605 in FIG. 97). On the other hand, when the ball passes through the ordinary symbol starting port 67, if the value of the ordinary symbol retaining ball number counter 203d is 4, nothing is newly stored in the ordinary symbol retaining ball storage area 203b (see FIG. 97). S603: No).

  The probable changing flag 203e is a flag indicating whether or not the pachinko machine 10 is in the probable changing state of the special symbol (high probability state of the special symbol). If the value of the probable changing flag 203e is on, the pachinko machine 10 is turned off. It indicates that the special symbol is in the probable state, and if the value of the probable changing flag 203e is off, it indicates that the pachinko machine 10 is in the normal state of the special symbol (low probability state of the special symbol). The initial value of the probable changing flag 203e is set to off, and the main controller 110 sets the timing at which the specific winning opening (large opening) 65a closes in the final round of the jackpot (ie, the end timing of the jackpot) in the main round of the jackpot. A value corresponding to the jackpot type is set. Specifically, in the case of "big hit type A" or "big hit type B", ON is set, and in the case of "big hit type C" and "big hit type D", OFF is set.

  When the special symbol change start process (see FIG. 59) is executed by the MPU 201, a special symbol lottery is performed. In the special symbol change start process, the value of the probable changing flag 203e is referred to, and if the value is on, a special symbol lottery is performed based on the high probability determination value in the first random number table 202a. On the other hand, if the value of the probable changing flag 203e is off, a special symbol lottery is performed based on the low probability determination value in the first random number table 202a.

  The time reduction counter 203f is a counter that indicates whether or not the pachinko machine 10 is in the normal symbol time reduction state. If the value of the time reduction counter 203f is 1 or more, the pachinko machine 10 is in the normal symbol time reduction state. If the value of the counter 203f during time reduction is 0, it indicates that the pachinko machine 10 is in a normal state of a normal symbol. The initial value of the time reduction counter 203f is set to zero, and the timing corresponding to the type of the jackpot at the closing timing of the specific winning opening (large opening opening) 65a (ie, the end timing of the jackpot) in the last round of the jackpot. Is set. Specifically, in the case of "big hit type A" or "big hit type C", 100 is set, and in the case of "big hit type B" or "big hit type D", 0 is set. Thereafter, 1 is decremented each time the special symbol fluctuating effect ends until the value of the counter 203f during working hours decreases to 0 (S223 in FIG. 57).

  When a lottery for a normal symbol is performed, the value of the counter 203f during time saving is referred to, and if the value is 1 or more, a lottery for a normal symbol is performed based on a random number per symbol symbol for a high probability time. On the other hand, if the value of the counter 203f during time-saving is 0, the lottery of the ordinary symbols is performed based on the random number table per symbol for low probability time (see S710 and S711 in FIG. 62).

  As described above, the counter buffer 203h is a buffer area used for counting each counter value.

  The other memory area 203z is provided as an area for storing data other than the above-described data, and is an area for temporarily storing other counter values used by the MPU 201 of the main control device 110.

  Next, the ROM 202 provided in the MPU 201 of the main control device 110 will be described with reference to FIGS. The ROM 202 stores various control programs executed by the MPU 201 and fixed value data as described above.

  FIG. 81A is a diagram schematically showing the contents of the ROM 202 provided in the main control device 110. As shown in FIG. 81A, the ROM 202 is provided with at least a first random number table 202a, a first random type selection table 202b, a second random number table 202c, and a variation pattern selection table 202d. .

  The first hit random number table 202a (see FIG. 81 (b)) is a table in which the value of the random number which is the big hit of the special symbol is defined as described above. When the random number value defined in the first random number table 202a matches the value of the first random number counter C1, it is determined that the special symbol is a big hit. The first random number table 202a includes a table (a first random number table 202a for low probability) for determining whether or not a special symbol is a big hit when the special symbol has a low probability. There is provided a table (first random number table 202a for high probability) for discriminating whether or not a special symbol is a jackpot at the time of probability, and the number of jackpot random numbers included in each table is different. I have. In this way, by making the number of random numbers which are big hits different, the probability of big hits is changed between a low probability of a special symbol and a high probability of a special symbol.

  The first hit type selection table 202b (see FIG. 81 (c)) is a data table in which the determination value of the first hit type counter C2 for determining the big hit type is set for each big hit type. . As shown in FIG. 81 (c), in the first hit type selection table 202b, the big hit A, the big hit B, the big hit C, and the big hit D are set to be selectable, respectively. The value “0-24” of the type counter C2, “25-49” as the jackpot B determination value, “50-74” as the jackpot C determination value, and “74-99” as the jackpot D determination value are set. I have.

  The second hit random number table 202c (see FIG. 81 (d)) is a data table in which hit determination values of ordinary symbols are stored. As shown in FIG. 81 (d), when the normal symbol has a low probability (in the normal state of the ordinary symbol), the value of the second random number counter C3 stored in the second random number counter buffer is in the range of 5-28. In the case of, it is determined that the hit is a normal symbol. As described above, when it is determined that a normal symbol has been hit, after the variable display on the second symbol display device 83 is completed, a symbol of “」 ”is displayed as a stopped symbol (second symbol) while being lit and displayed. The electric accessory 640a attached to the second winning opening 640 is opened for “0.2 seconds × 1 time”.

  On the other hand, at the time of the high probability of the ordinary symbol (during the time saving state of the ordinary symbol), when the value of the second random number counter C3 is in the range of 5 to 204, it is determined that the symbol is a normal symbol hit. As described above, when it is determined that a normal symbol has been hit, after the variable display on the second symbol display device 83 is completed, a symbol of “」 ”is displayed as a stopped symbol (second symbol) while being lit and displayed. Then, the electric accessory 640a attached to the second winning opening 640 is opened “1 second × 2 times”.

  Next, the variation pattern selection table 202d will be described with reference to FIG. The fluctuation pattern selection table 202d (see FIG. 82A) is a data table used to determine the display mode of the fluctuation pattern, and the display mode is defined for each value of the fluctuation type counter CS1. A plurality of different tables corresponding to the special symbol lottery results are defined in the variation pattern selection table 202d. More specifically, as shown in FIG. 82 (a), the variation pattern selection table 202d includes a special jackpot variation pattern table 202d1 (see FIG. 82 (b)) when the hit determination result is a big hit, and The result is out of range, and when the game is in the normal game state, a special (normal) variation pattern table 202d2 (see FIG. 82 (c)) is used. Each of them is at least constituted by a use (probable change) variation pattern selection table 202d3 (see FIG. 82D).

  Here, the various super reach selected by each variation pattern table includes “super reach A”, “super reach B”, or other super reach selected by the value of the variation type counter CS1. The type of the super reach selected by the variation pattern table is transmitted from the main control device 110 to the voice control device 113, and is transmitted from the voice control device 113 to the display control device 114, so that various super reach effects are executed. Is done.

  Next, the ROM 222 and the RAM 223 of the audio lamp control device 113 will be described with reference to FIG. The ROM 222 of the audio ramp control device 113 stores at least a fluctuation pattern table. The variation pattern table will be briefly described because it is already known. However, based on the variation pattern command output from the main controller 110, the rough variation contents (variation time, variation type) indicated by the variation pattern command are described. (Reach, departure, etc.)). As a result, various variations can be determined.

  As shown in FIG. 83, the RAM 223 of the sound lamp control device 113 includes a winning information storage area 223a, a special symbol holding ball counter 223b, a change start flag 223c, a stop type selection flag 223d, At least a flag 223e, a frame SW valid period 223f, a replacement timing 223g, a replacement flag 223h, an effect counter 223i, and another memory area 223z are provided.

  The prize information storage area 223a has one execution area and four areas (first area to fourth area). Each of these areas has a counter C1 to C3 as prize information. Each value is stored. In the present pachinko machine 10, when the main controller 110 wins a start, each value of the first random number counter C1, the first hit type counter C2, and the stop type selection counter C3 acquired according to the start winning is obtained. The main controller 110 predicts (estimates) various information (acceptance, stop type, variation pattern) obtained when a special symbol corresponding to the start winning is selected, and the predicted various information is The main controller 110 notifies the sound lamp controller 113 of a winning information command.

  When the prize information command is received, the sound lamp control device 113 extracts various information (acceptance, stop type, change pattern) notified by the prize information command, as the prize information, and divides the prize information into the prize information. It is stored in the storage area 223a. More specifically, the extracted winning information is stored in ascending order of the area numbers (first to fourth) among the vacant areas of the four areas (first area to fourth area). Is done. That is, the data corresponding to the winning in time is stored in the area having the smaller area number, and the data corresponding to the winning in time is stored in the first area.

  The special symbol retaining ball number counter 223b is a variable effect (variable display) performed by the first symbol display device 37 (and the third symbol display device 81), similarly to the special symbol retaining ball number counter 203c of the main controller 110. The counter is a counter that counts up to four times the number of suspended balls (the number of times of waiting) of the variable effect that is suspended in the main control device 110.

  As described above, the sound lamp control device 113 cannot directly access the main control device 110 and acquire the value of the special symbol reserved ball count counter 203c stored in the RAM 203 of the main control device 110. Therefore, the sound lamp control device 113 counts the number of reserved balls based on the reserved ball number command transmitted from the main control device 110, and manages the reserved ball number with the special symbol reserved ball number counter 223b. Has become.

  Specifically, the main control device 110 adds the number of reserved balls of the variable display by entering the first winning opening 64 or the second winning opening 640, or the first special symbol in the main controlling device 110. When the change display is executed and the number of retained balls is subtracted, a retained ball number command indicating the value of the special symbol retained ball number counter 203c after addition or subtraction is transmitted to the voice lamp control device 113.

  When receiving the reserved ball count command transmitted from the main control device 110, the sound ramp control device 113 obtains the value of the special symbol reserved ball count counter 203c of the main control device 110 from the reserved ball count command, and It is stored in the symbol holding ball number counter 223b (see S1308 in FIG. 104). As described above, the voice lamp control device 113 updates the value of the special symbol reserved ball number counter 223b in accordance with the reserved ball number command transmitted from the main control device 110. The value can be updated while synchronizing with 203c.

  The value of the special symbol reserved ball number counter 223b is used for displaying the reserved ball number symbol on the third symbol display device 81. That is, in response to the reception of the reserved ball number command, the sound lamp control device 113 stores the reserved ball number indicated by the command in the special symbol reserved ball number counter 223b, and also stores the stored special symbol reserved ball number counter 223b. Is transmitted to the display control device 114 to notify the display control device 114 of the value.

  When the display control device 114 receives the display reserved ball number command, the value of the reserved ball number indicated by the command, that is, the reserved ball number corresponding to the value of the special symbol reserved ball number counter 223b of the voice lamp control device 113, is displayed. The drawing of the image is controlled so that the symbol is displayed in the lower display area Ds of the third symbol display device 81. As described above, the value of the special symbol reserved ball number counter 223b is changed in synchronization with the special symbol reserved ball number counter 203c of the main controller 110. Therefore, the number of reserved ball count symbols displayed in the lower display area Ds of the third symbol display device 81 can also be changed while synchronizing with the value of the special symbol reserved ball count counter 203c of the main control device 110. . Therefore, the third symbol display device 81 can accurately display the number of the reserved balls for which the variable display is suspended.

  The fluctuation start flag 223c is turned on when a fluctuation pattern command transmitted from the main control device 110 is received (see S1302 in FIG. 104), and turned off when the fluctuation display is set on the third symbol display device 81. (See S1402 in FIG. 105). When the variation start flag 223c is turned on, a variation pattern command for display is set based on the variation pattern extracted from the received variation pattern command.

  The display variation pattern command set here is stored in a command transmission ring buffer provided in the RAM 223, and is included in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the display control device 114. The display control device 114 receives the display variation pattern command, so that the third symbol display device 81 performs the variation display of the third symbol in the variation pattern indicated by the display variation pattern command. The display control of the variable effect is started.

  The stop type selection flag 223d is turned on when a stop type command transmitted from the main control device 110 is received (see S1305 in FIG. 104), and turned off when the stop type is set in the third symbol display device 81. (See S1410 in FIG. 105). When the stop type selection flag 223d is turned on, the stop type (big hit type in the case of a big hit) extracted from the received stop type command is set. Further, the set stop type is notified to the display control device 114 by a display stop type command. The display control device 114 displays the stop effect of the variable effect such that the stop symbol corresponding to the stop type indicated by the display stop type command received from the audio lamp control device 113 is stopped and displayed on the third symbol display device 81. Is controlled.

  The power-off flag 223e is set to ON by receiving a command indicating power failure detection from the main control device 110. Thereafter, in the startup process, when it is determined that the power-off flag 223e is on, the work area of the RAM is cleared and set to off.

  The frame SW valid period 223f is a counter for indicating a period in which the effect based on the operation of the frame button 22 is possible in the effect of the super reach A or the super reach B. This frame SW valid period 223f is set when Super Reach A or Super Reach B is executed, and is executed every 1 ms in the main process of the sound lamp control device 113. SW input monitoring and effect processing (see FIG. 106). Is subtracted by one.

  The replacement timing 223g indicates a timing for replacing with an effect for notifying a jackpot in spite of the fact that the frame button was not pressed in the super reach B. The replacement timing 223g is referred to in the super reach B operation process (see FIG. 109), and is reset based on the number of executions of the effective effect based on the pressing of the frame button 22.

  The replacement flag 223h is set to ON when a replacement effect is set when it is determined that the replacement timing has elapsed in the super reach B operation process (see FIG. 109). Thus, it is determined that the replacement timing has passed once after the replacement effect has been set, thereby preventing the replacement effect from being set again. This replacement flag 223h is turned off (initialized) when the frame SW validity period becomes zero.

  The effect counter 223i is updated in the main process (see FIG. 103) of the sound lamp control device 113. The effect counter 223i selects an effect mode based on the pressing of the frame button 22.

  The other memory area 223z is provided as an area for storing data other than the above-described data, and is an area for temporarily storing other counter values used by the MPU 221 of the audio ramp control device 113.

  The RAM 223 further includes a command storage area (not shown) for temporarily storing a command received from the main control device 110 until a process corresponding to the command is performed. The command storage area is formed by a ring buffer, and data is read and written by a FIFO (First In First Out) method. When the command determination process (see FIG. 104) of the sound ramp processing device 113 is executed, the command stored first among the unprocessed commands stored in the command storage area is read, and the command determination process performs The command is analyzed, and processing according to the command is performed.

  The display control device 114 is connected to the voice lamp control device 113 and the third symbol display device 81, and based on a command received from the voice lamp control device 113, displays the variation of the third symbol on the third symbol display device 81 (variation). Direction) and a continuous announcement effect. Details of the display control device 114 will be described later with reference to FIG.

  The power supply unit 115 includes a power supply unit 251 for supplying power to each unit of the pachinko machine 10, a power failure monitoring circuit 252 for monitoring power interruption due to a power failure or the like, and a RAM provided with a RAM erase switch 122 (see FIG. 3). And an erase switch circuit 253. The power supply unit 251 is a device that supplies a required operating voltage to each of the control devices 110 to 114 and the like via a power supply path (not shown). As an outline, the power supply unit 251 takes in a voltage of AC 24 volts supplied from the outside, and outputs a voltage of 12 volts for driving various switches such as various switches 208, a solenoid such as the solenoid 209, a motor, and the like. A voltage of 5 volts for logic, a backup voltage for RAM backup, and the like are generated, and these 12 volts, 5 volts and backup voltage are supplied to necessary voltages to the control devices 110 to 114 and the like.

  The power failure monitoring circuit 252 is a circuit for outputting a power failure signal SG1 to each NMI terminal of the MPU 201 of the main control device 110 and the MPU 211 of the payout control device 111 when the power is cut off due to the occurrence of a power failure or the like. The power failure monitoring circuit 252 monitors a DC stable voltage of 24 volts, which is the maximum voltage output from the power supply unit 251, and determines that a power failure (power interruption, power interruption) has occurred if this voltage falls below 22 volts. Then, the power outage signal SG1 is output to the main control device 110 and the payout control device 111. Based on the output of the power failure signal SG1, the main control device 110 and the payout control device 111 recognize the occurrence of the power failure and execute the NMI interrupt processing. Note that, even after the DC stable voltage of 24 volts becomes less than 22 volts, the power supply unit 251 outputs the voltage of 5 volts, which is the drive voltage of the control system, for a time sufficient for executing the NMI interrupt processing. Is maintained at a normal value. Therefore, main controller 110 and payout controller 111 can normally execute and complete the NMI interrupt process (see FIG. 98).

  The RAM erasure switch circuit 253 is a circuit for outputting a RAM erasure signal SG2 for clearing the backup data to the main controller 110 when the RAM erasure switch 122 (see FIG. 3) is pressed. The main controller 110 clears the backup data when the RAM erasing signal SG2 is input when the power of the pachinko machine 10 is turned on, and also controls the payout control device 111 to execute a payout initialization command for clearing the backup data. Transmit to the device 111.

  Next, an electrical configuration of the display control device 114 will be described with reference to FIG. FIG. 84 is a block diagram showing an electrical configuration of the display control device 114. The display control device 114 includes an MPU 231, a work RAM 233, a character ROM 234, a resident video RAM 235, a normal video RAM 236, an image controller 237, an input port 238, an output port 239, and bus lines 240 and 241. have.

  The input side of the input port 238 is connected to the output side of the audio lamp control device 113, and the output side of the input port 238 is connected to the MPU 231, the work RAM 233, the character ROM 234, and the image controller 237 via the bus line 240. . The resident video RAM 235 and the normal video RAM 236 are connected to the image controller 237, and an output port 239 is connected via a bus line 241. The third symbol display device 81 is connected to the output side of the output port 239.

  In addition, the pachinko machine 10 is a symbol displayed on the third symbol display device 81, even if it is a different model having different lottery probabilities of special symbol jackpots and different numbers of prize balls paid out in one special symbol jackpot. Since there are models having exactly the same configuration, the display control device 114 is made a common component to reduce costs.

  Hereinafter, the MPU 231, the character ROM 234, the image controller 237, the resident video RAM 235, and the normal video RAM 236 will be described first, and then the work RAM 233 will be described.

  First, the MPU 231 controls the display contents of the third symbol display device 81 based on the display variation pattern command output from the audio lamp control device 113 based on the variation pattern command of the main control device 110. The MPU 231 has a built-in instruction pointer 231a, reads and fetches an instruction code stored at an address indicated by the instruction pointer 231a, and executes various processes according to the instruction code. The MPU 231 is configured to perform a system reset from the power supply device 115 immediately after power-on (including power recovery from a power failure; the same applies hereinafter). When the system reset is released, the instruction pointer 231 a Is automatically set to “0000H” by the hardware of the MPU 231. Each time the instruction code is fetched, the value of the instruction pointer 231a is incremented by one. When the MPU 231 executes an instruction pointer setting instruction, the pointer value specified by the setting instruction is set in the instruction pointer 231a.

  Although details will be described later, in this control example, a control program executed by the MPU 231 and various fixed value data used in the control program are provided in a dedicated program ROM like a conventional gaming machine. Instead, the character data is stored in a character ROM 234 provided to store image data to be displayed on the third symbol display device 81.

  As will be described later in detail, the character ROM 234 is constituted by a NAND flash memory 234a capable of increasing the capacity with a small area. Thereby, not only the image data but also the control program and the like can be sufficiently stored. If a control program and the like are stored in the character ROM 234, there is no need to provide a dedicated program ROM for storing the control program and the like. Therefore, the number of components in the display control device 114 can be reduced, the manufacturing cost can be reduced, and an increase in the failure rate due to an increase in the number of components can be suppressed.

  On the other hand, the NAND flash memory has a problem that the reading speed is reduced particularly when random access is performed. For example, in a case where data arranged continuously on a plurality of pages is read, high-speed reading of data on the second and subsequent pages is possible, but an address is specified for reading data of the first page. It takes a long time from when the data is output until the data is output. In addition, when data that is not continuous is read, a long time is required every time the data is read. As described above, since the reading speed of the NAND flash memory is low, if the MPU 231 is configured to directly read the control program from the character ROM 234 and execute various processes, it takes time to read the instructions constituting the control program. However, even if a high-performance processor is used as the MPU 231, the processing performance of the display control device 114 may be deteriorated.

  Therefore, in the present control example, when the system reset of the MPU 231 is released, first, the control program stored in the NAND flash memory 234a of the character ROM 234 is transferred to the work RAM 233 provided for temporarily storing various data. And store. Then, the MPU 231 executes various processes according to the control program stored in the work RAM 233. The work RAM 233 is constituted by a DRAM (Dynamic RAM), as will be described later, and reads and writes data at a high speed. Therefore, the MPU 231 can read instructions constituting the control program without delay. Therefore, high processing performance can be maintained in the display control device 114, and diversified and complicated effects can be easily executed using the third symbol display device 81.

  The character ROM 234 is a memory that stores a control program executed by the MPU 231 and data of an image displayed on the third symbol display device 81, and is connected to the MPU 231 via the bus line 240. The MPU 231 directly accesses the character ROM 234 via the bus line 240 after the system reset is released, and transfers the control program stored in the second program storage area 234a1 of the character ROM 234 to the program storage area 233a of the work RAM 233. An image controller 237 is also connected to the bus line 240. The image controller 237 stores image data stored in a character storage area 234a2 (described later) of the character ROM 234 into a resident video RAM 235 connected to the image controller 237, The data is transferred to the normal video RAM 236.

  The character ROM 234 is configured by modularizing a NAND flash memory 234a, a ROM controller 234b, a buffer RAM 234c, and a NOR ROM 234d.

  The NAND flash memory 234a is a nonvolatile memory provided as a main storage unit in the character ROM 234, and stores most of the control program executed by the MPU 231 and fixed value data for driving the third symbol display device 81. It has at least a second program storage area 234a1 for storing, and a character storage area 234a2 for storing data of an image (such as a character) to be displayed on the third symbol display device 81.

  Here, the NAND flash memory has a feature that a large storage capacity can be obtained in a small area, and the capacity of the character ROM 234 can be easily increased. Thus, in the present pachinko machine, by using the NAND flash memory 234a having a capacity of, for example, 2 gigabytes, many images can be stored in the character storage area 234a2 as images to be displayed on the third symbol display device 81. it can. Therefore, in order to further enhance the interest of the player, the image displayed on the third symbol display device 81 can be diversified and complicated.

  Further, the NAND flash memory 234a can further store a control program and fixed value data in the second program storage area 234a1 in a state where much image data is stored in the character storage area 234a2. As described above, the control program and the fixed value data are provided for storing the data of the image to be displayed on the third symbol display device 81 without providing and storing the dedicated program ROM as in a conventional gaming machine. Since the number of components in the display control device 114 can be reduced, the manufacturing cost can be reduced, and an increase in the failure rate due to an increase in the number of components can be suppressed.

  The ROM controller 234b is a controller for controlling the operation of the character ROM 234. For example, based on an address transmitted from the MPU 231 or the image controller 237 via the bus line 240, the corresponding data from the NAND flash memory 234a or the like is read. And outputs it to the MPU 231 or the image controller 237 via the bus line 240.

  Here, due to the nature of the NAND flash memory 234a, a relatively large number of error bits (bits in which erroneous data has been written) occur when writing data, or a defective data block in which data cannot be written occurs. Or Therefore, the ROM controller 234b performs a known error correction on the data read from the NAND flash memory 234a, and reads and writes the data to the NAND flash memory 234a while avoiding the defective data block. Executes the conversion of the data address.

  Since the ROM controller 234b performs error correction on the data read from the NAND flash memory 234a including the error bit, even if the NAND flash memory 234a is used as the character ROM 234, the error is corrected based on the erroneous data. Thus, it is possible to prevent the MPU 231 from performing processing and the image controller 237 from generating various images.

  Further, the defective data block of the NAND flash memory 234a is analyzed by the ROM controller 234b, and access to the defective data block is avoided, so that the MPU 231 and the image controller 237 use different defective data for each NAND flash memory 234a. Access to the character ROM 234 can be easily performed without considering the address position of the block. Therefore, even when the NAND flash memory 234a is used as the character ROM 234, it is possible to suppress complicated access control to the character ROM 234.

  The buffer RAM 234c is a memory used as a buffer for temporarily storing data read from the NAND flash memory 234a. When an address allocated to the character ROM 234 is specified from the MPU 231 or the image controller 237 via the bus line 240, the ROM controller 234b operates for one page (for example, 2 kilobytes) including data corresponding to the specified address. Is set in the buffer RAM 234c. If it is not set, the data of one page (for example, 2 kilobytes) including the data corresponding to the designated address is read from the NAND flash memory 234a (or the NOR ROM 234d) and temporarily set in the buffer RAM 234c. I do. Then, the ROM controller 234b performs a known error correction process, and outputs data corresponding to the designated address to the MPU 231 and the image controller 237 via the bus line 240.

  The buffer RAM 234c is composed of two banks, and one bank of data of the NAND flash memory 234a can be set per bank. Accordingly, the ROM controller 234b outputs data of the NAND flash memory 234a to the outside using the other bank while the data is set in one bank, or specifies the data from the MPU 231 or the image controller 237. One page of data including the data corresponding to the specified address is transferred from the NAND flash memory 234a to one bank and set, and the data corresponding to the address specified by the MPU 231 or the image controller 237 is transferred to the other bank. The process of reading out from the bank and outputting it to the MPU 231 and the image controller 237 can be processed in parallel. Therefore, the response in reading the character ROM 234 can be improved.

  The NOR ROM 234d is a non-volatile memory provided as a sub storage unit in the character ROM 234, and has a much smaller capacity (for example, 2 kilobytes) than the NAND flash memory 234a for the purpose of complementing the NAND flash memory 234a. ). In the NOR ROM 234d, among the control programs stored in the character ROM 234, the programs not stored in the second program storage area 234a1 of the NAND flash memory 234a, specifically, the MPU 231 first stores the program after the system reset is released. At least a first program storage area 234d1 for storing a part of the boot program to be executed is provided.

  The boot program is a control program for activating the display control device 114 so that various controls on the third symbol display device 81 can be executed. After the system reset is released, the MPU 231 first executes the boot program. Thus, the display control device 114 can be put into a state in which various controls can be executed. The first program storage area 234d1 has a capacity of one bank of the buffer RAM 234c (that is, one page of the NAND flash memory 234a) of the boot program, and should be processed first by the MPU 231 after the system reset is released. A predetermined number of instructions (for example, if the capacity of one page is 2 kilobytes, instructions for 1024 words (1 word = 2 bytes)) are stored. The number of instructions of the boot program stored in the first program storage area 234d1 only needs to be smaller than the capacity of one bank of the buffer RAM 234c, and is appropriately set according to the specifications of the display control device 114. There may be.

  When the system reset is released, the MPU 231 sets the value of the instruction pointer 231a to “0000H” by hardware and specifies the address “0000H” indicated by the instruction pointer 231a to the bus line 240. It is configured. On the other hand, when the ROM controller 234b of the character ROM 234 detects that the address “0000H” is specified on the bus line 240, the ROM controller 234b stores the boot program stored in the first program storage area 234d1 of the NOR type ROM 234d in one bank of the buffer RAM 234c. And outputs the corresponding data (instruction code) to the MPU 231.

  When the MPU 231 fetches the instruction code received from the character ROM 234, it executes various processes according to the fetched instruction code, adds one to the instruction pointer 231a, and sends the address indicated by the instruction pointer 231a to the bus line 240. To specify. Then, while the address specified by the bus line 240 is an address indicating the program stored in the NOR-type ROM 234d, the ROM controller 234b of the character ROM 234 selects a program from among the programs previously set from the NOR-type ROM 234d to the buffer RAM 234c. , Reads the instruction code at the corresponding address from the buffer RAM 234c, and outputs it to the MPU 231.

  Here, in the present control example, instead of storing the entire control program in the NAND flash memory 234a, a predetermined number of instructions to be processed first by the MPU 231 after the system reset is released are replaced by the NOR ROM 234d in the boot program. Is stored for the following reason. That is, as described above, the NAND flash memory 234a requires a large amount of time from when an address is specified to when data is output in reading data of the first page, which is unique to the NAND flash memory. There's a problem.

  When all the control programs are stored in such a NAND flash memory 234a, the address “0000H” is designated from the MPU 231 via the bus line 240 to fetch the instruction code to be executed first by the MPU 231 after the system reset is released. In this case, the character ROM 234 must read out one page of data including the data (instruction code) corresponding to the address “0000H” from the NAND flash memory 234a and set the data in the buffer RAM 234c. Then, due to the nature of the NAND flash memory 234a, a great amount of time is required from the reading to the setting to the buffer RAM 234c. Therefore, the MPU 231 specifies the address “0000H” and then executes the instruction Spend a lot of time waiting to receive the code. Therefore, since the time required to start the MPU 231 becomes longer, there is a problem that the control of the third symbol display device 81 in the display control device 114 may not be started immediately.

  On the other hand, since the NOR ROM is a memory from which data can be read at high speed, a predetermined number of instructions of the boot program to be processed first by the MPU 231 after the system reset is released are stored in the NOR ROM 234d. When the address “0000H” is designated from the MPU 231 via the bus line 240 after the system reset is released, the character ROM 234 immediately stores the boot program stored in the first program storage area 234d1 of the NOR type ROM 234d in the buffer RAM 234c. And the corresponding data (instruction code) can be output to the MPU 231. Therefore, the MPU 231 can receive the instruction code corresponding to the address “0000H” in a short time after specifying the address “0000H”, and can start the MPU 231 in a short time. Therefore, even if the control program is stored in the character ROM 234 composed of the NAND flash memory 234a having a low reading speed, the control of the third symbol display device 81 in the display control device 114 can be started immediately.

  The boot program is a control program stored in the second program storage area 234a1 of the NAND flash memory 234a, that is, a control program excluding the boot program stored in the first program storage area 234d1 of the NOR ROM 234d, The fixed value data (for example, a display data table, a transfer data table, and the like, which will be described later) used in the control program is stored in a predetermined amount (for example, the capacity of one page of the NAND flash memory 234a) in the program storage area 233a or It is programmed to transfer to the data table storage area 233b. Then, the MPU 231 sets the control program stored in the second program storage area 234a1 according to the boot program read from the first program storage area 234d1 after the system reset is released, and sets the boot program in the first program storage area 234d1. A predetermined amount is transferred to and stored in the program storage area 233a while using a bank different from the bank of the buffer RAM 234c.

  Here, since the boot program stored in the first program storage area 234d1 has a capacity corresponding to one bank of the buffer RAM 234c as described above, the address of the internal bus is designated as "0000H". When the boot program in the first program storage area 234d1 is set in the buffer RAM 234c in response to the setting, the boot program is set in only one bank of the buffer RAM 234c. Therefore, when transferring the control program stored in the second program storage area 234a1 to the program storage area 233a in accordance with the boot program in the first program storage area 234d1, the first program set in one bank of the buffer RAM 234c is used. The transfer process can be executed using the other bank while leaving the boot program in the storage area 234d1. Therefore, it is not necessary to reset the boot program in the first program storage area 234d1 in the buffer RAM 234c after the transfer process, so that the time required for the boot process can be shortened.

  When the control program stored in the second program storage area 234a1 is transferred to the program storage area 233a by a predetermined amount, the boot program stored in the first program storage area 234d1 moves the instruction pointer 231a into the program storage area 233a. It is programmed to set to the first predetermined address. Thus, after the system reset is released, when the control program stored in the second program storage area 234a1 by the MPU 231 is transferred to the program storage area 233a by a predetermined amount, the instruction pointer 231a moves to the first predetermined area of the program storage area 233a. The address is set.

  Therefore, when a predetermined amount of programs among the control programs stored in the second program storage area 234a1 is stored in the program storage area 233a, the MPU 231 reads out the control program stored in the program storage area 233a, Various processes can be executed. That is, the MPU 231 does not read out the control program from the NAND flash memory 234a having the second program storage area 234a1 and fetches the instruction, but reads out the control program transferred to the work RAM 233 having the program storage area 233a and fetches the instruction. Then, various processes are executed. As will be described later, the work RAM 233 is constituted by a DRAM, so that a high-speed read operation is performed. Therefore, even when most of the control program is stored in the NAND flash memory 234a having a low reading speed, the MPU 231 can fetch an instruction at high speed and execute processing for the instruction.

  Here, the control programs stored in the second program storage area 234a1 include the remaining boot programs not stored in the first program storage area 234d1. On the other hand, the boot programs stored in the first program storage area 234d1 include the remaining boot programs in the control programs transferred from the second program storage area 234a1 by a predetermined amount to the program storage area 233a of the work RAM 233. The program is programmed so as to be included, and the instruction pointer 231a is set such that the start address of the remaining boot program stored in the program storage area 233a is the first predetermined address.

  Accordingly, the MPU 231 transfers the control program stored in the second program storage area 234a1 by a predetermined amount to the program storage area 233a by the boot program stored in the first program storage area 234d1, and then transfers the control program. Execute the remaining boot program included in the control program.

  In the remaining boot programs, all of the remaining control programs not transferred to the program storage area 233a and fixed value data (for example, a display data table and a transfer data table described later) used in the control programs are stored in the second program storage. A process of transferring a predetermined amount from the area 234a1 to the program storage area 233a or the data table storage area 233b is executed. At the end of the boot program, the instruction pointer 231a is set to a second predetermined address in the program storage area 233a. Specifically, the start address of the program corresponding to the boot processing by the boot program (see S1901 in FIG. 111) stored in the program storage area 233a is set as the second predetermined address.

  By executing the remaining boot program, the MPU 231 transfers all control programs and fixed value data stored in the second program storage area 234a1 to the program storage area 233a or the data table storage area 233b. When the boot program is executed to the end by the MPU 231, the instruction pointer 231a is set to the second predetermined address. Thereafter, the MPU 231 is transferred to the program storage area 233a without referring to the NAND flash memory 234a. Various processes are executed using the control program.

  Therefore, even when most of the control programs are stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, the control programs are transferred to the program storage area 233a of the work RAM 233 after the system reset is released. Thus, the MPU 231 can perform various controls by reading the control program from the work RAM constituted by a DRAM having a high read speed. Therefore, high processing performance can be maintained in the display control device 114, and diversified and complicated effects can be easily executed using the third symbol display device 81.

  Further, as described above, without storing all the boot programs in the NOR ROM 234d, a predetermined number of instructions to be processed first by the MPU 231 after the system reset is released are stored, and for the remaining boot programs, Even when the control program is stored in the second program storage area 234a1 of the NAND flash memory 234a, the control program stored in the second program storage area 234a1 can be reliably transferred to the program storage area 233a. Therefore, the character ROM 234 can start the MPU 231 in a short time only by adding the NOR-type ROM 234d having a very small capacity. Can be.

  The image controller 237 is a digital signal processor (DSP) that draws an image and displays the drawn image on the third symbol display device 81 at a predetermined timing. The image controller 237 draws an image for one frame based on a drawing list (see FIG. 91) described later transmitted from the MPU 231 and outputs one of the frames of a first frame buffer 236b and a second frame buffer 236c described later. The image drawn in the buffer is expanded, and the image information of one frame previously expanded in the other frame buffer is output to the third symbol display device 81, thereby displaying the image on the third symbol display device 81. . The image controller 237 performs this one-frame image drawing process and one-frame image display process for one frame of image display time on the third symbol display device 81 (20 milliseconds in this control example). In parallel.

  The image controller 237 transmits a vertical synchronization interrupt signal (hereinafter, referred to as a “V interrupt signal”) to the MPU 231 every 20 milliseconds when the rendering processing of the image for one frame is completed. Each time the MPU 231 detects the V interrupt signal, it executes a V interrupt process (see FIG. 112B) and instructs the image controller 237 to draw an image for the next one frame. In response to this instruction, the image controller 237 executes a process of drawing the next one frame of image and a process of displaying the image developed by the drawing on the third symbol display device 81.

  As described above, the MPU 231 executes the V interrupt processing in accordance with the V interrupt signal from the image controller 237 and issues a drawing instruction to the image controller 237. Therefore, the image controller 237 performs the image drawing processing and display. An image drawing instruction can be received from the MPU 231 at each processing interval (20 milliseconds). Therefore, the image controller 237 does not receive a drawing instruction of the next image at a stage where the image drawing processing or the display processing is not completed, so that the image controller 237 starts drawing a new image during drawing of the image, It is possible to prevent an image from being developed in a frame buffer in which image information being displayed is stored in accordance with a new drawing instruction.

  The image controller 237 also executes processing for transferring image data from the character ROM 234 to the resident video RAM 235 or the normal video RAM 236 based on a transfer instruction from the MPU 231 and transfer data information included in the drawing list.

  The image is drawn using the image data stored in the resident video RAM 235 and the normal video RAM 236. That is, the image data necessary for drawing is transferred from the character ROM 234 to the resident video RAM 235 or the normal video RAM 236 based on an instruction from the MPU 231 before the drawing is performed.

  Here, the NAND flash memory facilitates increasing the capacity of the ROM, but has a lower read speed than other ROMs (such as a mask ROM and an EEPROM). On the other hand, in the display control device 114, the MPU 231 instructs the image controller 237 to transfer a part of the image data stored in the character ROM 234 to the resident video RAM 235 after turning on the power. It is configured to be. Then, as described later, the image data stored in the resident video RAM 235 is controlled to be resident without being overwritten.

  Thereby, after the transfer of the image data to be resident in the resident video RAM 235 after the power is turned on, the image controller 237 draws the image while using the image data resident in the resident video RAM 235. Processing can be performed. Therefore, if the image data used for the drawing process is resident in the resident video RAM 235, it is not necessary to read the corresponding image data from the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed when drawing an image. The time required for the reading can be omitted, and the image can be drawn immediately and the drawn image can be displayed on the third symbol display device 81.

  In particular, in the resident video RAM 235, image data of frequently displayed images and image data of images to be displayed immediately after the display is determined by the main control device 110 or the display control device 114 are resident. Even if the character ROM 234 is configured by the NAND flash memory 234a, the responsiveness until a certain image is displayed on the third symbol display device 81 can be kept high.

  Further, when drawing an image using non-resident image data in the resident video RAM 235, the display control device 114 needs to perform drawing from the character ROM 234 to the normal video RAM 236 before the drawing is performed. The MPU 231 is configured to instruct the image controller 237 to transfer image data. As will be described later, the image data transferred to the normal video RAM 236 may be deleted by overwriting after being used for drawing an image. It is not necessary to read out the corresponding image data from the character ROM 234 composed of, and the time required for reading out the image data can be omitted. Therefore, it is possible to immediately draw the image and display the drawn image on the third symbol display device 81. it can.

  Further, since the image data is also stored in the normal video RAM 236, it is not necessary to keep all the image data resident in the resident video RAM 235. Therefore, it is not necessary to prepare a large-capacity resident video RAM 235. Therefore, an increase in cost due to the provision of the resident video RAM 235 can be suppressed.

  The image controller 237 has a buffer RAM 237a composed of a 132 kilobyte SRAM which is the capacity of one block of the NAND flash memory 234a.

  The transfer instruction of the image data performed by the MPU 231 to the image controller 237 based on the transfer instruction or the transfer data information of the drawing list includes the start address (storage source start address) of the character ROM 234 in which the image data to be transferred is stored. Last address (storage source final address), transfer destination information (information indicating to which of the resident video RAM 235 and the normal video RAM 236 to transfer), and the beginning of the transfer destination (the resident video RAM 235 or the normal video RAM 236) Contains the address. The data size of the image data to be transferred may be included in place of the storage source final address.

  The image controller 237 reads one block of data from a predetermined address of the character ROM 234 and temporarily stores the data in the buffer RAM 237a in accordance with the various information of the transfer instruction. When the resident video RAM 235 or the normal video RAM 236 is not used, the buffer RAM 237a Is transferred to the resident RAM 235 or the normal video RAM 236. Then, the processing is repeatedly executed until all the image data stored from the storage source start address indicated by the transfer instruction to the storage source end address is transferred.

  As a result, the image data read from the character ROM 234 over time is temporarily stored in the buffer RAM 237a, and then the image data is transferred from the buffer RAM 237a to the resident video RAM 235 or the normal video RAM 236 in a short time. Can be. Therefore, while the image data is transferred from the character ROM 234 to the resident video RAM 235 or the normal video RAM 236, the resident video RAM 235 or the normal video RAM 236 is prevented from being occupied for a long time by the transfer of the image data. be able to. Therefore, since the resident video RAM 235 and the normal video RAM 236 are occupied by the transfer of the image data, the video RAMs 235 and 236 cannot be used for the image drawing processing. In addition, it is possible to prevent the display on the third symbol display device 81 from being missed.

  Further, the transfer of the image data from the buffer RAM 234c to the resident video RAM 235 or the normal video RAM 236 is performed by the image controller 237. It is possible to easily determine a period that is not used for display processing on the device 81, and to simplify the processing.

  The resident video RAM 235 is used so that the image data transferred from the character ROM 234 is maintained without being overwritten while the power is turned on. The power-on main image area 235a, the rear image area 235c, and the character design area are used. 235e, an error message image area 235f, and at least a power-on fluctuation image area 235b and a third symbol area 235d.

  The power-on main image area 235a stores a power-on main image displayed on the third symbol display device 81 from when the power is turned on to when all image data to be resident in the resident video RAM 235 is stored. An area for storing corresponding data. Further, in the power-on fluctuation image area 235b, the game is started by the player while the power-on main image is displayed on the third symbol display device 81, and the entrance to the first winning port 64 is detected. This is an area for storing image data corresponding to a power-on fluctuation image in which the result of the lottery performed in the main control device 110 is displayed in a fluctuation effect when the power control is performed.

  The MPU 231 transfers the image data corresponding to the power-on main image and the power-on fluctuation image from the character ROM 234 to the power-on main image area 235a when the power supply from the power supply unit 251 is started. A transfer instruction is transmitted to the controller 237 (see S1803 and S1804 in FIG. 40). The power-on main image is an image displayed on the third symbol display device 81 immediately after power-on, while image data to be stored in the resident video RAM 235 is being transferred from the character ROM 234, This is a simple image with a smaller amount of data than an image displayed during a normal game. Therefore, the image data can be transferred quickly after the power is turned on, and the image can be displayed.

  During display of the main image at power-on, when a display variation pattern command transmitted from the sound lamp control device 113 is received based on a variation pattern command from the main control device 110 which is a variation start instruction command, the display control device 114 On the power-on main image display screen, the power-on fluctuation image of the “○” symbol in the lower right position toward the screen and the “×” symbol in the same position as the “○” symbol when the power is turned on The change image is alternately and repeatedly displayed during the change period. Then, based on the fluctuation pattern command and the stop type command from the main controller 110, the display fluctuation pattern command and the display stop type command transmitted from the sound lamp controller 113 are used to determine the lottery performed by the main controller 110. Judging the result, if it is a "special symbol jackpot", display the "○" symbol for a fixed period after stopping the variable effect, and if it is "special symbol loss", display the "x" symbol after the variable effect stops Display for a certain period.

  The MPU 231 uses the image data stored in the power-on main image area 235a to the image controller 237 until all image data to be resident in the resident video RAM 235 is transferred to the resident video RAM 235. Instructs the main image to be drawn at power-on. Thereby, while the remaining image data to be resident is transferred to the resident video RAM 235, the player or the person in charge of the hall can check the power-on main image displayed on the third symbol display device 81. it can. Accordingly, the display control device 114 transfers the remaining image data to be resident from the character ROM 234 to the resident video RAM 235 over time while displaying the main image at power-on on the third symbol display device 81. be able to. Further, the player or the like can recognize that some processing is being performed while the power-on main image is displayed on the third symbol display device 81, so that the remaining images to be resident in the resident video RAM 235 are displayed. Until the data is transferred from the character ROM 234 to the resident video RAM 235, it is necessary to wait until the transfer of the image data to the resident video RAM 235 is completed without worrying that the operation has not stopped. Can be.

  Also, in an operation check at a factory or the like at the time of manufacturing, the main image at the time of turning on the power is immediately displayed on the third symbol display device 81, so that the operation of the third symbol display device 81 is started without any problem by turning on the power. Can be immediately confirmed, and the use of the NAND flash memory 234a having a low reading speed as the character ROM 234 can prevent the efficiency of the operation check from deteriorating.

  Further, when the player starts the game while the main image at power-on is displayed on the third symbol display device 81 and a ball is detected at the first entrance ball 64, the power-on fluctuation image area The power-on fluctuation image is drawn using the image data corresponding to the power-on fluctuation image resident at 235b, and the "O" symbol and the "X" symbol are alternately displayed on the third symbol display device 81. Thus, the MPU 231 instructs the image controller 237. Thus, a simple fluctuation effect can be performed using the power-on fluctuation image. Therefore, even when the main image is displayed on the third symbol display device 81 when the power is turned on, the player can surely confirm that the lottery has been performed by the simple variable effect.

  When the main image at the time of power-on is displayed on the third symbol display device 81, the image data corresponding to the power-on fluctuation image is already resident in the power-on fluctuation image area 235b. If a ball is detected in the first entrance ball 64 while the time main image is displayed on the third symbol display device 81, the corresponding variable effect can be immediately displayed on the third symbol display device 81. it can.

  Returning to FIG. 16, the description will be continued. The back image area 235c is an area for storing image data corresponding to the back image displayed on the third symbol display device 81. Here, with reference to FIG. 88, the back image and the range of the back image stored in the back image area 235c among the back images will be described. FIG. 88 is an explanatory diagram for explaining two types of back images and the range of the back images stored in the back image area 235c of the resident video RAM 235 for each back image. FIG. FIG. 88 (b) shows the back surface A corresponding to the "sky stage" and the back surface A corresponding to the "sky stage".

  As shown in FIG. 88, as the back images corresponding to the back surfaces A and B, images that are longer in the horizontal direction than the display area displayed on the third symbol display device 81 are prepared in the character ROM 234. The image controller 237 draws the image such that the rear image is displayed on the third symbol display device 81 while scrolling the image horizontally from left to right.

  The images prepared on each of the back surfaces A and B (hereinafter, referred to as “scroll images”) are configured such that the back images are continuous at the positions a and c. The image between the position c and the position d and the image between the position a and the position a ′ are composed of images corresponding to the horizontal width of the display area, and are images between the position c and the position d. Is displayed on the third symbol display device 81 as a display area, and then the image between the position a and the position a ′ is displayed on the third symbol display device 81 as a display area. The back image is scroll-displayed with a proper connection.

  When the player operates the frame button 22 to change the stage to the “city stage” or the “empty stage”, the MPU 231 changes the initial position of the display area from the first position a to the position a ′ of the corresponding rear image. The image controller 237 is controlled so that the image at the initial position is displayed on the third symbol display device 81. Then, as time passes, the display area is moved from left to right with respect to the scroll image, and the image controller 237 is controlled so that the display area is sequentially displayed on the third symbol display device 81. When the area reaches the image between the position c and the position d, the image controller 237 is controlled so that the display area is displayed again on the third symbol display device 81 as the image from the position a to the position a ′. Therefore, on the third symbol display device 81, the image between the positions a to c can be repeatedly scrolled and displayed with a smooth connection so as to flow toward the left.

  On the other hand, unlike the above-described back surface A and back surface B, the back image (not shown) used for the super background notice is an image that can be scroll-displayed not only in the horizontal direction but also in the vertical direction. Thereby, scroll display in the horizontal direction or the vertical direction is possible. Further, the image used for the super background notice can be scroll-displayed and includes an image that changes with the passage of time. Thus, a display in which the specific image (image of the door) blinks for a predetermined time can be executed.

  Next, in each back image, the range of the back image stored in the back image area 235c will be described. As shown in FIG. 88 (a), the back surface A corresponding to the street stage which is the initial stage has the entire range of the back surface A, that is, all the image data corresponding to the positions a to d are the back surface of the resident video RAM 235. It is stored in the image area 235c. Normally, a game is often performed without changing the stage while the city stage, which is the initial stage, is displayed. Therefore, all the image data of the back A corresponding to the city stage, which is frequently displayed, is displayed in the rear image area. By making the character ROM 234 resident, the number of data accesses to the character ROM 234 can be reduced, and the load on the display control device 114 can be reduced.

  On the other hand, as shown in FIG. 88 (b), the back surface B corresponding to the empty stage stores only a part of the back surface, that is, only the image data corresponding to the image between the position a and the position b in the resident video RAM 235. Is stored in the back image area 235c.

  Here, since the operation of the frame button 22 performed by the player to change the stage is performed at an arbitrary timing based on the intention of the player, even if the frame button 22 is operated at an arbitrary timing. In order to immediately change the rear image, it is ideal that the entire range of image data for all the rear images is resident in the resident video RAM 235. A large capacity RAM must be used, which may lead to an increase in cost.

  On the other hand, in the present pachinko machine 10, the initial position of the rear image displayed first when the stage is changed is fixed in a range from the position a to the position a ', and the position is shifted from the position a including the initial position to the position a'. Since the image during b is stored in the rear image area 235c of the resident video RAM 235, even if the character ROM 234 is configured by the NAND flash memory 234a having a low reading speed, the character ROM 234 can be arbitrarily operated by the player operating the frame button 22. When the stage is changed at the timing of (3), the image data resident in the back image area 235c of the resident video RAM 235 is used to immediately set the initial position of the back B or back C to the third symbol display device 81. Can be displayed on a scrolling display or changing the color tone over time. It is possible. In addition, since only the image data corresponding to the image in the partial range is stored for the rear surface B and the rear surface C, an increase in the storage capacity of the resident video RAM 235 can be suppressed, and an increase in cost can be suppressed.

  After the image at the initial position is displayed, the rear surface B scrolls the range from position a to position b from left to right using the image data resident in the rear image area 235c of the resident video RAM 235. The range from the position a to the position b is set so that the image data corresponding to the images from the position b ′ to the position d can be transferred from the character ROM 234 to the normal RAM 236 during the operation. As a result, the image data from the position b ′ to the position d can be transferred to the normal video RAM 236 while scrolling the range from the position a to the position b, so that the image data stored in the rear image area 235c of the resident video RAM 235 can be After scrolling the range from position a to position b using the image data corresponding to the back image stored in the normal video RAM 236 without delay, the range from position b ′ to position d is scrolled. It can be displayed on the symbol display device 81.

  On the rear surface B, the image data stored in the normal video RAM 236 is stored in a sub-area dedicated to the rear image provided in the image storage area 236a (see FIG. 84) of the normal video RAM 236. Thus, the rear image data stored in the sub-area dedicated to the rear image is not overwritten by other image data, so that the rear image can be reliably displayed.

  On the back surface B, the image data stored in the back image area 235c of the resident video RAM 235 and the image data stored in the normal video RAM 236 correspond to the image corresponding to the image between the position b ′ and the position b. Data is stored redundantly. Then, under the control of the image controller 237 by the MPU 231, the image up to the position “b” is displayed on the third symbol display device 81 using the image data stored in the rear image area 235 c of the resident video RAM 235, and then the normal video By displaying the image from the position b 'on the third symbol display device 81 using the image data stored in the RAM 236, the rear image is scroll-displayed with a smooth connection to the third symbol display device 81. ing.

  Further, when the MPU 231 controls the image controller 237 so that the image between the position c and the position d is displayed as a display area on the third symbol display device 81 using the image data of the normal video RAM 236, The MPU 231 controls the image controller 237 so that the image between the position a and the position a 'is displayed as a display area on the third symbol display device 81 using the image data of the rear image area 235c of the resident video RAM 235. I do. This allows the third symbol display device 81 to repeatedly scroll and display the images between the positions a to c so as to flow leftward.

  Returning to FIG. 84, the description will be continued. The third symbol area 235d is an area where the third symbol used in the variable effect displayed on the third symbol display device 81 is resident. That is, in the third symbol area 235d, the image data corresponding to the above-mentioned main symbol, which is the number of the third symbol “0” to “9”, is resident. Thus, when performing a fluctuation effect on the third symbol display device 81, it is not necessary to read out the image data from the character ROM 234 every time. Therefore, even if the NAND flash memory 234a is used for the character ROM 234, A fluctuating effect can be started quickly. Therefore, after the ball enters the first winning opening 64, the variable effect is not immediately started on the third symbol display device 81 even though the variable effect is started on the first symbol display device 37. The occurrence of such a state can be suppressed.

  Further, in the third symbol area 235d, image data corresponding to the main symbol without numbers “0” to “9” is also resident. These image data are used for a demonstration effect displayed on the third symbol display device 81 when the next variable effect associated with the start winning is not started even if a predetermined time has elapsed after one variable effect has stopped. Can be Thus, when the demonstration effect is displayed on the third symbol display device 81, a main symbol without a number is displayed as the third symbol in the demonstration effect. Therefore, the player can easily recognize that the pachinko machine 10 is in the demonstration state by visually recognizing the main symbol without a number from the display image of the third symbol display device 81.

  The character symbol area 235e is an area for storing image data corresponding to character symbols used in various effects displayed on the third symbol display device 81. In this pachinko machine 10, various characters including "girl" are displayed in accordance with various effects, and data corresponding to these characters is resident in the character design area 235e, thereby controlling display. When changing the character design based on the content of the command received from the audio lamp control device 113, the device 114 does not newly read out the corresponding image data from the character ROM 234, but instead stores the corresponding image data in the character design area 235e of the resident video RAM 235. By reading out the resident image data, the image controller 237 can draw a predetermined image. As a result, it is not necessary to read the corresponding image data from the character ROM 234. Therefore, even if the NAND flash memory 234a having a low reading speed is used as the character ROM 234, the character pattern can be changed immediately.

  The error message image area 235f is an area for storing image data corresponding to an error message displayed when an error occurs in the pachinko machine 10. In the present pachinko machine 10, for example, when the sound lamp control device 113 detects vibration from the output of a vibration sensor (not shown) attached to the back of the game board 13, the sound lamp control device 113 detects the occurrence of the vibration error. The display control device 114 is notified by an error command. Also, when the occurrence of another error is detected by the sound lamp control device 113, the sound lamp control device 113 notifies the display control device 114 of the occurrence of the error together with the error type by an error command. Upon receiving the error command, the display control device 114 is configured to display an error message corresponding to the received error on the third symbol display device 81.

  Here, the error message is required to be displayed almost simultaneously with the occurrence of the error, from the viewpoint of preventing the player from cheating and protecting the player against the error. In the present pachinko machine 10, since image data corresponding to various error messages is resident in the error message image area 235f in advance, the display control device 114 determines the error message in the resident video RAM 235 based on the received error command. By reading out the image data previously resident in the image area 235f, the image controller 237 can immediately draw each error message image. As a result, it is not necessary to sequentially read out the image data corresponding to the error message from the character ROM 234. Therefore, even if the NAND flash memory 234a having a low reading speed is used as the character ROM 234, the error message corresponding to the error message is received. It can be displayed immediately.

  The normal video RAM 236 is used so that data is overwritten and updated at any time, and is provided with at least an image storage area 236a, a first frame buffer 236b, and a second frame buffer 236c.

  The image storage area 236a is an area for storing image data that is not resident in the resident video RAM 235 among image data necessary for drawing an image to be displayed on the third symbol display device 81. The image storage area 236a is divided into a plurality of sub-areas, and the type of image data stored in the sub-area is predetermined for each sub-area.

  The MPU 231 transfers, from the image data that is not resident in the resident video RAM 235, image data necessary for drawing an image thereafter, from the character ROM 234 to the sub area provided in the image storage area 236 a of the normal video RAM 236. , And instructs the image controller 237 to transfer the type of the image data to a predetermined sub-area to be stored. Accordingly, the image controller 237 reads the image data specified by the MPU 231 from the character ROM 234, and transfers the read image data to a specified sub-area of the image storage area 236a via the buffer RAM 237a.

  The transfer instruction of the image data is performed by including the transfer data information in a later-described drawing list in which the MPU 231 instructs the image controller 237 to draw the image. Thus, the MPU 231 can issue an image drawing instruction and an image data transfer instruction only by transmitting the drawing list to the image controller 237, so that the processing load can be reduced.

  The first frame buffer 236b and the second frame buffer 236c are buffers for developing an image to be displayed on the third symbol display device 81. The image controller 237 writes an image for one frame drawn in accordance with an instruction from the MPU 231 into one of the first frame buffer 236b and the second frame buffer 236c, thereby writing the image for one frame into the frame buffer. While the image is being developed, while the image is being developed in one of the frame buffers, the image information for one frame that has been previously developed is read out from the other frame buffer, and the readout signal is sent to the third symbol display device 81 together with the drive signal. By transmitting the image information, the third symbol display device 81 executes a process of displaying the image for one frame.

  As described above, by providing the first frame buffer 236b and the second frame buffer 236c as the frame buffers, the image controller 237 simultaneously develops the image for one frame drawn in one frame buffer while developing the image. The image of one frame that has been developed first is read from the other frame buffer, and the read image of one frame can be displayed on the third symbol display device 81.

  The frame buffer for expanding the image for one frame and the frame buffer for reading the image information for one frame to display the image on the third symbol display device 81 are different from each other. Every 20 milliseconds to be completed, the MPU 231 alternately specifies one of the first frame buffer 236b and the second frame buffer 236c.

  That is, at a certain timing, the first frame buffer 236b is specified as a frame buffer for developing an image of one frame, and the second frame buffer 236c is specified as a frame buffer from which image information of one frame is read. When the drawing process and the display process are executed, the second frame buffer 236c is designated as a frame buffer for developing the image of one frame 20 ms after the completion of the drawing process of the image of one frame, The first frame buffer 236b is designated as the frame buffer from which the image information is read. Thereby, the image information of the image previously developed in the first frame buffer 236b can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the second frame buffer 236c. You.

  Then, after the next 20 milliseconds, the first frame buffer 236b is designated as a frame buffer for developing an image of one frame, and the second frame buffer 236c is designated as a frame buffer from which image information of one frame is read. Is done. As a result, the image information of the image previously developed in the second frame buffer 236c can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the first frame buffer 236b. You. Thereafter, the frame buffer for expanding the image for one frame and the frame buffer from which the image information for one frame is read out are changed to one of the first frame buffer 236b and the second frame buffer 236c every 20 milliseconds. By alternately specifying the images, it is possible to continuously perform the display processing of the image of one frame in units of 20 milliseconds while performing the drawing processing of the image of one frame.

  The work RAM 233 is a memory for storing control programs and fixed value data stored in the character ROM 234, and for temporarily storing work data and flags used when the MPU 231 executes various control programs. It is composed of a DRAM. The work RAM 233 includes a program storage area 233a, a data table storage area 233b, a simple image display flag 233c, a display data table buffer 233d, a transfer data table buffer 233e, a pointer 233f, a drawing list area 233g, a clock counter 233h, and stored image data determination. Flag 233i, drawing buffer flag 233j, winning information storage area 233k, game state storage area 233m, fluctuation history storage area 233n, display effect counter 233o, continuation counter 233p, back image change flag 233q, super background flag 233r, map storage area 233s, a mass setting table storage area 233t, a mass event storage area 233u, a route history storage area 233w, a background addition flag 233x, and the number of times of change in the door At least it has a counter 233y.

  The program storage area 233a is an area for storing a control program executed by the MPU 231. When the system reset is released, the MPU 231 reads out the control program from the character ROM 234, transfers it to the work RAM 233, and stores it in the program storage area 233a. When all the control programs are stored in the program storage area 233a, the MPU 231 thereafter executes various controls using the control programs stored in the program storage area 233a. As described above, since the work RAM 233 is configured by a DRAM, a high-speed read operation is performed. Therefore, even when the control program is stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, high processing performance can be maintained in the display control device 114, and the third symbol display device 81 , It is possible to easily execute diversified and complicated effects.

  The data table storage area 233b includes a display data table that describes display contents to be displayed on the third symbol display device 81 with the passage of time for one effect to be displayed based on a command from the main control device 110, and a display data table. This area stores transfer data information of image data that is not resident in the resident video RAM 235 among image data used in one effect displayed by the table and a transfer data table defining transfer timing.

  These data tables are usually stored as a type of fixed value data in a second program storage area 234a1 provided in the NAND flash memory 234a of the character ROM 234, and according to a boot program executed by the MPU 231 after the system reset is released. These data tables are transferred from character ROM 234 to work RAM 233 and stored in data table storage area 233b. Then, when all the data tables are stored in the data table storage area 233b, the MPU 231 thereafter controls the display of the third symbol display device 81 using the data tables stored in the data table storage area 233b. As described above, since the work RAM 233 is configured by a DRAM, a high-speed read operation is performed. Therefore, even when various data tables are stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, high processing performance can be maintained in the display control device 114. By using 81, diversified and complicated effects can be easily executed.

  Here, details of various data tables will be described. First, one display data table is prepared for each effect mode of each effect displayed on the third symbol display device 81 based on a command from the main control device 110. For example, a variable effect, an opening effect A display data table corresponding to a round effect, an ending effect, and a demonstration effect is prepared.

  The fluctuation effect is an effect started on the third symbol display device 81 when a display fluctuation pattern command is received from the audio lamp control device 113. When the display variation pattern command is received, the display stop type command indicating the variation effect stop type is also received. For example, when the fluctuation effect is started, if the stop type of the fluctuation effect is out, the stop symbol indicating the deviation is finally stopped and displayed, while the stop type of the fluctuation effect is the jackpot A to D. In any case, the stop symbols indicating the respective jackpots are finally stopped and displayed. The player can recognize the jackpot type by visually recognizing the stop symbols in the variable effect, and can easily determine the game value given according to the jackpot type.

  The opening effect is an effect for notifying the player that the pachinko machine 10 will be shifted to the special game state and the specific winning port 65a which is normally closed will be repeatedly opened, and the round effect will be performed in the future. This is an effect for notifying the player of the number of rounds to be started. The ending effect is an effect for notifying the player of the end of the special game state. As described above, the demonstration effect is an effect displayed on the third symbol display device 81 when the next variable effect associated with the start winning is not started even after a predetermined time has elapsed after one variable effect has stopped. In this case, the third symbol is not displayed, and the rear image changes. If the demonstration effect is displayed on the third symbol display device 81, the player or the person related to the hall can recognize that the game is not performed in the pachinko machine 10.

  The data table storage area 233b stores a variable effect, an opening effect, a round effect, an ending effect, a confirmed display effect, and a demonstration effect. Here, the details of the data table storage area 233b will be described with reference to FIG. FIG. 86 is a schematic diagram schematically showing the contents of the data table storage area 233b.

  First, in the data table storage area 233b, a variable effect table storage area corresponding to the variable effect, an opening effect table storage area corresponding to the opening effect, a round effect table storage area corresponding to the round effect, and an ending effect are provided. An ending effect table storage area corresponding to the final display effect, a final display effect table storage area corresponding to the final display effect, and a demonstration effect table storage area corresponding to the demonstration effect are provided.

  Here, in the fluctuating effect table storage area, various fluctuating effect display data tables for executing a normal fluctuating effect, and various stop display data data tables for executing a stop display are provided. Various display data tables for Super Reach A for executing Super Reach A described above are provided. Further, there are provided various display data tables for super reach B for executing the above-described super reach B, and various display data tables for throw display for executing effective effects used in the effect of super reach B. And various display data tables for displaying false throws for performing a false effect, and various display data tables for displaying replacement for performing a replacement effect are provided.

  Further, in other opening effect table storage areas and the like, a plurality of types of display data tables corresponding to the respective effects are provided.

  Next, details of the display data table will be described with reference to FIG. FIG. 89 is a schematic diagram schematically showing an example of the variable display data table among the display data tables. The display data table should be displayed at the time corresponding to an address in which the time (20 milliseconds in the present control example) in which the image of one frame is displayed on the third symbol display device 81 is defined as one unit. The content (drawing content) of an image for one frame is defined in detail.

  In the drawing content, the type of the sprite is defined for each sprite that is a display object constituting an image for one frame, and the display position coordinates, the enlargement ratio, the rotation angle, the translucency, and the like are determined according to the type of the sprite. Drawing information, such as a value, α blending information, color information, and filter designation information, for drawing a sprite on the third symbol display device 81 is defined.

  The sprite type is information for specifying a sprite to be displayed. The display position coordinates are information for specifying the coordinates on the third symbol display device 81 at which the sprite is to be displayed. The enlargement ratio is information for specifying an enlargement ratio for a standard display size preset for the sprite, and the size of the sprite to be displayed is specified according to the enlargement ratio. If the enlargement ratio is larger than 100%, the sprite is displayed in an enlarged scale than the standard size. If the enlargement ratio is smaller than 100%, the sprite is reduced in size from the standard size. Is displayed.

  The rotation angle is information for specifying the rotation angle when the sprite is rotated and displayed. The translucent value is for specifying the transparency of the entire sprite, and the higher the translucent value, the more the image displayed on the back side of the sprite is displayed. The α blending information is information for specifying a known α blending coefficient used when performing a superimposition process with another sprite. The color information is information for specifying a color tone of a sprite to be displayed. The filter designation information is information for designating an image filter to be applied to the designated sprite when drawing the designated sprite.

  In the variation display data table, one back image, nine third symbols (symbol 1, symbol 2,...), And one light image For each sprite, drawing information for each sprite such as an effect expressing insertion of characters and characters used for various effects such as boy images and characters is defined for each address. One or more pieces of information on effects and characters are defined in accordance with the content to be displayed in the frame.

  Here, the display position of the rear image is fixed to the entire screen of the third symbol display device 81, and the magnification, the rotation angle, the translucent value, the α blending information, the color information, and the filter designation information are set with respect to the elapse of time. Since it is fixed, only the rear type, which is information for specifying the type of the rear image, is specified in the variable display data table. This back type indicates whether to display any of the back surfaces A to C corresponding to the stage (one of the “city stage”, “empty stage”, and “island stage”) selected by the player, or Information specifying whether to display a back image different from C (for example, an image corresponding to the super background notice effect) is described. In addition, when specifying to display a rear image different from the rear surfaces A to C, the rear type also includes information for specifying which rear image is to be displayed.

  If it is specified by the back type that any of the backs A to C is to be displayed, the MPU 231 specifies the back image corresponding to the stage specified by the player among the backs A to C as a drawing target. Also, the range of the back image to be displayed for the frame is specified as time passes. On the other hand, when it is specified that a back image different from the back surfaces A to C is to be displayed, the back image to be displayed is specified based on the back type.

  In this control example, a case will be described in which only the back type is defined as the drawing content of the back image in the display data table. Instead, the back type and the range of the May be defined as position information indicating whether or not to be displayed. The position information may be, for example, information indicating an elapsed time from when the rear image in the range corresponding to the initial position is displayed. In this case, the MPU 231 specifies the range of the rear image to be displayed for the frame based on the elapsed time from when the rear image in the range corresponding to the initial position indicated by the position information is displayed.

  Further, the position information may be information indicating an elapsed time from the start of drawing of an image based on the display data table (or display of the third symbol display device 81). In this case, the MPU 231 displays the range of the back image to be displayed for the frame at the stage when the drawing of the image (or the display of the third symbol display device 81) is started based on the display database. It is specified based on the position of the back image and the elapsed time from the start of drawing of the image indicated by the position information (or the display of the third symbol display device 81).

  Further, the position information includes information indicating the elapsed time since the rear image in the range corresponding to the initial position is displayed and drawing of an image based on the display data table according to the rear type (or the third symbol display device 81). May indicate any of the information indicating the elapsed time from the start of the display, or the type information of the position information (for example, the range of the range corresponding to the initial position) together with the back type and the position information. This is information indicating the elapsed time since the back image was displayed, or information indicating the elapsed time since the drawing of the image based on the display database (or the display of the third symbol display device 81) was started. May be defined as the drawing content of the back image. In addition, the position information may not be information indicating the elapsed time, but may be information indicating an address at which the range of the rear image to be displayed is stored.

  In the third symbol (symbol 1, symbol 2,...), Symbol type offset information is described as symbol type information for specifying the third symbol to be displayed. This offset information is information representing the difference between the numbers given to the respective third symbols. Rather than directly specifying the type of the third symbol, the offset information is specified because the display of the third symbol in the variable effect is the stop symbol of the variable effect performed immediately before and the variable effect performed this time. This is because it changes according to the stop symbol, and in the symbol offset information from the start of the fluctuation until a predetermined time has elapsed, the offset information from the stop symbol of the fluctuation effect performed immediately before is described. Thereby, the variable effect is started from the stop symbol in the immediately preceding variable effect.

  On the other hand, after a lapse of a predetermined time from the start of the fluctuation, the offset from the stop symbol set in accordance with the stop type command (display stop type command) received from the main control device 110 via the audio lamp control device 113. Provide information. Thus, the variable effect can be stopped at a stop symbol corresponding to the stop type specified by the main control device 110.

  In addition, since each 3rd symbol is given a unique number, a variation symbol in the immediately preceding variation effect and a stop symbol corresponding to the stop type designated by the main control device 110 are displayed in the 3rd symbol. In addition, the third symbol to be displayed can be easily specified from the offset information by managing the offset information by the difference between the numbers assigned to the third symbols.

  In the symbol offset information, the predetermined time in which the offset information of the stop symbol of the variable effect performed immediately before is switched to the offset information of the stop symbol of the variable effect performed this time, the third symbol fluctuates at high speed. It is set to be the time displayed. While the third symbol is being displayed at a high speed, the third symbol is invisible to the player, and during that time, the stop effect of the variable effect performed immediately before the symbol offset information is displayed. By switching from the offset information to the offset information of the stop symbol of the fluctuation effect performed this time, even if the continuity of the number of the third symbol is interrupted, the player is not made aware of the discontinuity of the continuity of the number. be able to.

  “Start” information indicating the start of the data table is described in “0000H”, which is the start address of the display data table. "End" information indicating the end of the process is described. Then, for each address between the address “0000H” in which the “Start” information is described and the address in which the “End” information is described, the drawing content corresponding to the rendering mode to be defined in the display data table Is described.

  The MPU 231 selects a display data table to be used in accordance with a command (for example, a display variation pattern command) transmitted from the audio lamp control device 113 based on a command or the like from the main control device 110, and selects the selected display. The data table is read from the data table storage area 233b, stored in the display data table buffer 233d, and the pointer 233f is initialized. Then, every time the rendering process for one frame is completed, the pointer 233f is incremented by one, and in the display data table stored in the display data table buffer 233d, based on the rendering content specified by the address indicated by the pointer 233f, The image content to be drawn is specified, and a drawing list (see FIG. 22) described later is created. By transmitting the drawing list to the image controller 237, a drawing instruction for the image is issued. As a result, the contents of the drawing are specified in the order specified by the display data table in accordance with the update of the pointer 233f, so that the image specified by the display data table is displayed on the third symbol display device 81.

  As described above, in the pachinko machine 10, the display control device 114 responds to a command (for example, a display variation pattern command) transmitted from the sound lamp control device 113 based on a command or the like from the main control device 110, and the like. Instead of changing the program to be executed by the MPU 231, the effect image to be displayed on the third symbol display device 81 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 233d. .

  Here, when a program executed by the MPU 231 is started every time the effect image displayed on the third symbol display device 81 is changed, as in a conventional pachinko machine, the effect image is diversified. Since a large load is applied to the processing of starting and executing a complicated and enormous program, the processing capability of the display control device 114 is limited, and there is a possibility that diversification of controllable effect images is limited. there were. On the other hand, in the present pachinko machine 10, the effect image to be displayed on the third symbol display device 81 can be changed only by a simple operation of appropriately replacing the display data table with the display data table buffer 233d. Regardless of the processing capability of the control device 114, various effect images can be displayed on the third symbol display 81.

  In addition, a display data table is prepared corresponding to each rendering mode, a display data table is set according to the rendering mode to be displayed, and a drawing list is created for each frame according to the set data table. This is because, in the pachinko machine 10, the effect to be displayed on the third symbol display device 81 is determined in advance based on the result of the lottery performed based on the winning start. On the other hand, in a game machine other than a game machine such as a pachinko machine, the display content changes on the spot based on the user's operation, so that the display content cannot be predicted. It is not possible to have a display data table corresponding to the presentation mode. In this way, a display data table is prepared corresponding to each rendering mode, a display data table is set according to the rendering mode to be displayed, and a drawing list is created frame by frame according to the set data table. The configuration can be realized for the first time based on the configuration in which the pachinko machine 10 determines an effect mode to be displayed on the third symbol display device 81 in advance based on the result of the lottery performed based on the winning start.

  Next, details of the transfer data table will be described with reference to FIG. FIG. 90 is a schematic diagram schematically illustrating an example of the transfer data table. The transfer data table is prepared corresponding to the display data table prepared for each effect, and as described above, among the sprite image data used in the effect specified in the display data table, the resident The transfer data information for transferring the image data not resident in the video RAM 235 from the character ROM 234 to the image storage area 236a of the normal video RAM 236 and the transfer timing are specified.

  If all the image data of the sprites used in the effects specified in the display data table are stored in the resident video RAM 235, no transfer data table corresponding to the display data table is prepared. Thus, an increase in the capacity of the data table storage area 233b can be suppressed.

  The transfer data table corresponds to an address specified in the display data table, and is transfer data information of image data of a sprite to be transferred at a time indicated by the address (hereinafter, referred to as “transfer target image data”). (Addresses “0001H” and “0097H” in FIG. 90 correspond). Here, the transfer start timing of the transfer target image data is set so that the image data corresponding to the predetermined sprite is stored in the image storage area 236a by the time the drawing of the predetermined sprite is started according to the display data table. In the transfer data table, the transfer data information of the transfer target image data is defined in correspondence with the address corresponding to the transfer start timing.

  On the other hand, if there is no transfer target image data to start transfer at the time indicated by the address specified in the display data table, there is no transfer target image data to start transfer corresponding to that address. Null data is defined (address “0002H” in FIG. 90 corresponds).

  The transfer data information includes the start address (storage source start address) and the end address (storage source end address) of the character ROM 234 in which the transfer target image data is stored, and the start address of the transfer destination (normal video RAM 236). Is included.

  As in the display data table, “Start” information indicating the start of the data table is described in the start address “0000H” of the transfer data table, and the final address of the transfer data table (in the example of FIG. 21, “02F0H”) describes “End” information indicating the end of the data table. Then, for each address between the address “0000H” in which the “Start” information is described and the address in which the “End” information is described, the transfer data information of the transfer target image data to be defined in the transfer data table. Is described.

  When the MPU 231 selects a display data table to be used in accordance with a command (for example, a display variation pattern command) transmitted from the audio ramp control device 113 based on a command or the like from the main control device 110, the display data table If there is a transfer data table corresponding to, the transfer data table is read from the data table storage area 233b and stored in a transfer data table buffer 233e of the work RAM 233 described later. Each time the pointer 233f is updated, the display data table stored in the display data table buffer 233d specifies the drawing content specified by the address indicated by the pointer 233f, and creates a drawing list (see FIG. 91) described later. At the same time, from the transfer data table stored in the transfer data table buffer 233e, the transfer data information of the image data of the predetermined sprite at which the transfer is to be started at that time is acquired, and the transfer data information is added to the created drawing list. to add.

  For example, in the example of FIG. 91, when the pointer 233f becomes “0001H” or “0097H”, the MPU 231 creates the transfer data information specified at the address of the transfer data table based on the display data table. The drawing list is added to the drawing list, and the added drawing list is transmitted to the image controller 237. On the other hand, when the pointer 233f is “0002H”, since null data is defined in the address “0002H” of the transfer data table, it is determined that there is no transfer target image data to start the transfer, and the transfer data table is generated. The drawing list is transmitted to the image controller 237 without adding the transfer data information to the drawing list.

  When the transfer data information is described in the drawing list received from the MPU 231, the image controller 237 transfers the transfer target image data from the character ROM 234 to a predetermined sub-area of the image storage area 236a according to the transfer data information. Execute the processing to be performed.

  Here, as described above, in the transfer data table, the image data corresponding to the predetermined sprite is stored in the image storage area 236a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information of the transfer target image data is specified for a predetermined address, the image data is transferred from the character ROM 234 to the image storage area 236a in accordance with the transfer data information specified in the transfer data table. When a predetermined sprite is drawn in accordance with the display data table, image data that is not resident in the resident video RAM 235 and that is required for drawing the sprite can always be stored in the image storage area 236a. Then, using the image data stored in the image storage area 236a, a predetermined sprite can be drawn based on the display data table.

  Thus, even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, an image necessary for display can be read from the character ROM 234 in advance without delay and transferred to the normal video RAM 236. The corresponding effect can be displayed on the third symbol display device 81 while drawing the image of each sprite specified in the data table. Further, by describing the transfer data table, only the non-resident image data in the resident video RAM 235 can be easily and reliably transferred from the character ROM 234 to the normal video RAM 236.

  In the pachinko machine 10, the display control device 114 displays the display data in response to a command (for example, a display variation pattern command) transmitted from the sound lamp control device 113 based on a command or the like from the main control device 110. When the table is set in the display data table buffer 233d, the transfer data table corresponding to the display data table is set in the transfer data table buffer 233e, so that the image data of the sprite used in the display data table is The data can be reliably transferred from the character ROM 234 to the normal video RAM 236 at a desired timing.

  In the transfer data table, transfer data information is defined so that image data is transferred from the character ROM 234 to the normal video RAM 236 for each image data corresponding to a sprite. Thus, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. By controlling the transfer of image data from the character ROM 234 to the normal video RAM 236 on a sprite basis, the image data transfer can be controlled in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in load on transfer.

  The transfer data table has the same data structure as the display data table, and corresponds to an address specified in the display data table, and transfers transfer target image data to start transfer at the time indicated by the address. Since the data information is defined, before the image data of a predetermined sprite is used based on the display data table set in the display data table buffer 233d, the image data is reliably stored in the normal video RAM 236. Thus, the transfer start timing can be instructed, so that even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, various effect images can be easily displayed on the third symbol display device 81. be able to.

  The simple image display flag 233c is a flag indicating whether or not to display the above-described power-on image (power-on main image and power-on fluctuation image) on the third symbol display device 81. The simple image display flag 233c is set after the image data corresponding to the power-on main image and the power-on fluctuation image is transferred to the power-on main image area 235a or the power-on fluctuation image area 235b of the resident video RAM. Is set to ON in the main processing (see FIG. 110) executed by the MPU 231 (see S1905). Then, at the stage when all the resident target image data is stored in the resident video RAM 235 by the resident image transfer process of the image transfer process, the third symbol display device 81 displays an image other than the power-on image. It is set to off (see S4405 in FIG. 130 (b)).

  This simple image display flag 233c is referred to in the V interrupt processing executed by the MPU 231 each time the V interrupt signal transmitted from the image controller 237 is detected (see S2201 in FIG. 112B), and When the image display flag 233c is on, the simple command determination process (see S2208 in FIG. 112 (b)) and the simple display setting process (see FIG. 112B) so that the power-on image is displayed on the third symbol display device 81. 112 (b) S2209) is executed. On the other hand, when the simple image display flag 233c is off, the command determination is performed so that various images are displayed in accordance with a command transmitted from the audio lamp control device 113 based on a command from the main control device 110 or the like. Processing (see FIGS. 113 to 126) and display setting processing (see FIGS. 127 to 130) are executed.

  The simple image display flag 233c is referred to in the transfer setting process executed by the MPU 231 during the V interrupt process (see S4301 in FIG. 130A), and the simple image display flag 233c is on. Executes the resident image transfer setting process (see FIG. 130 (b)) for transferring the resident target image data from the character ROM 234 to the resident video RAM 235 because there is resident target image data not stored in the resident video RAM 235. If the simple image display flag 233c is off, a normal image transfer setting process (see FIG. 131) for transferring image data necessary for the drawing process from the character ROM 234 to the normal video RAM 236 is executed.

  The display data table buffer 233d stores a display data table corresponding to an effect mode to be displayed on the third symbol display device 81 in accordance with a command or the like transmitted from the sound lamp control device 113 based on a command or the like from the main control device 110. Buffer for The MPU 231 determines an effect mode to be displayed on the third symbol display device 81 based on a command or the like transmitted from the audio lamp control device 113 and stores a display data table corresponding to the effect mode from the data table storage area 233b. Then, the selected display data table is stored in the display data table buffer 233d. Then, the MPU 231 increments the pointer 233f by one, and, based on the drawing content specified by the address indicated by the pointer 233f in the display data table stored in the display data table buffer 233d, increments the image controller 237 for each frame. A drawing list (see FIG. 91) described below, which describes the contents of an image drawing instruction with respect to, is generated. Thereby, the effect corresponding to the display data table stored in the display data table buffer 233d is displayed on the third symbol display device 81.

  The MPU 231 increments the pointer 233f by one and, based on the drawing content specified by the address indicated by the pointer 233f in the display data table stored in the display data table buffer 233d, sends an image to the image controller 237 for each frame. A drawing list described later (see FIG. 91) that describes the contents of the drawing instruction is generated. Thereby, the effect corresponding to the display data table is displayed on the third symbol display device 81.

  The transfer data table buffer 233e stores a transfer data table corresponding to the display data table stored in the display data table buffer 233d in response to a command or the like transmitted from the audio ramp control device 113 based on a command or the like from the main control device 110. Is a buffer for storing. When storing the display data table in the display data table buffer 233d, the MPU 231 selects a transfer data table corresponding to the display data table from the data table storage area 233b, and transfers the selected transfer data table. The data is stored in the data table buffer 233e. When all the image data of the sprite used in the display data table stored in the display data table buffer 233d is stored in the resident video RAM 235, a transfer data table corresponding to the display data table is not prepared. Therefore, the MPU 231 clears the contents by writing Null data indicating that there is no transfer target image data in the transfer data table buffer 233e.

  Then, the MPU 231 adds transfer pointer 233f to the transfer data table stored in the transfer data table buffer 233e, and defines transfer data information of transfer target image data specified by the address indicated by the pointer 233f. If this is the case (that is, if no Null data is described), the transfer data information is stored in a later-described drawing list (see FIG. 91) that describes the contents of an image drawing instruction to the image controller 237 generated for each frame. to add.

  Accordingly, when the transfer data information is described in the drawing list received from the MPU 231, the image controller 237 transfers the transfer target image data from the character ROM 234 to a predetermined sub area of the image storage area 236a according to the transfer data information. Execute the transfer process. Here, as described above, in the transfer data table, the image data corresponding to the predetermined sprite is stored in the image storage area 236a by the time the drawing of the predetermined sprite is started according to the display data table. Transfer data information of transfer target image data is defined for a predetermined address. Therefore, by transferring image data from the character ROM 234 to the image storage area 236a in accordance with the transfer data information specified in the transfer data table, it is necessary to draw a predetermined sprite in accordance with the display data table. The image data that is not resident in the resident video RAM 235 can always be stored in the image storage area 236a.

  Thus, even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, an image necessary for display can be read from the character ROM 234 in advance without delay and transferred to the normal video RAM 236. The corresponding effect can be displayed on the third symbol display device 81 while drawing the image of each sprite specified in the data table. Further, by describing the transfer data table, only the non-resident image data in the resident video RAM 235 can be easily and reliably transferred from the character ROM 234 to the normal video RAM 236.

  The pointer 233f is an address at which the corresponding drawing content or transfer data information of the transfer target image data is to be obtained from the display data table and the transfer data table stored in each of the display data table buffer 233d and the transfer data table buffer 233e. Is to be specified. The MPU 231 temporarily initializes the pointer 233f to 0 at the same time that the display data table is stored in the display data table buffer 233d. Then, the display setting processing of the V interrupt processing executed by the MPU 231 based on the V interrupt signal transmitted every 20 milliseconds when the drawing processing of the image for one frame is completed from the image controller 237 (FIG. 91 (b) ), The pointer update process (see S3005 in FIG. 129) is performed, and the value of the pointer 233f is incremented by one.

  Each time such an update of the pointer 233f is performed, the MPU 231 specifies the drawing content specified by the address indicated by the pointer 233f from the display data table stored in the display data table buffer 233d, (See FIG. 91), transfer data information of image data of a predetermined sprite to start transfer at that time is acquired from the transfer data table stored in the transfer data table buffer 233e, and the transfer data Add information to the created drawing list.

  Thereby, the effect corresponding to the display data table stored in the display data table buffer 233d is displayed on the third symbol display device 81. Therefore, the effect to be displayed on the third symbol display device 81 can be easily changed only by changing the display data table stored in the display data table buffer 233d. Therefore, regardless of the processing capability of the display control device 341, various effects can be displayed.

  Further, when the transfer data table stored in the transfer data table buffer 233e is stored, the sprite is drawn before the drawing of a predetermined sprite is started by the corresponding display data table based on the transfer data table. The image data that is not resident in the resident video RAM 235 used in the drawing of the image can be always stored in the image storage area 236a. Thus, even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, an image necessary for display can be read from the character ROM 234 in advance without delay and transferred to the normal video RAM 236. The corresponding effect can be displayed on the third symbol display device 81 while drawing the image of each sprite specified in the data table. Further, by describing the transfer data table, only the non-resident image data in the resident video RAM 235 can be easily and reliably transferred from the character ROM 234 to the normal video RAM 236.

  The drawing list area 233g is used by an image controller to draw one frame of image generated based on the display data table stored in the display data table buffer 233d and the transfer data table stored in the transfer data table buffer 233e. 237 is an area for storing a drawing list instructed by 237.

  Here, the drawing list will be described in detail with reference to FIG. FIG. 91 is a schematic diagram schematically showing the contents of the drawing list. The drawing list is an instruction table for instructing the image controller 237 to draw an image for one frame. As shown in FIG. 91, a back image used for one frame image, ..., effect (effect 1, effect 2, ...), character (character 1, character 2, ..., reserved ball number design 1, reserved ball number design 2, ..., error) For each sprite such as a pattern, detailed drawing information (detailed information) of the sprite is described. The drawing list also describes transfer data information for causing the image controller 237 to transfer predetermined image data from the character ROM 234 to the normal video RAM 236.

  The detailed drawing information (detailed information) of each sprite includes information indicating the RAM type (resident video RAM 235 or normal video RAM 236) in which the image data of the corresponding sprite (displayed object) is stored. The image controller 237 obtains the image data of the sprite from the memory area specified by the RAM type and the address. The detailed drawing information (detailed information) includes display position coordinates, enlargement ratio, rotation angle, translucent value, α blending information, color information, and filter designation information. A standard image generated from the image data of the sprite read from the video RAM is subjected to a scaling process according to a magnification, a rotation process according to a rotation angle, and a translucent process according to a translucent value. Subject to alpha blending information, perform synthesis processing with other sprites, perform color tone correction processing according to color information, and perform filtering processing according to the method specified by the information according to the filter specification information. Then, an image obtained by performing various processes on the display position indicated by the display position coordinates is drawn. Then, the drawn image is developed by the image controller 237 in either the first frame buffer 236b or the second frame buffer 236c specified by the drawing target buffer flag 233j.

  In the display data table stored in the display data table buffer 233d, the MPU 231 stores the drawing content specified by the address indicated by the pointer 233f and the content of other images to be drawn (for example, Based on the image and a warning image notifying that an error has occurred, detailed drawing information (detailed information) for all sprites used for drawing one frame of image is generated, and the detailed information is output for each sprite. Create a drawing list by rearranging.

  Here, in the detailed information of each sprite, the storage RAM type and the address of the data of the sprite (display object) correspond to the sprite type specified in the display data table and the sprite type specified from other image contents. Generated accordingly. That is, for each sprite, the area of the resident video RAM 235 in which the image data of the sprite is stored, or the sub-area of the image storage area 236a of the normal video RAM 236 is fixed, so that the MPU 231 Thus, the storage RAM type and the address where the image data of the sprite is stored can be immediately specified, and the information can be easily included in the detailed information of the drawing list.

  Further, the MPU 231 defines other information (display position coordinates, enlargement ratio, rotation angle, translucent value, α blending information, color information, and filter designation information) among the detailed information of each sprite in the display data table. Copy the information as it is.

  Further, when generating the drawing list, the MPU 231 sorts the sprites to be arranged on the rear side to the sprites to be arranged on the front side in the image of one frame, and obtains detailed drawing information for each sprite. (Detailed information). That is, in the drawing list, first, detailed information corresponding to the back image is described, and then, the third design (design 1, design 2,...), Effect (effect 1, effect 2,. Detailed information corresponding to each sprite is described in the order of (character 1, character 2,..., Reserved ball number symbol 1, reserved ball number symbol 2,..., Error symbol).

  The image controller 237 executes drawing processing of each sprite in accordance with the order described in the drawing list, and expands the drawn sprite in the frame buffer by overwriting. Therefore, in the image of one frame generated by the drawing list, the sprite drawn first can be arranged at the rearmost side, and the sprite drawn last can be arranged at the frontmost side.

  When the transfer data table stored in the transfer data table stored in the transfer data table buffer 233e includes the transfer data information at the address indicated by the pointer 233f, the MPU 231 stores the transfer data information (the character in which the transfer target image data is stored). The storage source start address and the storage source end address in the ROM 234 and the storage destination start address of the sub area provided in the image storage area 236a where the transfer target image data is to be stored are added to the end of the drawing list. If the drawing list includes the transfer data information, the image controller 237 reads an image from a predetermined area (the area indicated by the storage source start address and the storage source end address) of the character ROM 234 based on the transfer data information. The data is read, and the image data to be transferred is transferred to a predetermined sub-area (storage address) provided in the image storage area 236a of the normal video RAM 236.

  The time counter 233h is a counter that counts the effect time of the effect displayed on the third symbol display device 81 based on the display data table stored in the display data table buffer 233d. The MPU 231 sets time data indicating an effect time of an effect to be displayed based on the display data table in accordance with storing one display data table in the display data table buffer 233d. The time data is a value obtained by dividing the effect time by the image display time for one frame on the third symbol display device 81 (20 milliseconds in the present control example).

  Then, based on the V interrupt signal transmitted from the image controller 237 every 20 milliseconds when the rendering process and the display process of the image for one frame are completed, the V interrupt process executed by the MPU 231 (FIG. 112 (b) Each time the display setting process is performed, the time counter 233h is decremented by one (see S4007 in FIG. 127). As a result, when the value of the time counter 233h becomes 0 or less, the MPU 231 determines that the effect displayed by the display data table stored in the display data table buffer 233d has ended, and performs the operation in accordance with the end of the effect. Perform various processings to be performed.

  The stored image data determination flag 233i indicates that, for all sprites whose corresponding image data is not resident in the resident video RAM 235, the image data corresponding to the sprite is stored in the image storage area 236a of the normal video RAM 236. This is a flag indicating a storage state indicating whether or not there is any.

  The stored image data determination flag 233i is generated by an initialization process (see S1902 in FIG. 110) executed by the MPU 231 in the main process when the power is turned on. The stored image data determination flag 233i generated here is set to “OFF” indicating that the storage states of all sprites are not stored in the image storage area 236a.

  The stored image data determination flag 233i is updated when a transfer instruction of transfer target image data corresponding to one sprite is set in the normal image transfer setting process (see FIG. 131) executed by the MPU 231. Is In this update, the storage state corresponding to one sprite for which the transfer instruction is set is set to “ON” indicating that the corresponding image data is stored in the image storage area 236a. In addition, the image data of the other sprite that is to be stored in the sub area of the same image storage area 236a as the one sprite is always in an unstored state by storing the image data of the one sprite. Therefore, the storage state corresponding to the other sprite is set to “off”.

  The MPU 231 refers to the stored image data discrimination flag 233i when transferring image data of a sprite in which image data is not resident in the resident video RAM 235 from the character ROM 234 to the normal video RAM 236, and transmits the sprite of the transfer target sprite. It is determined whether the image data has already been stored in the image storage area 236a of the normal video RAM 235 (see S4513 in FIG. 131). If the storage state corresponding to the transfer target sprite is “OFF” and the corresponding image data is not stored in the image storage area 236a, a transfer instruction for the image data is set (see S4514 in FIG. 131). The image controller 237 causes the image data to be transferred from the character ROM 234 to a predetermined sub-area of the image storage area 236a. On the other hand, if the storage state corresponding to the sprite to be transferred is “ON”, since the corresponding image data has already been stored in the image storage area 236a, the transfer processing of the image data is stopped. As a result, useless transfer from the character ROM 234 to the normal video RAM 236 can be suppressed, and the processing load on each unit of the display control device 114 and the traffic on the bus line 240 can be reduced. it can.

  The drawing target buffer flag 233j is a frame buffer (hereinafter, referred to as a “drawing target buffer”) that develops an image drawn by the image controller 237 from the two frame buffers (the first frame buffer 236b and the second frame buffer 236c). If the drawing target buffer flag 233j is 0, the first frame buffer 236b is specified as the drawing target buffer, and if it is 1, the second frame buffer 236c is specified. Then, the information of the designated drawing target buffer is transmitted to the image controller 237 together with the drawing list (see S4602 in FIG. 132).

  As a result, the image controller 237 executes a drawing process of expanding the image drawn based on the drawing list on the specified drawing target buffer. Further, the image controller 237 reads out the rendered image information previously developed from a frame buffer different from the rendering target buffer in parallel with the rendering process, and sends the read image information to the third symbol display device 81 together with the drive signal. By transferring the information, a display process for displaying an image on the third symbol display device 81 is executed.

  The drawing target buffer flag 233j is updated at the same time that the drawing target buffer information is transmitted to the image controller 237 together with the drawing list. This updating is performed by inverting the value of the drawing target buffer flag 233j, that is, setting the value to “1” when the value is “0” and setting it to “0” when the value is “1”. Done by Thus, the drawing target buffer is alternately set between the first frame buffer 236b and the second frame buffer 236c every time the drawing list is transmitted. The transmission of the drawing list is performed by the MPU 231 based on the V interrupt signal transmitted from the image controller 237 every 20 milliseconds when the drawing process and the display process of the image for one frame are completed. It is performed every time the drawing process of the process (see FIG. 112B) is executed (see S4602 of FIG. 132).

  That is, at a certain timing, the first frame buffer 236b is specified as a frame buffer for developing an image of one frame, and the second frame buffer 236c is specified as a frame buffer from which image information of one frame is read. When the drawing process and the display process are executed, the second frame buffer 236c is designated as a frame buffer for developing the image of one frame 20 ms after the completion of the drawing process of the image of one frame, The first frame buffer 236b is designated as the frame buffer from which the image information is read. Thereby, the image information of the image previously developed in the first frame buffer 236b can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the second frame buffer 236c. You.

  Then, after the next 20 milliseconds, the first frame buffer 236b is designated as a frame buffer for developing an image of one frame, and the second frame buffer 236c is designated as a frame buffer from which image information of one frame is read. Is done. As a result, the image information of the image previously developed in the second frame buffer 236c can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the first frame buffer 236b. You. Thereafter, the frame buffer for expanding the image for one frame and the frame buffer from which the image information for one frame is read out are changed to one of the first frame buffer 236b and the second frame buffer 236c every 20 milliseconds. By alternately specifying the images, it is possible to continuously perform the display processing of the image of one frame in units of 20 milliseconds while performing the drawing processing of the image of one frame.

  The prize information storage area 233k is an area for storing the prize information received from the audio lamp control device 113, and is used to determine whether or not there is a big hit in the hold at the time of a super background notice or the like.

  In the gaming state storage area 233m, when a variation pattern command for display is received from the audio lamp control device 113, the gaming state is extracted from the received variation pattern command and stored. This gaming state storage area 233m is used in the opening command process (S2902) executed in the jackpot-related command process (FIG. 118) to determine whether or not the started big hit is a continuous big hit. Specifically, if it is determined that the probability is changing or the time is being reduced, it is determined that the jackpot is a continuous jackpot, and otherwise, it is determined that the jackpot is not a continuous jackpot.

  The variation history storage area 233n is an area in which a variation pattern based on a received command is stored in the variation pattern command processing, like the gaming state storage area 233m. The change history storage area 233n is used when setting a mass event in the map setting process (S3001) in the opening command process (FIG. 119) executed at the start of the big hit. More specifically, it will be described later in the description of the mass event setting table storage area 233t.

  The display effect counter 233o is a loop counter of 0 to 198, and is updated in the counter update process (S2207) executed in the V interrupt process (FIG. 112) of the display control device 114. This display effect counter is used to select a background type in the super background effect process (see FIG. 115), to set a mass event in the map setting process (FIG. 120), or to execute a super background SW process (see FIG. 124). Are used to select a background type, or to select a background addition flag to be set to ON in the big hit SW process (see FIG. 125).

  The continuation counter 233p is incremented when it is determined in the map setting process (see FIG. 120) executed at the start of the big hit effect that a continuous big hit has occurred. Based on the value of the continuation counter 233p and the value of the display effect counter 233o, a mass event defined in a mass setting table storage area 233t described later is set. The continuation counter 233p is initialized to 0 when the continuation of the jackpot ends (when the gaming state becomes normal).

The back image change flag 233q is set to ON in the back image change command processing (see FIG. 122) when the back image change command is received from the audio lamp control device 113. When the rear image change flag 233q is set to ON, in the normal image transfer setting process (see FIG. 131),
The super-background flag 233r is set to on when the back-image discrimination flag corresponding to the super-background notice is set to on in the back-image change command (see FIG. 122). By setting the super background flag 233r to ON, it is determined that the super background notice is being rendered. As a result, when a SW-related command is received from the audio lamp control device 113, the super background SW process (S3602) is executed in the SW-related command process (see FIG. 123). The super background SW process is a process based on the operation of the selection switch 270 and the like during the production of the super background notice. This super-background flag 233q is set to off at the end of the super-background announcement effect.

  The map storage area 233s is an area for storing information on maps and mass events set in the big hit effect. The map storage area 233s is an area where the information of the map and the mass event is stored in the process at the time of receiving the ending command, which is the end of the big hit effect, and is read when the continuous big hit is executed. is there. Thereby, when the continuous big hit is executed, the previously set map and mass event can be read out, and the continuous big hit effect can be executed.

  The mass setting table storage area 233t is referred to when a mass event is set in the map setting process (see FIG. 120) executed at the start of the big hit effect. Here, the details of the mass setting table storage area 233t will be described with reference to FIG. FIG. 87A is a schematic diagram schematically showing the contents of the mass setting table storage area 233t.

  In the cell setting table storage area 233t, a normal cell setting table 233t1 and a continuous cell setting table 233t2 are stored.

  The normal mass setting table 233t1 is a table that is referred to for setting a mass event when the first map is read (when the big hit does not continue and there is no passing history of the continuum).

  In the normal cell setting table 233t1, patterns A to C of cell events are defined based on the values of the jackpot type and the display effect counter 233o. Here, the jackpot type is determined using the information in the change history storage area 233n. For example, when the big hit type is “big hit A” and the value of the display effect counter 233o is “10”, “pattern B” is set as the mass event.

  Next, the continuous mass setting table 233t2 is a table that is referred to for setting a mass event when a continuous map is read (when the big hit is continued or when there is a continuation mass passing history). is there.

  Patterns A to E of the mass event are set in the continuous mass setting table 233t2 based on the values of the number of continuations (the value of the continuation counter 233p) and the display effect counter 233o. For example, when the number of continuations (the value of the continuation counter 233p) is “5” and the value of the display effect counter 233o is “10”, “Pattern B” is set as the mass event. In this control example, when the number of continuations is 5 or more, the “pattern D” of the mass event may be set, and when the number of continuations is 10 or more, the “pattern E” of the mass event Is configured to be set. This makes it possible to set a special mass event that is set only when the jackpot continues.

  The mass event storage area 233u is an area for storing the event of the mass selected during the big hit effect. Specifically, when the decision switch 270e is pressed in the big hit SW process (FIG. 125), the event of the determined cell is stored in the cell event storage area by the processing of S3807. The mass event stored in the mass event storage area 233u is referred to in the processing of S3101 in the round number command processing (see FIG. 119) for executing the round effect, and is used for determining the round number display data table. As a result, a round effect corresponding to the event of the determined cell can be executed.

  The route history storage area 233w is an area for storing selected (passed) cells in a jackpot effect. In the route history storage area 233w, information on the selected cell is added when the decision switch 270e is pressed in the big hit SW process (see FIG. 125). Thus, in the map setting process (see FIG. 120), it is possible to determine whether there is a passing history of continuum, whether there is a non-passing cell, and the like.

  The background addition flag 223x is a flag that is set to ON in accordance with the selected mass event in a jackpot effect. By setting the background addition flag 223x to ON, when a back image change command is received, a corresponding additional background can be set.

  The in-door change number counter 223y is an area for counting the number of changes performed during the display of the in-door background in the super background notice stage. The in-door variation counter 223y is set to a predetermined value (20 in this control example) when the in-door background is set, and is decremented by one each time a subsequent variation is executed. When the in-door fluctuation frequency counter 223y becomes 0, the winning information storage area 233k is referred to. If there is a big hit in the hold, the same background in the door is set again with a high probability, and if there is no big hit in the hold, A background other than the background inside the door is set with high probability.

<Regarding Control Process of Main Control Device in First Control Example>
Next, each control process executed by the MPU 201 in the main control device 110 will be described with reference to the flowcharts in FIGS. The processing of the MPU 201 is roughly divided into a start-up processing started when the power is turned on, a main processing executed after the start-up processing, and a timer started periodically (at an interval of 2 ms in this control example). There are an interrupt process and an NMI interrupt process started by input of a power failure signal SG1 to the NMI terminal. For convenience of explanation, first, a timer interrupt process and an NMI interrupt process will be described, and then a start process will be described. And the main processing will be described.

  FIG. 92 is a flowchart showing a timer interrupt process executed by MPU 201 in main controller 110. The timer interrupt process is a periodic process executed, for example, every 2 milliseconds. In the timer interrupt process, first, a process of reading various winning switches is executed (S101). That is, the state of the various switches connected to the main controller 110 is read, and the state of the switch is determined to store the detection information (winning detection information).

  Next, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are updated (S102). Specifically, the first initial value random number counter CINI1 is incremented by one, and is cleared to 0 when the counter value reaches a maximum value (299 in this control example). Then, the updated value of the first initial value random number counter CINI1 is stored in a corresponding buffer area of the RAM 203. Similarly, the second initial value random number counter CINI2 is incremented by one, and when the counter value reaches a maximum value (239 in this control example), it is cleared to 0, and the updated value of the second initial value random number counter CINI2 is incremented. Is stored in the corresponding buffer area of the RAM 203.

  Further, the first random number counter C1, the first type counter C2, the stop type selection counter C3, and the second random number counter C4 are updated (S103). Specifically, the first random number counter C1, the first type counter C2, the stop type selection counter C3, and the second random number counter C4 are each incremented by one, and their counter values are maximized (in this control example, When they reach 299, 99, 99, 239, respectively, they are cleared to 0, respectively. Then, the updated values of the counters C1 to C4 are stored in the corresponding buffer areas of the RAM 203.

  Next, in addition to the process for displaying on the first symbol display device 37, a special symbol variation process for setting a variation pattern of the third symbol and the like by the third symbol display device 81 is executed (S104). A start winning process is executed in accordance with a win (start winning) in the first winning port 64 (S105). The details of the special symbol change process and the start winning process will be described later with reference to FIGS. 93 to 95.

  After the start winning process, the normal symbol variation process, which is a process for displaying on the second symbol display device 83, is executed (S106), and the through gate passing process accompanying the passing of the ball at the normal entrance 67 is performed. Is executed (S107). The details of the ordinary symbol change process and the through gate passage process will be described later with reference to FIGS. 96 and 97. After the execution of the through gate passage process, the launch control process is executed (S108), and other processes to be executed periodically are executed (S109), and the timer interrupt process is terminated. The firing control process detects that the player is touching the operation handle 51 with the touch sensor 51a, and fires the ball on condition that the stop switch 51b for stopping firing is not operated. This is a process for determining ON / OFF of the data. The main controller 110 instructs the launch controller 112 to launch the ball when the launch of the ball is on.

  Next, with reference to FIG. 93, the special symbol changing process (S104) executed by the MPU 201 in the main control device 110 will be described. FIG. 93 is a flowchart showing the special symbol change process (S104). This special symbol change process (S104) is executed in the timer interrupt process (see FIG. 92), and the special symbol (first symbol) change display performed by the first symbol display device 37 or the third symbol display device This is a process for controlling the variable display of the third symbol performed at 81.

  In this special symbol change process, first, it is determined whether or not the present is a special symbol jackpot (S201). During the special symbol jackpot, the first symbol display device 37 and the third symbol display device 81 display a special symbol jackpot (including a special symbol jackpot game), and the special symbol jackpot. During the predetermined time after the end of the big hit game. If the result of the determination is that the special symbol is in a big hit (S201: Yes), this processing is terminated as it is.

  If it is not during the special symbol jackpot (S201: No), it is determined whether the display mode of the first symbol display device 37 is changing (S202), and the display mode of the first symbol display device 37 is changing. If not (S202: No), the value of the special symbol reserved ball number counter 203c (the number of times of suspension of the variable display in the special symbol) is acquired (S203). Next, it is determined whether or not the value (N) of the special symbol reserved ball number counter 203c is greater than 0 (S204), and if the value (N) of the special symbol reserved ball number counter 203c is 0 (S204: No), this process ends as it is.

  On the other hand, if the value (N) of the special symbol reserved ball number counter 203c is not 0 (S204: Yes), the value (N) of the special symbol reserved ball number counter 203c is subtracted by 1 (S205) and changed by the calculation. A reserved ball number command indicating the value of the special symbol reserved ball number counter 203c is set (S206). The set number-of-spheres command set here is stored in a command transmission ring buffer provided in the RAM 203, and is included in an external output process (S901) of a later-described main process (see FIG. 100) executed by the MPU 201. Are transmitted to the audio lamp control device 113. When receiving the reserved ball number command, the sound ramp control device 113 extracts the value of the special symbol reserved ball number counter 203c from the reserved ball number command, and stores the extracted value in the special symbol reserved ball number counter 223b of the RAM 223. .

  After setting the number-of-retained-balls command by the processing of S206, the data stored in the special symbol-reserved-ball storage area 203a is shifted (S207). In the process of S207, a process of sequentially shifting the data stored in the reserved first area to the reserved fourth area of the special symbol reserved ball storage area 203a to the execution area side is performed. More specifically, the first area in the hold → the execution area, the second area in the hold → the first area in the hold, the third area in the area → the second area in the hold, the fourth area in the area → the third area in the hold, etc. Shift data. After shifting the data, a special symbol variation start process for starting variable display on the first symbol display device 37 is executed (S208). The special symbol change start process will be described later with reference to FIG.

  In the process of S202, if the display mode of the first symbol display device 37 is changing (S202: Yes), it is determined whether or not the change time of the variable display executed on the first symbol display device 37 has elapsed. (S209). The fluctuation time of the fluctuation display executed in the first symbol display device 37 is determined according to the fluctuation pattern selected by the fluctuation type counter CS1 (determined according to the fluctuation pattern command), and the fluctuation time is determined. If has not elapsed (S209: No), the display content of the first symbol display device 37 is updated (S210), and this processing ends.

  On the other hand, in the process of S209, if the fluctuating time of the fluctuating display being executed has elapsed (S209: Yes), a display mode corresponding to the stop symbol of the first symbol display device 37 is set (S211). The setting of the stop symbol is performed in advance by a special symbol change start process (S208) described later with reference to FIG. When the special symbol change start process is executed, a special symbol lottery is performed based on the values of various counters stored in the execution area of the special symbol holding ball storage area 203a. More specifically, it is determined whether or not the special symbol is a big hit according to the value of the first random number counter C1. Is determined from jackpot A to jackpot D.

  In the present control example, when the big hit A occurs, the blue LED is turned on in the first symbol display device 37, and when the big hit B occurs, the red LED is turned on. In the case of a disconnection, the red LED and the green LED are turned on. The display of each LED is turned off when the next change display is started, but may be turned on only for a few seconds after the change stops.

  After the processing of S211 is completed, when the variable display being executed on the first symbol display device 37 is started, the lottery result of the special symbol performed by the special symbol variation start process (the current lottery result) is: It is determined whether it is a special symbol jackpot (S212). If the current lottery result is a special symbol jackpot (S212: Yes), the start of the special symbol jackpot is set (S213), and this processing ends. When the start of the special symbol big hit is set by the process of S213, when the big hit control process (S904) is executed in the main process (see FIG. 100), the process branches to S1001: Yes to open the opening command. Is set. As a result, in the third symbol display device 81, a big hit effect is started. In addition, in the process of S213, the probable changing flag 203e is set to off, or the value of the time reduction counter 203f is set to 0. This is because the state during the jackpot is the same as the initial state.

  In the process of S212, if the result of the current lottery is out of the special symbol (S212: No), it is determined whether or not the value of the counter for hourly working counter 203f is 1 or more (S214). If this is the case (S214: Yes), the value of the time reduction counter 203f is decremented by 1 (S215), and this processing ends. On the other hand, if the value of the counter 203f during time reduction is 0 (S214: No), the process of S215 is skipped, and the present process ends.

  Next, with reference to FIG. 94, the special symbol change start process (S208) executed by the MPU 201 in the main control device 110 will be described. FIG. 94 is a flowchart showing the special symbol change start process (S208). This special symbol change start process (S208) is a process executed in the special symbol change process (S104) of the timer interrupt process (see FIG. 92), and is stored in the execution area of the special symbol holding ball storage area 203a. Based on the values of the various counters performed, a lottery of "special symbol jackpot" or "special symbol departure" is performed (whether or not), and is performed by the first symbol display device 37 and the third symbol display device 81. This is a process for determining an effect pattern of a variable effect (a variable effect pattern).

  In the special symbol change start process, first, each value of the first random number counter C1, the first hit type counter C2, and the stop type selection counter C3 stored in the execution area of the special symbol holding ball storage area 203a is obtained. (S301).

  Next, it is determined whether the probable changing flag 203e of the RAM 203 is on (S302). The probable changing flag 203e is a flag indicating whether or not the pachinko machine 10 is in the special symbol probable state. If the probable changing flag 203e is on, it indicates that the pachinko machine 10 is in the special symbol probable state. If the probable changing flag 203e is off, it indicates that the pachinko machine 10 is in the normal state of the special symbol.

  When the probable changing flag 203e is on (S302: Yes), since the pachinko machine 10 is in the probable changing state of the special symbol, the value of the first random number counter C1 obtained in S301 and the first random number table are obtained. Based on the jackpot determination value for high probability at 202a, a lottery result of whether or not a special symbol jackpot is obtained is acquired (S303). Specifically, the value of the first per-random number counter C1 is compared with one of the thirty high-probability jackpot determination values stored in the first per-random number table 202a. As described above, 30 random numbers “0 to 29” are set as the random numbers that are the big hits of the special symbol at the time of the high probability, and the value of the first random number counter C1 and the random numbers that make these hits When the numerical values match, it is determined that the special symbol is a big hit. When the lottery result of the special symbol is obtained, the process proceeds to S305.

  On the other hand, in the processing of S302, if the probable changing flag 203e is off (S302: No), the value of the first random number counter C1 obtained in the processing of S301 is obtained because the pachinko machine 10 is in the normal state of the special symbol. And the lottery result of whether or not it is a special symbol big hit is acquired based on the big hit determination value for low probability in the first random number table 202a (S304). Specifically, the value of the first random number counter C1 is compared with three large probability determination values for low probability stored in the first random number table 202a. As described above, three random numbers of “0 to 2” are set as the random numbers of the special symbol at the time of the low probability, and the value of the first random number counter C1 and the random number of these random numbers are set. When the numerical values match, it is determined that the special symbol is a big hit. When the lottery result of the special symbol is obtained, the process proceeds to S305.

  Then, it is determined whether the lottery result of the special symbol acquired by the processing of S303 or S304 is a special symbol jackpot (S305), and if it is determined that the special symbol jackpot (S305: Yes), Based on the value of the first hit type counter C2 acquired in the process of S301, the display mode at the time of the big hit is set (S306). More specifically, the value of the first hit type counter C2 obtained in the process of S301 is compared with the random number value stored in the first hit type selection table 202b, and the four types of special symbol big hits (big hits) are compared. Among the A to D), it is determined what the jackpot type is. As described above, if the value of the first hit type counter C2 is in the range of “0 to 24”, it is determined that the hit is big hit A (16 rounds of probability change big hit), and if it is in the range of “25 to 49”, If it is determined to be jackpot B (four round probability variable jackpot), if it is in the range of “50 to 74”, it is determined to be jackpot C (16 rounds short jackpot), if it is in the range of “74 to 99”, It is determined that the jackpot is a jackpot D (a four-round time-saving jackpot) (see FIG. 81 (b)).

  In the process of S306, the display mode of the first symbol display device 37 (the lighting state of the LEDs 37A and 37B) is set according to the determined big hit type (big hits A to D). In order to stop and display the stop symbol corresponding to the big hit type on the third symbol display device 81, the big hit types (big hits A to D) are set as the stop types.

  Next, the fluctuation pattern at the time of the big hit is determined (S307). When the fluctuation pattern is set in the process of S307, the fluctuation time (display time) of the fluctuation effect on the first symbol display device 37 is set, and the third symbol display device 81 stops at the big hit symbol until it stops. The fluctuation time of the symbol is determined. At this time, the value of the variation type counter CS1 stored in the counter buffer of the RAM 203 is checked, and the variation time of the symbol variation such as normal reach and super reach is determined based on the value of the variation type counter CS1. The relationship between the value of the variation type counter CS1 and the variation time is defined in advance by a table or the like.

  For example, as the variation pattern for deviation, “complete deviation”, “departure normal reach”, “departure super reach”, and “departure special reach” are defined. Various types of "hit super reach" and "hit special reach" are specified.

  In the process of S305, when it is determined that the special symbol is out of the way (S305: No), the display mode at the time of being out of place is set (S308). In the process of S308, the display mode of the first symbol display device 37 is set to the display mode corresponding to the deviated symbol, and the value of the stop type selection counter C3 stored in the execution area of the special symbol holding ball storage area 203a is set. Based on this, the type of stop to be displayed on the third symbol display device 81 is set to reach out of front and rear, reach other than back and forth, or completely out of reach.

  Here, if the pachinko machine 10 is in the special symbol probable state, the value of the stop type selection counter C3 acquired in the process of S301 is compared with the random number value stored in the high probability stop type selection table. Then, the stop type is set. Specifically, if the value of the stop type selection counter C3 is in the range of "0 to 89", complete departure is set, and if it is in the range of "90 to 97", reach other than departure is set, and "98" , 99 ”, the reach is set. On the other hand, if the pachinko machine 10 is in the normal state of the special symbol, the stop type is set by comparing the value of the stop type selection counter C3 with the random number value stored in the low probability stop type selection table. I do. Specifically, if the value of the stop type selection counter C3 is in the range of “0 to 79”, complete out is set, and if it is in the range of “80 to 97”, reach other than out of front and back is set, and “98” , 99 ”, the reach is set.

  Next, a variation pattern at the time of departure is determined (S309). Here, the display time of the first symbol display device 37 is set, and the fluctuation time of the third symbol until the third symbol display device 81 stops at the off symbol is determined. At this time, as in the process of S308, the value of the variation type counter CS1 stored in the counter buffer of the RAM 203 is checked, and based on the value of the variation type counter CS1, the variation time of the symbol variation such as normal reach, super reach, etc. Is determined.

  Here, the various types of “winning super reach” and “missing super reach” include “super reach A”, “super reach B”, and other super reach, and are based on the numerical value of the fluctuation type counter CS1. Selected in the processing of S307 or S309. In the present control example, the super reach type (“super reach A”, “super reach B”, etc.) is selected by the MPU 201 of the main control device 110. However, the present invention is not limited to this. May be configured to be selected by the MPU 221. Thereby, the processing load on MPU 201 of main controller 110 can be reduced.

  When the processing of S307 or the processing of S309 is completed, next, a fluctuation pattern command for notifying the display control device 114 of the fluctuation pattern determined in the processing of S307 or S309 is set (S310). Next, a stop type command for notifying the display control device 114 of the stop type set in the processing of S306 or S308 is set (S311). These fluctuation pattern command and stop type command are stored in a command transmission ring buffer provided in the RAM 203, and these commands are transmitted to the sound ramp control device 113 in the processing of S901 of the main processing (see FIG. 100). Is done. The sound lamp control device 113 transmits the stop type command to the display control device 114 as it is. When the processing of S312 ends, the process returns to the special symbol change processing.

  Next, the start winning process (S105) executed by the MPU 201 in the main control device 110 will be described with reference to the flowchart in FIG. FIG. 95 is a flowchart showing the start winning processing (S105). This start winning process (S105) is executed in the timer interrupt process (see FIG. 92), and it is determined whether or not there is a winning (start winning) in the first winning opening 64. This is a process for executing the pre-reading of the lottery result in the special symbol from the holding process of the values indicated by the various random number counters and the values indicated by the held various random number counters.

  When the start winning process is executed, first, it is determined whether or not the ball has won the first winning opening 64 (start winning) (S401). Here, a ball entering the first winning port 64 is detected over three timer interrupt processes. Then, when it is determined that the ball has won the first winning opening 64 (S401: Yes), the value of the special symbol reserved ball number counter 203c (the number N of times of the variable display in the special symbol) is acquired (S402). Then, it is determined whether or not the value (N) of the special symbol reserved ball number counter 203c is less than the upper limit value (4 in the present control example) (S403).

  Then, there is no winning in the first winning opening 64 (S401: No), or even if there is a winning in the first winning opening 64, the value (N) of the special symbol reserved ball number counter 203c must be less than 4. If (S403: No), this process ends. On the other hand, if there is a winning in the first winning opening 64 (S401: Yes) and the value (N) of the special symbol reserved ball number counter 203c is less than 4 (S403: Yes), the special symbol reserved ball number counter is set. The value (N) of 203c is incremented by 1 (S404). Then, a reserved ball number command indicating the value of the special symbol reserved ball number counter 203c changed by the calculation is set (S405).

  The set number-of-spheres command set here is stored in a command transmission ring buffer provided in the RAM 203, and is included in an external output process (S901) of a later-described main process (see FIG. 100) executed by the MPU 201. Are transmitted to the audio lamp control device 113. When receiving the reserved ball number command, the sound ramp control device 113 extracts the value of the special symbol reserved ball number counter 203c from the reserved ball number command, and stores the extracted value in the special symbol reserved ball number counter 223b of the RAM 223. .

  After setting the pending ball number command in the processing of S405, the values of the first random number counter C1, first collision type counter C2, and stop type selection counter C3 updated in S103 of the timer interrupt processing are stored in the RAM 203. Is stored in the first one of the free reserved areas (the reserved first area to the reserved fourth area) of the special symbol reserved ball storage area 203a (S406). In the process of S406, the value of the special symbol reserved ball counter 203c is referred to, and if the value is 0, the reserved first area is set as the first area. Similarly, if the value is 1, the reserved second area is set as the first area, if the value is 2, the reserved third area is set as the initial area, and if the value is 3, the reserved fourth area is set as the initial area.

  Next, on the basis of the various counter values stored in the process of S406, the success or failure of the lottery in the special symbol (whether or not a big hit), its stop type (in the case of a big hit, a big hit type), and its fluctuation pattern are predicted. (S407).

  If the success or failure of the lottery in the special symbol, the stop type (big hit type in the case of a big hit), and the fluctuation pattern are predicted by the processing of S407, next, the predicted success or failure of the lottery, the predicted stop type, A winning information command including the predicted fluctuation pattern is set (S408).

  The winning information command set here is stored in a command transmission ring buffer provided in the RAM 203, and is executed in an external output process (S901) of a main process (see FIG. 100) described later executed by the MPU 201. It is transmitted to the sound lamp control device 113. Upon receiving the winning information command, the sound lamp control device 113 extracts a winning / wrong, a stop type, and a fluctuation pattern from the winning information command, and stores the information as winning information in the winning information storage area 223a.

  Next, it is determined whether or not the game state is a jackpot (S409). In the processing of S409, when it is determined that the gaming state is the probability change big hit (S409: Yes), the prefetching certainty change flag 203g provided in the RAM 203 is set to ON (S410), and this processing ends. On the other hand, when it is determined that the gaming state is not the jackpot (S409: No), the process proceeds to S411.

  In the process of S411, it is determined whether or not the gaming state is a time savings jackpot (S411). If it is determined that the gaming state is a time savings jackpot (S411: Yes), the prefetch certainty provided in the RAM 203 is being changed. The flag 203g is set to off (S412), and this process ends. On the other hand, in the process of S411, when it is determined that the gaming state is not the time saving big hit (S411: No), the process of S412 is skipped and the process ends.

  Next, with reference to the flowchart of FIG. 96, the ordinary symbol variation process (S106) executed by the MPU 201 in the main control device 110 will be described. FIG. 96 is a flowchart showing the ordinary symbol change processing (S106). The normal symbol change process (S106) is executed in the timer interrupt process (see FIG. 92), and the second symbol change display performed by the second symbol display device 83 or the electric control attached to the second winning opening 640 is performed. This is a process for controlling the opening time of the accessory 640a and the like.

  In the normal symbol variation process, first, it is determined whether or not the present is hitting a normal symbol (second symbol) (S501). As the winning of the normal symbol (the second symbol), during the display indicating the hit on the second symbol display device 83, and the opening / closing control of the electric accessory 640a attached to the second winning opening 640 is performed. In the middle of being included. If the result of the determination is that a normal symbol (second symbol) is being hit (S501: Yes), the present process ends.

  On the other hand, if the normal symbol (second symbol) is not being hit (S501: No), it is determined whether or not the display mode of the second symbol display device 83 is changing (S502), and the second symbol display device is determined. If the display mode of 83 is not fluctuating (S502: No), the value of the ordinary symbol reserved ball number counter 203d (the number M of suspended display of the ordinary symbol in the ordinary symbol) is acquired (S503). Next, it is determined whether or not the value (M) of the ordinary symbol retaining ball number counter 203d is greater than 0 (S504). If the value (M) of the ordinary symbol retaining ball number counter 203d is 0 (S504: S504). No), this process ends as it is. On the other hand, if the value (M) of the ordinary symbol retaining ball number counter 203d is not 0 (S504: Yes), the value (M) of the ordinary symbol retaining ball number counter 203d is decremented by 1 (S505).

  Next, the data stored in the ordinary symbol holding ball storage area 203b is shifted (S506). In the process of S506, a process of sequentially shifting the data stored in the reserved first area to the reserved fourth area of the ordinary symbol reserved ball storage area 203b to the execution area side is performed. More specifically, the first area in the hold → the execution area, the second area in the hold → the first area in the hold, the third area in the area → the second area in the hold, the fourth area in the area → the third area in the hold, etc. Shift data. After the data is shifted, the value of the second random number counter C4 stored in the execution area of the ordinary symbol holding sphere storage area 203b is obtained (S507).

  Next, it is determined whether or not the value of the during-hours counter 203f of the RAM 203 is 1 or more (S508). The time reduction counter 203f is a counter that indicates whether or not the pachinko machine 10 is in the normal symbol time reduction state. If the value of the counter 203f during time reduction is 0, it indicates that the pachinko machine 10 is in a normal state of a normal symbol.

  When the value of the time reduction counter 203f is 1 or more (S508: Yes), it is determined whether or not the present is in a special symbol jackpot (S509). During the special symbol jackpot, the first symbol display device 37 and the third symbol display device 81 display a special symbol jackpot (including a special symbol jackpot game), and the special symbol jackpot. During the predetermined time after the end of the big hit game. If the result of the determination is that the special symbol is in a big hit (S509: Yes), the process proceeds to S511. In the present control example, during the special symbol big hit, it is configured such that the lottery of the ordinary symbol is hard to win.

  During the special symbol jackpot (that is, during the special game state), the player hits the ball in an attempt to win the specific winning opening 65a. , And the ball is in a state where it easily enters. Here, in the present control example, the electric accessory 640a attached to the second winning opening 640 is not opened during the special symbol big hit (that is, during the special game state). Accordingly, it is possible to suppress as much as possible a ball trying to win the specific winning opening 65a from entering the second winning opening 640.

  In addition, even if the ball is suppressed from entering the second winning opening 640 during the special symbol jackpot, the ball enters the first winning opening 64. As a result, in most cases, while the pachinko machine 10 is in the special game state, the number of reserved balls for the first winning port 64 becomes maximum (four times).

  In the process of S509, if it is not during the special symbol jackpot (S509: No), since the pachinko machine 10 is not in the special symbol jackpot and the pachinko machine 10 is in the normal symbol time saving state, it is acquired in the process of S507. Based on the value of the second random number counter C4 thus obtained and the second random number table for high probability, a lottery result of whether or not a normal symbol has been won is obtained (S510). Specifically, the value of the second random number counter C4 is compared with the random number value stored in the second random number table for high probability. As described above, if the value of the second hit type counter C4 is in the range of “5 to 204”, it is determined that the hit is a normal symbol, and if it is in the range of “0 to 4,205 to 239”, It is determined that the symbol is out of the ordinary pattern (see FIG. 81 (d)).

  In the process of S508, if the value of the during-hours-saving counter 203f is 0 (S508: No), the process proceeds to S511. In the process of S511, since the pachinko machine 10 is in the special symbol jackpot or the pachinko machine 10 is in the normal state of the normal symbol, the value of the second random number counter C4 obtained in the process of S507 and the low Based on the second random number table for probabilities, a lottery result is obtained as to whether or not a normal symbol has been won (S511). Specifically, the value of the second random number counter C4 is compared with the random number value stored in the second random number table for low probability. As described above, if the value of the second hit type counter C4 is in the range of “5 to 28”, it is determined that the hit is a normal symbol, and if the value is in the range of “0 to 4, 29 to 239”, It is determined that the symbol is out of the ordinary pattern (see FIG. 81 (d)).

  Next, it is determined whether the lottery result of the ordinary symbol acquired by the processing of S510 or S511 is a hit of the ordinary symbol (S512), and when it is determined that it is a hit of the ordinary symbol (S512: Yes). Then, the display mode of the hit is set (S513). In the process of S513, after the variable display on the second symbol display device 83 is completed, the symbol “O” is set to be lit and displayed as a stop symbol (second symbol).

  Then, it is determined whether or not the value of the time reduction counter 203f is 1 or more (S514). If the value of the time reduction counter 203f is 1 or more (S514: Yes), the special symbol is hit at the moment. It is determined whether or not it is (S515). If the result of the determination is that the special symbol is being hit (S515: Yes), the process proceeds to S517. In the present control example, during the special symbol big hit, in order to suppress the ball from entering the second winning opening 640 as much as possible, even if the normal symbol hits, similarly to the case where the normal symbol comes off. , The number of times and the opening time of the electric accessory 640a are set.

  In the process of S515, if the special symbol is not in the special jackpot (S515: No), the pachinko machine 10 is not in the special symbol jackpot and the pachinko machine 10 is in the normal symbol time saving state, so the second winning opening 640 Is set to one second, and the number of times of opening is set to two (S516), and the process proceeds to S519. In the process of S514, if the value of the time reduction counter 203f is 0 (S514: No), the process proceeds to S517. In the processing of S517, since the pachinko machine 10 is in the special symbol jackpot or the pachinko machine 10 is in the normal state of the normal symbol, the open period of the electric accessory 640a attached to the second winning opening 640 is set to 0. In addition to the setting of 2 seconds, the number of times of release is set to 1 (S517), and the process proceeds to S519.

  In the process of S512, when it is determined that the symbol is out of the ordinary pattern (S512: No), the display mode at the time of the out of pattern is set (S518). In the process of S518, after the variable display on the second symbol display device 83 is completed, a setting is made so that a symbol “x” is lit as a stopped symbol (second symbol). When the setting of the display mode at the time of departure is completed, the process proceeds to S519.

  In the processing of S519, it is determined whether the value of the time reduction counter 203f is 1 or more (S519). If the value of the time reduction counter 203f is 1 or more (S519: Yes), the fluctuation in the second symbol display device 83 is performed. The change time of the display is set to 3 seconds (S520), and the process ends. On the other hand, if the value of the counter 203f during time saving is 0 (S519: No), the fluctuation time of the fluctuation display on the second symbol display device 83 is set to 30 seconds (S521), and this processing ends. Thus, except during the special symbol jackpot, when the normal symbol has a high probability, the fluctuation display time is very short, "30 seconds → 3 seconds", compared to when the normal symbol has a low probability, and further, Since the release period of the second winning port 640 is very long, that is, “0.2 seconds × 1 time → 1 second × 2 times”, the ball can easily enter the second winning port 640.

  In the process of S502, if the display mode of the second symbol display device 83 is changing (S502: Yes), it is determined whether or not the change time of the variable display executed in the second symbol display device 83 has elapsed. (S522). Here, the fluctuation time is a time set beforehand by the processing of S520 or the processing of S521 before the fluctuation display is started on the second symbol display device 83.

  In the processing of S522, if the fluctuation time has not elapsed (S522: No), this processing ends. On the other hand, in the process of S522, if the variation time of the variation display being executed has elapsed (S522: Yes), the stop display of the second symbol display device 83 is set (S523). In the process of S523, the lottery of the ordinary symbol is a hit, and if the display mode is set by the process of S513, the symbol “○” as the second symbol is stopped and displayed on the second symbol display device 83 (lighting). Display). On the other hand, if the lottery of the ordinary symbol is lost and the display mode is set by the processing of S518, the “X” symbol as the second symbol is stopped (lit) on the second symbol display device 83. Is set to When the stop display is set by the process of S523, when the second symbol display updating process (see S907) of the main process (see FIG. 100) is executed next, the variable display on the second symbol display device 83 is changed. After finishing, the stopped symbol (the second symbol) is stopped (lit) on the second symbol display device 83 in the display mode set in the process of S513 or the process of S518.

  Next, when the variation display being executed on the second symbol display device 83 is started, whether the lottery result of the ordinary symbol performed by the ordinary symbol variation process (the current lottery result) is a hit of the ordinary symbol or not. Is determined (S524). If the current lottery result is a normal symbol hit (S524: Yes), the opening / closing control of the electric accessory 640a attached to the second winning opening 640 is set (S525), and this processing is ended. When the opening / closing control start of the electric accessory 640a is set by the process of S525, when the electric accessory opening / closing process (see S905) of the main process (see FIG. 100) is executed next, the electric accessory 640a is opened. The opening / closing control is started, and the opening / closing control of the electric accessory 640a is continued until the opening time and the number of times of opening set in the processing of S516 or S517 are completed. On the other hand, in the process of S524, if the current lottery result is out of the ordinary symbol (S524: No), the process of S525 is skipped, and the present process ends.

  Next, a through gate passage process (S107) executed by the MPU 201 in the main control device 110 will be described with reference to the flowchart in FIG. FIG. 97 is a flowchart showing this through gate passage processing (S107). This through gate passage processing (S107) is executed in the timer interruption processing (see FIG. 92), and it is determined whether or not a ball has passed through the normal entrance 67, and if a ball has passed, the first pass is performed. This is a process for acquiring and suspending the value indicated by the random number counter C4 per two.

  In the through gate passage process, first, it is determined whether or not the ball has passed the normal entrance 67 (S601). Here, the passage of a ball at the normal entrance 67 is detected over three timer interrupt processes. Then, when it is determined that the ball has passed the normal entrance 67 (S601: Yes), the value of the normal symbol holding ball number counter 203d (the number of times M of the variable display in the normal symbol is held) is acquired (S602). Then, it is determined whether or not the value (M) of the normal symbol reserved ball number counter 203d is less than the upper limit value (4 in this control example) (S603).

  Whether the ball has not passed through the normal entrance 67 (S601: No), or even if the ball has passed through the normal entrance 67, the value (M) of the ordinary symbol holding ball counter 203d is less than 4 If not (S603: No), this processing ends. On the other hand, if the ball passes through the normal entrance 67 (S601: Yes) and the value (M) of the ordinary symbol retaining ball number counter 203d is less than 4 (S603: Yes), the ordinary symbol retaining ball number counter The value (M) of 203d is incremented by 1 (S604). Then, the value of the second random number counter C4 updated in S103 of the above-described timer interrupt processing is stored in the first one of the free holding areas (first holding area to fourth holding area) of the ordinary symbol holding ball storage area 203b of the RAM 203. (S605), and the process ends. In the process of S605, the value of the normal symbol holding ball counter 203d is referred to, and if the value is 0, the holding first area is set as the first area. Similarly, if the value is 1, the reserved second area is set as the first area, if the value is 2, the reserved third area is set as the initial area, and if the value is 3, the reserved fourth area is set as the initial area.

  FIG. 98 is a flowchart showing the NMI interrupt processing executed by the MPU 201 in the main control device 110. The NMI interrupt process is a process executed by the MPU 201 of the main control device 110 when the power of the pachinko machine 10 is shut down due to a power failure or the like. By this NMI interrupt processing, the power-off occurrence information is stored in the RAM 203. That is, when the power of the pachinko machine 10 is cut off due to the occurrence of a power failure or the like, the power failure signal SG1 is output from the power failure monitoring circuit 252 to the NMI terminal of the MPU 201 in the main control device 110. Then, the MPU 201 interrupts the control being executed, starts the NMI interrupt process, stores the power-off occurrence information in the RAM 203 as the setting of the power-off occurrence information, and ends the NMI interrupt process (S701). I do.

  Note that the above-described NMI interrupt processing is executed in the same manner by the payout and departure control device 111, and the power-off occurrence information is stored in the RAM 213 by the NMI interrupt processing. That is, when the power of the pachinko machine 10 is cut off due to the occurrence of a power failure or the like, the power failure signal SG1 is output from the power failure monitoring circuit 252 to the NMI terminal of the MPU 211 in the payout control device 111, and the MPU 211 interrupts the control being executed. Thus, the NMI interrupt process is started.

  Next, with reference to FIG. 99, a description will be given of a start-up process executed by the MPU 201 in the main control device 110 when the main control device 110 is powered on. FIG. 99 is a flowchart showing the start-up process. This start-up process is started by a reset when the power is turned on. In the start-up process, first, an initial setting process accompanying power-on is executed (S801). For example, a predetermined value is set in the stack pointer. Next, a wait process (one second in this control example) is executed in order to wait until the sub-side control devices (peripheral control devices such as the voice lamp control device 113 and the payout control device 111) become operable. (S802). Then, access to the RAM 203 is permitted (S803).

  Thereafter, it is determined whether or not the RAM erase switch 122 (see FIG. 3) provided on the power supply 115 is turned on (S804). If it is turned on (S804: Yes), the process proceeds to S810. On the other hand, if the RAM erasure switch 122 is not turned on (S804: No), it is further determined whether or not power-off occurrence information is stored in the RAM 203 (S805). Since there is a possibility that the processing at the time of the previous power shutdown may not have been completed normally, the processing also shifts to S810 in this case.

  If the power-off occurrence information is stored in the RAM 203 (S805: Yes), the RAM determination value is calculated (S806). If the calculated RAM determination value is not normal (S807: No), that is, the calculated RAM If the determination value does not match the RAM determination value stored when the power is turned off, the backed-up data has been destroyed, and the process also shifts to S810 in such a case. The RAM determination value is, for example, a checksum value at the work area address of the RAM 203, as described later in the processing of S914 of the main processing (see FIG. 100). Instead of the RAM determination value, the validity of the backup may be determined based on whether or not the keyword written in a predetermined area of the RAM 203 is correctly stored.

  In the process of S810, a payout initialization command is transmitted to initialize the payout control device 111 serving as the sub-side control device (peripheral control device) (S810). Upon receiving the payout initialization command, the payout control device 111 clears an area (work area) other than the stack area of the RAM 213, sets an initial value, and enters a state where the payout control of the game ball can be started. After transmitting the pay-out initialization command, main controller 110 executes an initialization process of RAM 203 (S811, S812).

  As described above, in the pachinko machine 10, when the RAM data is initialized when the power is turned on, for example, when the hall is opened, the power is turned on while pressing the RAM erase switch 122. Therefore, if the RAM erasure switch 122 is pressed at the time of the start-up processing, the RAM initialization processing (S811, S812) is executed. Similarly, the initialization process of the RAM 203 (S811 and S812) is executed also when the power-off occurrence information is not set or when a backup abnormality is confirmed by the RAM determination value (checksum value or the like). . In the initialization processing of the RAM (S811, S812), the used area of the RAM 203 is cleared to 0 (S811), and thereafter, the initial value of the RAM 203 is set (S812). After the execution of the initialization process of the RAM 203, the process proceeds to S813.

  On the other hand, if the RAM erasure switch 122 is not turned on (S804: No), power-off occurrence information is stored (S805: Yes), and if the RAM determination value (checksum value, etc.) is normal (S804). S807: Yes), the power-off information is cleared while the data backed up in the RAM 203 is held (S808). Next, a payout return command at the time of power restoration for returning the sub-side control device (peripheral control device) to the gaming state at the time of driving power cutoff is transmitted (S809), and the process proceeds to S813. When the payout control device 111 receives the payout return command, the payout control device 111 is ready to start the payout control of the game balls while holding the data stored in the RAM 213.

  In the process of S813, the effect permission command is transmitted to the sound lamp control device 113, and the sound lamp control device 113 and the display control device 114 are permitted to execute various effects. Next, an interrupt is permitted (S814), and the process proceeds to a main process described later.

  Next, a main process executed by the MPU 201 in the main control device 110 after the above-described startup process will be described with reference to FIG. FIG. 100 is a flowchart showing the main processing. In this main processing, main processing of the game is executed. As an outline, each process of S901 to S907 is executed as a periodic process with a period of 4 ms, and the counter updating process of S910 and S911 is executed in the remaining time.

  In the main process, first, during execution of the timer interrupt process (see FIG. 92), output data such as commands stored in a command transmission ring buffer provided in the RAM 203 is transmitted to each of the sub-side control devices (peripheral devices). An external output process to be transmitted to the control device is executed (S901). Specifically, the presence / absence of winning detection information detected in the switch reading process in S101 in the timer interrupt process (see FIG. 92) is determined. Send a prize ball command. In addition, the CPU transmits the number-of-remaining-balls command set in the special symbol change process (see FIG. 93) and the start winning process (see FIG. 95) to the sound lamp control device 113. Further, the winning information command set in the starting winning process (see FIG. 95) is transmitted to the sound lamp control device 113. Further, by this external output processing, a variation pattern command, a stop type command, and the like necessary for the variation display of the third symbol by the third symbol display device 81 are transmitted to the sound lamp control device 113. Further, the opening command, the number of rounds command, and the ending command set in the jackpot control process (see FIG. 101) are transmitted to the sound lamp control device 113. In addition, when launching a ball, a ball launch signal is transmitted to the launch control device 112.

  Next, the value of the variation type counter CS1 is updated (S902). Specifically, the variation type counter CS1 is incremented by one, and is cleared to zero when the counter value reaches a maximum value (198 in this control example). Then, the updated value of the variation type counter CS1 is stored in a corresponding buffer area of the RAM 203.

  When the variation type counter CS1 is updated, the winning ball counting signal and the abnormal payout signal received from the payout control device 111 are read (S903). A jackpot control process for opening or closing the specific winning port (large opening port) 65a of the winning device 65 is executed (S904). In the jackpot control process, the specific winning port 65a is opened in each round of the jackpot state, and it is determined whether the maximum opening time of the specific winning port 65a has elapsed or the specified number of balls have been won in the specific winning port 65a. When any one of these conditions is satisfied, the specific winning opening 65a is closed. The opening and closing of the specific winning opening 65a is repeatedly executed a predetermined number of rounds. In the present control example, the jackpot control process (S904) is executed in the main process, but may be executed in the timer interrupt process.

  Next, an electric accessory opening / closing process for controlling opening / closing of the electric accessory 640a associated with the second winning opening 640 is executed (S905). In the electric auditors product opening / closing process, the opening / closing control of the electric auditors accessory 640a is started when the opening / closing control start of the electric auditors accessory 640a is set by the process of S525 of the normal symbol variation process (see FIG. 96). The opening / closing control of the electric accessory 640a is continued until the opening time and the number of times of opening set in the processing of S516 or the processing of S517 in the normal symbol variation processing are ended.

  Next, a first symbol display update process for updating the display of the first symbol display device 37 is executed (S906). In the first symbol display updating process, when a variation pattern is set by the process of S307 or the process of S309 of the special symbol variation start process (see FIG. 94), the variation display according to the variation pattern is performed by the first symbol display. Beginning at device 37. In this control example, of the LEDs 37A and 37B of the first symbol display device 37, for example, if the currently lit LED is red until the fluctuation time elapses after the fluctuation starts, the red LED Is turned off and the green LED is turned on. If the green LED is turned on, the green LED is turned off and the blue LED is turned on. If the blue LED is turned on, the blue LED is turned on. Is turned off and the red LED is turned on.

  The main processing is executed every 4 milliseconds. However, if the lighting color of the LED is changed each time the main processing is executed, the player cannot confirm the change in the lighting color of the LED. Therefore, a counter (not shown) is counted by one each time the main process is executed so that the player can confirm the change of the lighting color of the LED. Change the lighting color of. That is, the lighting color of the LED is changed every 0.4 seconds. The value of the counter is reset to 0 when the lighting color of the LED is changed.

  In the first symbol display updating process, when the variation time corresponding to the variation pattern set by the process of S307 or the process of S309 of the special symbol variation start process (see FIG. 94) ends, the first symbol display device is activated. The variable display executed in 37 is ended, and the stopped symbol (first symbol) is displayed in the first symbol display in the display mode set by the process of S306 or the process of S308 of the special symbol variation start process (see FIG. 94). A stop display (lighting display) is displayed on the device 37.

  Next, a second symbol display update process for updating the display of the second symbol display device 83 is executed (S907). In the second symbol display updating process, when the variation time of the second symbol is set by the process of S520 or the process of S521 of the ordinary symbol variation process (see FIG. 96), the variation display is started on the second symbol display device 83. I do. As a result, the second symbol display device 83 performs a variable display in which the symbol “O” and the symbol “X” as the second symbol are alternately turned on. In the second symbol display updating process, when the stop display of the second symbol display device 83 is set by the process of S523 of the ordinary symbol variation process (see FIG. 96), the process is executed by the second symbol display device 83. Is stopped, and the stopped symbol (second symbol) is stopped and displayed on the second symbol display device 83 in the display mode set by the process of S513 or the process of S518 of the normal symbol variation process (see FIG. 96). Lights up).

  Thereafter, it is determined whether or not power-off occurrence information is stored in the RAM 203 (S908). If power-off occurrence information is not stored in the RAM 203 (S908: No), the power failure monitoring circuit 252 sends a power failure signal. SG1 is not output, and the power is not cut off. Therefore, in such a case, it is determined whether or not the next main processing execution timing has been reached, that is, whether or not a predetermined time (4 ms in this control example) has elapsed from the start of the current main processing (S909). If the predetermined time has already passed (S909: Yes), the process proceeds to S901, and the above-described processes after S901 are repeatedly executed.

  On the other hand, if the predetermined time has not yet elapsed from the start of the main processing this time (S909: No), during the remaining time until the predetermined time, that is, the remaining time until the next main processing execution timing is reached, The first initial value random number counter CINI1, the second initial value random number counter CINI2, and the variation type counter CS1 are repeatedly updated (S910, S911).

  First, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are updated (S910). Specifically, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are incremented by one, and cleared to 0 when the counter value reaches the maximum value (299, 239 in this control example). . Then, the updated values of the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are stored in the corresponding buffer areas of the RAM 203, respectively. Next, the variation type counter CS1 is updated by the same method as the process of S902 (S911).

  Here, since the execution time of each processing of S901 to S907 changes according to the state of the game, the remaining time until the execution timing of the next main processing is not constant but fluctuates. Therefore, by repeatedly executing the updating of the first initial value random number counter CINI1 and the second initial value random number counter CINI2 using the remaining time, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 (that is, , The initial value of the first random number counter C1 and the initial value of the second random number counter C4), and similarly, the fluctuation type counter CS1 can be updated at random.

  In addition, in the process of S908, if the power-off occurrence information is stored in the RAM 203 (S908: Yes), the power is shut off due to the occurrence of the power failure or the power-off, and the power failure monitoring circuit 252 outputs the power failure signal SG1. As a result, since the NMI interrupt processing of FIG. 98 has been executed, the processing at the time of power shutdown after S912 is executed. First, the occurrence of each interrupt process is prohibited (S912), and a power-off command indicating that the power is turned off is sent to another control device (a peripheral control device such as the payout control device 111 or the sound lamp control device 113). (S913). Then, the RAM determination value is calculated, the value is stored (S914), access to the RAM 203 is prohibited (S915), and the infinite loop is continued until the power is completely shut off and the process cannot be executed. Here, the RAM determination value is, for example, a checksum value in a stack area and a work area of the RAM 203 to be backed up.

  Note that the process of S908 is performed at the end of a series of processes corresponding to game state changes performed in S901 to S907, or at the end of one cycle of the processes of S910 and S911 performed within the remaining time. It is running. Therefore, in the main processing of the main control device 110, the power-off occurrence information is checked at the timing when each setting is completed. Therefore, when returning from the power-off state, the processing is performed after the startup processing is completed. The processing can be started from the processing of S901. That is, the process can be started from the process of S901, as in the case where the process is initialized in the startup process. Therefore, in the process at the time of power-off, even if the contents of each register used by the MPU 201 are not saved to the stack area or the value of the stack pointer is not saved, the stack When the pointer is set to a predetermined value (initial value), the processing can be started from the processing of S901. Therefore, the control load on main controller 110 can be reduced, and accurate control can be performed without erroneous operation or runaway of main controller 110.

  Next, the jackpot control process (S904) executed by the MPU 201 in the main control device 110 will be described with reference to the flowchart in FIG. FIG. 101 is a flowchart showing the jackpot control process (S904). This jackpot control process (S904) is executed in the main process (see FIG. 100), and when the pachinko machine 10 is in the special symbol jackpot state, execution of various effects according to the jackpot and a specific winning opening ( This is a process for opening or closing the large opening port 65a.

  In the jackpot control process, first, it is determined whether a special symbol jackpot is started (S1001). Specifically, the process of S213 of the special symbol variation process (see FIG. 93) is executed, and if the start of the special symbol big hit is set, it is determined that the special symbol big hit is started. In the process of S1001, if a special symbol jackpot is started (S1001: Yes), an opening command is set (S1002), and the process ends.

  The opening command set here is stored in a command transmission ring buffer provided in the RAM 203, and is used in the external output processing (S901) of the main processing (see FIG. 100) executed by the MPU 201, in the sound ramp control. It is transmitted to the device 113. Upon receiving the opening command, the sound lamp control device 113 transmits a display opening command to the display control device 114. When a display opening command is received by the display control device 114, an opening effect is started in the third symbol display device 81.

  On the other hand, if the special symbol jackpot has not been started in the processing of S1001 (S1001: No), it is determined whether or not the special symbol jackpot is in progress (S1003). During the special symbol jackpot, the first symbol display device 37 and the third symbol display device 81 display a special symbol jackpot (including a special symbol jackpot game), and the special symbol jackpot. During the predetermined time after the end of the big hit game. In the processing of S1003, if it is not during the special symbol big hit (S1003: No), this processing is ended as it is.

  On the other hand, in the process of S1003, if the special symbol is in a big hit (1003: Yes), it is determined whether it is the start timing of a new round (S1004). If it is the start timing of a new round (S1004: Yes), the special winning opening (large opening) 65a is opened (S1005), and a round number command indicating the number of newly started rounds is set (S1006). After setting the number-of-rounds command, the process ends. The round number command set here is stored in a command transmission ring buffer provided in the RAM 203, and is used as an audio lamp in the external output processing (S901) of the main processing (see FIG. 100) executed by the MPU 201. It is transmitted to the control device 113. When receiving the round number command, the sound ramp control device 113 extracts the round number from the round number command. Then, a display round number command corresponding to the extracted round number is transmitted to the display control device 114. When the display control device 114 receives the display round number command, the third symbol display device 81 starts a new round effect.

  On the other hand, in the process of S1004, if it is not the start timing of a new round (S1004: No), it is determined whether the closing condition of the specific winning opening (large opening) 65a is satisfied (S1007). Specifically, when a predetermined time (for example, 30 seconds) has elapsed after opening the specific winning opening (large opening) 65a, or when a predetermined number of balls have been released after opening the specific winning opening (large opening) 65a. When winning (for example, 10), it is determined that the closing condition is satisfied.

  In the processing of S1007, when the closing condition of the specific winning opening (large opening) 65a is satisfied (S1007: Yes), the specific winning opening (large opening) 65a is closed (S1008), and this processing ends. I do. On the other hand, when the closing condition of the specific winning opening (large opening) 65a is not satisfied (S1007: No), it is determined whether it is the timing to start the ending effect (S1009). Specifically, when the special game state (all 16 or 4 rounds) in which a larger amount of prize balls are paid out than usual is completed, it is determined that it is time to start the ending effect.

  In the processing of S1009, if it is the ending effect start timing (S1009: Yes), the ending command is set (S1010). The ending command set here is stored in a ring buffer for command transmission provided in the RAM 203, and is used in the external output processing (S901) of the main processing (see FIG. 100) executed by the MPU 201 to control the sound ramp control. It is transmitted to the device 113. Upon receiving the ending command, the sound ramp control device 113 selects the display mode of the ending effect based on the winning information stored in the winning information storage area 223a of the RAM 223. Then, a display ending command corresponding to the display mode of the selected ending effect is transmitted to the display control device 114. When the display ending command is received by the display control device 114, an ending effect is started in the third symbol display device 81. Next, it is determined whether or not the current jackpot is the jackpot A or the jackpot B (S1011). If the jackpot A or the jackpot B is determined (S1011: Yes), the high probability of the special symbol after the end of the jackpot A or the jackpot B is determined. In order to shift to the state, the probable changing flag 203e is set to ON (S1012), and the process shifts to S1015.

  In the process of S1011, when it is determined that the current jackpot is not the jackpot A or the jackpot (that is, the jackpot C or the jackpot D), after the jackpot C or the jackpot D ends, the normal symbol is shifted to the time saving state. Then, the probable changing flag 203e is set to off (S1013), the value of the time reduction counter 203f is set to 100 (S1014), and the process proceeds to S1015. In the processing of S1015 executed after the processing of S1013 or S1014, the end of the jackpot is set, and this processing ends.

  On the other hand, if it is not the ending start timing in the process of S1009 (S1009: No), the process ends. By the jackpot control process (see FIG. 101), various settings relating to the jackpot can be performed.

<Regarding the control processing of the audio lamp control device in the first control example>
Next, each control process executed by the MPU 221 in the audio lamp control device 113 will be described with reference to FIGS. The processes of the MPU 221 are roughly classified into a start-up process started upon power-on and a main process executed after the start-up process.

  First, with reference to FIG. 102, a start-up process executed by the MPU 221 in the audio lamp control device 113 will be described. FIG. 102 is a flowchart showing the start-up processing. This startup process is started when the power is turned on.

  When the start-up process is executed, first, an initial setting process accompanying power-on is executed (S1101). Specifically, a predetermined value is set in the stack pointer. Thereafter, depending on whether or not the power-off processing flag is turned on, the current start-up processing is performed during the execution of the power-off processing in S1217 due to a momentary voltage drop (a momentary power failure, so-called “momentary power failure”). It is determined whether or not it has been started (S1102). As will be described later with reference to FIG. 103, upon receiving the power-off command from main controller 110 (see S1214 in FIG. 103), sound lamp control device 113 executes the power-off process in S1217. The power-off processing flag is turned on before the power-off processing is performed, and the power-off processing flag is turned off after the power-off processing ends. Therefore, whether or not the power-off processing of S1217 is being performed can be determined based on the state of the power-off processing flag.

  If the power-off processing flag is off (S1102: No), the current startup processing is started after the power is completely cut off, or after a momentary power failure occurs, and the power-off processing in S1217 is performed. It is started after the execution of the process is completed, or started only by resetting the MPU 221 of the sound lamp control device 113 due to noise or the like (without receiving a power-off command from the main control device 110). is there. Therefore, in these cases, it is confirmed whether the data in the RAM 223 has been destroyed (S1103).

  Confirmation of data destruction of the RAM 223 is performed as follows. That is, data as a keyword of “55AAh” is written in a specific area of the RAM 223 by the process of S1106. Therefore, the data stored in the specific area is checked, and if the data is “55AAh”, the data is not destroyed in the RAM 223. Conversely, if the data is not “55AAh”, the data is destroyed in the RAM 223. If the data destruction of the RAM 223 is confirmed (S1103: Yes), the process proceeds to S1104 and the initialization of the RAM 223 is started. On the other hand, if data destruction of the RAM 223 is not confirmed (S1103: No), the process proceeds to S1108.

  If the current startup process is started after the power supply is completely shut off, the keyword “55AAh” is not stored in the specific area of the RAM 223 (the storage in the RAM 223 is lost due to the power cutoff). ), It is determined that the data in the RAM 223 has been destroyed (S1103: Yes), and the flow shifts to S1104. On the other hand, this startup process is started after an instantaneous power failure occurs and after the execution of the power-off process in S1217 is completed, or is reset only to the MPU 221 of the sound lamp control device 113 due to noise or the like. Is started, the keyword of "55AAh" is stored in the specific area of the RAM 223, so that the data of the RAM 223 is determined to be normal (S1103: No), and the process proceeds to S1108.

  If the power-off processing flag is on (S1102: Yes), this startup processing is performed after a momentary power failure occurs, and during the execution of the power-off processing in S1217, the audio lamp control device 113 Of the MPU 221 has been reset. In such a case, since the power-off process is being performed, the storage state of the RAM 223 is not always correct. Therefore, in such a case, the control cannot be continued, and the process shifts to S1104 to start initialization of the RAM 223.

  In the process of S1104, the storage area of the entire range of the RAM 223 is checked (S1104). As a checking method, first, "0FFh" is written for each byte, and it is read for each byte to check whether it is "0FFh". If "0FFh", it is determined that it is normal. Such writing and checking for each byte is performed in the order of “55h”, “0AAh”, and “00h” after “0FFh”. By this read / write check of the RAM 223, all storage areas of the RAM 223 are cleared to zero.

  If the read / write check is determined to be normal for all the storage areas of the RAM 223 (S1105: Yes), the keyword “55AAh” is written to the specific area of the RAM 223, and the RAM destruction check data is set (S1106). By confirming the keyword “55AAh” written in the specific area, it is checked whether or not data is destroyed in the RAM 223. On the other hand, if an abnormality of the read / write check is detected in any of the storage areas of the RAM 223 (S1105: No), the abnormality of the RAM 223 is notified (S1107), and an infinite loop is performed until the power is cut off. The abnormality of the RAM 223 is notified by the display lamp 34. Note that the sound output device 226 may output a sound to notify the abnormality of the RAM 223, or may transmit an error command to the display control device 114 to display an error message on the third symbol display device 81. It may be.

  In the process of S1108, it is determined whether or not the power-off flag is turned on (S1108). The power-off flag is turned on when the power-off process is performed in S1217 (see S1216 in FIG. 103). In other words, since the power-off flag is turned on before the power-off process in S1217 is executed, the process starting at S1108 with the power-off flag turned on is the instantaneous start-up process. This is a case where the process is started after the occurrence of the power failure and in a state where the execution of the power-off process in S1217 is completed. Therefore, in such a case (S1108: Yes), the work area of the RAM is cleared to initialize each process of the audio ramp control device 113 (S1109), and the initial value of the RAM 223 is set (S1110). The permission is set (S1111), and the process proceeds to the main processing. Note that the work area of the RAM 223 is an area other than an area for storing commands and the like received from the main control device 110.

  On the other hand, the reason why the process of step S1108 is reached with the power-off flag turned off is that the start-up process of this time is started after the power is completely cut off, for example, and the process of step S1108 is performed via the process from step S1104 to step S1106. This is the case where the processing has been reached or the MPU 221 of the sound lamp control device 113 has been reset only (without receiving a power-off command from the main control device 110) due to noise or the like and started. Therefore, in such a case (S1108: No), the process skips S1109, which is the process of clearing the work area of the RAM 223, shifts the process to S1110, sets the initial value of the RAM 223 (S1110), and sets the interrupt permission. Then (S1111), and shifts to the main processing.

  The reason why the clearing process of S1109 is skipped is that when the process from S1104 to the process of S1108 is performed via the process of S1106, all the storage areas of the RAM 223 have already been cleared by the process of S1104. When the MPU 221 of the sound lamp control device 113 is reset only due to noise or the like and the start-up process is started, the data in the work area of the RAM 223 is stored without being cleared, thereby saving the sound lamp control device 113. Can be continued.

  Next, a main process executed by the MPU 221 in the audio ramp control device 113 after the startup process of the audio ramp control device 113 will be described with reference to FIG. FIG. 103 is a flowchart showing this main processing. When the main processing is executed, first, it is determined whether or not 1 ms or more has elapsed since the main processing was started or since the previous processing of S1201 was executed (S1201). If not (S1201: No), the process proceeds to S1212 without performing the processes of S1202 to S1311. In the processing of S1201, it is determined whether or not 1 ms has elapsed. The processing in S1202 to S1311 is mainly for display (production), and it is not necessary to edit in a short cycle (within 1 msec). , S1212, and the variable display setting process of S1213 are preferably executed in a short cycle. By executing the processing of S1212 in a short cycle, it is possible to prevent omission of a command transmitted from the main control device 110, and by executing the processing of S1213 in a short cycle, a command received by the command determination processing can be prevented. Based on the above, it is possible to make settings relating to the fluctuation effect without delay.

  If 1 ms or more has elapsed in the process of S1201 (S1201: Yes), first, various commands for the display control device 114 set by the processes of S1203 to S1213 are transmitted to the display control device 114 (S1202). ). Next, the setting of the lighting mode of the display lamp 34 and the output of each lamp are set so as to be the lighting mode of the lamp edited in the process of S1208 described later (S1203), and thereafter, the power-on notification process is executed (S1204). The power-on notification processing is to perform notification for notifying that the power has been turned on for a predetermined time (for example, 30 seconds) when the power is turned on, and the notification is performed by the audio output device 226 or the lamp display device 227. Be done. Further, a command may be transmitted to the display control device 114 to notify that power has been supplied on the screen of the third symbol display device 81. If the power is not turned on, the process proceeds to S1205 without performing notification by the power-on notification process.

  In the process of S1205, a customer waiting effect process is executed, and thereafter, a held number display update process is executed (S1206). In the customer waiting effect process, when the pachinko machine 10 has not been played by the player for a predetermined period of time, a setting for switching the display of the third symbol display device 81 to the title screen is performed, and the setting is used as a command for display control. Sent to device 114. In the reserved number display update process, a process of lighting a reserved lamp (not shown) according to the value of the special symbol reserved ball number counter 223b is performed.

  Thereafter, the SW input monitoring and effect processing is executed (S1207). In this SW input monitoring / production process, the input of whether or not the frame button 22 or the selection switch 270 operated by the player has been pressed to enhance the production effect is monitored, and the input of the frame button 22 or the like is confirmed. This is a process for setting to perform an effect corresponding to the case. In this process, when an operation by the player such as the frame button 22 is detected, a SW-related command based on the switch operated on the display control device 114 is set. The details of the SW input monitoring and effect processing will be described later with reference to FIG.

  When the SW input monitoring / production process is completed, a lamp editing process is executed (S1208), and then a sound editing / output process is executed (S1209). In the lamp editing process, the lighting patterns of the illumination units 29 to 33 are set so as to correspond to the display performed by the third symbol display device 81. In the sound editing / output processing, the output pattern of the sound output device 226 is set so as to correspond to the display performed by the third symbol display device 81, and the sound is output from the sound output device 226 according to the setting.

  After the processing of S1209, a liquid crystal effect execution management processing is executed (S1210). In the liquid crystal effect execution management processing, a time synchronized with the time required for the fluctuation display performed by the third symbol display device 81 is set based on the fluctuation pattern command transmitted from the main controller 110. The lamp editing process of S1208 is executed based on the time set in the liquid crystal effect execution monitoring process. Note that the sound editing / output processing in S1209 is also executed at a time synchronized with the time required for the variable display performed by the third symbol display device 81.

  When the processing in S1210 ends, the effect counter 223i is updated (S1211). The effect counter updated here is used for selection of an effect when the frame button 22 is pressed in the super reach B described above. In the present control example, the effect counter 223i is updated in the main process. However, the present invention is not limited to this, and the update may be performed by providing an interrupt process.

  After the processing of S1211 is completed, a command determination processing for performing processing according to the command received from main controller 110 is executed (S1212). Details of this command determination processing will be described later with reference to FIG. Then, after the command determination processing, the variable display setting processing is executed (S1213). In the variation display setting process, a variation pattern command for display is generated and set based on the variation pattern command received from the main controller 110 in order to cause the third symbol display device 81 to execute the variation effect. As a result, the command is transmitted to the display control device 114. The details of the variable display setting process will be described later with reference to FIG.

  When the processing in S1213 is completed, it is determined whether or not the power-off occurrence information is stored in the work RAM 233 (S1214). The power-off information is stored when a power-off command is received from main controller 110. In the processing of S1214, when it is determined that the information of the occurrence of the power-off is stored (S1214: Yes), both the power-off flag and the power-off processing flag are turned on (S1216), and the power-off processing is executed. (S1217). After the execution of the power-off processing, the power-off processing-in-progress flag is turned off (S1218), and thereafter, the processing is in an infinite loop. In the power-off process, the occurrence of the interrupt process is prohibited, and each output port is turned off to turn off the output from the audio output device 226 and the lamp display device 227. Further, the storage of the information of the occurrence of the power interruption is also deleted.

  On the other hand, if power-off occurrence information is not stored in the process of S1214 (S1214: No), it is determined whether or not the RAM 223 is destroyed based on the keyword stored in the RAM 223 (S1215), and the RAM 223 is destroyed. If not (S1215: No), the process returns to S1201, and the main process is repeatedly executed. On the other hand, if the RAM 223 has been destroyed (S1215: Yes), the processing is executed in an infinite loop to stop the execution of the subsequent processing. Here, if it is determined that the RAM is destroyed and an infinite loop is performed, the main processing is not executed, and thereafter the display by the third symbol display device 81 does not change. Therefore, since the player can know that the abnormality has occurred, the player can call a store clerk of the hall or the like and request the pachinko machine 10 to be repaired. Further, when it is confirmed that the RAM 223 is destroyed, the sound output device 226 or the lamp display device 227 may be used to notify the RAM breakdown.

  Next, the command determination process (S1212) executed by the MPU 221 in the audio lamp control device 113 will be described with reference to FIG. FIG. 104 is a flowchart showing this command determination processing (S1212). This command determination process (S1212) is executed in the main process (see FIG. 103) executed by the MPU 221 in the audio lamp control device 113, and determines the command received from the main control device 110 as described above. .

  In the command determination process, first, among the unprocessed commands, the first command received from the main control device 110 is read from the command storage area provided in the RAM 223, analyzed, and the variation pattern command is received from the main control device 110. It is determined whether or not it has been performed (S1301). When a variation pattern command is received (S1301: Yes), the variation start flag 223c provided in the RAM 223 is turned on (S1302), and a variation pattern selection for extracting a variation pattern type from the received variation pattern command is performed. The process is executed (S1303), and the process returns to the main process. The variation pattern type extracted here is stored in the RAM 223, and is referred to when a later-described variation display setting process (see FIG. 105) is executed. It is used to set a display variation pattern command for notifying the display controller 114 of the start of the variation effect and the variation pattern type.

  On the other hand, if the fluctuation pattern command has not been received (S1301: No), it is then determined whether a stop type command has been received from the main control device 110 (S1304). If the stop type command is received (S1304: Yes), the stop type selection flag 223d of the RAM 223 is set to ON (S1305), and the stop type is extracted from the received stop type command (S1306). Return to processing. The stop type extracted here is stored in the RAM 223 and is referred to when a later-described variable display setting process (see FIG. 105) is executed. Then, it is used to set a display stop type command for notifying the display control device 114 of the stop type of the variable effect.

  On the other hand, if the stop type command has not been received (S1304: No), then it is determined whether or not a pending ball count command has been received from the main controller 110 (S1307). Then, when the reserved ball number command is received (S1307: Yes), the value included in the received reserved ball number command, that is, the value of the special symbol reserved ball number counter 203c of the main control device 110 (special symbol) Is extracted and stored in the special symbol reserved ball number counter 223b of the voice lamp control device 113 (S1308). In the process of S1308, a display reserved ball count command for notifying the display control device 114 of the updated value of the special symbol reserved ball count counter 223b is set. After the end of the process in S1308, the process returns to the main process.

  Here, the reserved ball number command is transmitted from the main control device 110 when the ball wins (starts winning) in the first winning opening 64 or when a special symbol is drawn, so that the starting winning is determined. Every time it is detected or every time a special symbol lottery is performed, the value of the special symbol retaining ball number counter 223b of the voice lamp control device 113 is changed by the processing of S1308 to the special symbol retaining ball number counter 203c of the main control device 110. Can be adjusted to the value of Therefore, even if the value of the special symbol reserved ball number counter 223b of the audio lamp control device 113 deviates from the value of the special symbol reserved ball number counter 203c of the main control device 110 due to the influence of noise, etc. At the time of symbol lottery, the value of the special symbol reserved ball number counter 223b of the audio lamp control device 113 can be corrected to match the value of the special symbol reserved ball number counter 203c of the main control device 110. When the process of S1408 is executed, a display reserved ball count command for notifying the display control device 114 of the updated value of the special symbol reserved ball count counter 223b is set. As a result, in the display control device 114, the number-of-reserved-balls symbol corresponding to the number of retained balls is displayed on the third symbol display device 81.

  In the processing of S1307, when the command of the number of reserved balls is not received (S1307: No), it is determined whether or not the winning command is received from the main control device 110 (S1309). When the opening command is received (S1309: Yes), winning information is extracted from the received command, stored in the winning information storage area 223a (S1310), and a display winning command based on the winning information is set. (S1311), and returns to the main processing. The display winning command set here is stored in the command transmission ring buffer provided in the RAM 223, and is displayed in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the control device 114. When the display control device 114 receives the display winning command, the third symbol display device 81 stores the winning information in the winning information storage area 233k.

  In the processing of S1309, if the command of the number of pending balls has not been received (S1309: No), then it is determined whether or not an opening command has been received from main controller 110 (S1312). Then, when the opening command is received (S1312: Yes), a display opening command for causing the third symbol display device 81 to execute an opening effect is set (S1313), and the process returns to the main processing. The display opening command set here is stored in the command transmission ring buffer provided in the RAM 223, and is displayed in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the control device 114. Upon receiving the display opening command, the display control device 114 starts an opening effect on the third symbol display device 81.

  On the other hand, if the opening command has not been received in the process of S1312 (S1312: No), then it is determined whether or not a round number command has been received from the main controller 110 (S1314). When the round number command is received (S1314: Yes), the number of rounds is extracted from the received round number command (S1315), and a display round number command corresponding to the extracted round number is set (S1315). S1316), and terminates the process. The display round number command set here is stored in a command transmission ring buffer provided in the RAM 223, and is included in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the display control device 114. When the display control device 114 receives the display round number command, the third symbol display device 81 starts a new round effect.

  On the other hand, in the processing of S1314, if the round number command has not been received (S1314: No), then it is determined whether or not an ending command has been received from main controller 110, and if the ending command has been received (S1317: Yes), an ending command for display is set (S1318), and this processing ends. The display ending command set here is stored in the command transmission ring buffer provided in the RAM 223, and is displayed in the command output process (S1202) of the main process (see FIG. 103) executed by the MPU 221. It is transmitted to the control device 114. When receiving the display ending command, the display control device 114 starts an ending effect in the third symbol display device 81.

  On the other hand, if the ending command has not been received in the process of S1317 (S1317: No), it is determined whether or not another command has been received, and the process corresponding to the received command is executed (S1319). ), And return to the main processing. For example, if the other command is a command used by the sound lamp control device 113, a process corresponding to the command is performed, the processing result is stored in the RAM 223, and if the command is a command used by the display control device 114, the command is displayed. The command is set to be transmitted to the device 114.

  By this processing, a command for performing various settings for the display control device 114 can be set based on the command output from the main control device 110.

  Next, the variable display setting process (S1213) executed by the MPU 221 in the audio lamp control device 113 will be described with reference to FIG. FIG. 105 is a flowchart showing the variable display setting process (S1213). This variable display setting process (S1213) is executed in the main process (see FIG. 103) executed by the MPU 221 in the audio lamp control device 113. In order to execute a variable effect on the third symbol display device 81, A display variation pattern command is generated and set based on the variation pattern command received from main controller 110.

  In the variation display setting process, first, it is determined whether or not a variation start flag 223c provided in the RAM 223 is turned on (S1401). If it is determined that the variation start flag 223c is not on (that is, it is off) (S1401: No), it means that the variation pattern command has not been received from the main control device 110, and the process proceeds to S1406. Transition. On the other hand, when it is determined that the change start flag 223c is on (S1401: Yes), the change start flag 223c is turned off (S1402), and then, in the process of S1303 of the command determination process (see FIG. 104), the change pattern is set. The variation pattern type in the variation effect extracted from the command is obtained from the RAM 223 (S1403).

  Then, a display variation pattern command for notifying the display control device 114 is generated based on the acquired variation pattern type, and the command is set to be transmitted to the display control device 114 (S1404). The display control device 114 receives the display variation pattern command, so that the third symbol display device 81 performs the variation display of the third symbol in the variation pattern indicated by the display variation pattern command. The display control of the variable effect is started.

  Next, a selected SW valid period is set based on the high-speed fluctuation period (S1405). Based on the selected SW valid period set here, in the SW input monitoring / producing process (see FIG. 106) to be described later, the super background operation process for performing the switch operation process at the time of the super background notice is executed. Become.

  After finishing the process of S1405, it is determined whether or not the variation pattern is a SW effect (S1406). In the process of S1406, when it is determined that the variation pattern is the SW effect (that is, super reach A or super reach B), the frame SW valid period 223f and the replacement timing 223g are set based on the variation pattern. , To S1408. On the other hand, if it is determined in the processing of S1406 that the fluctuation pattern is not the SW effect (that is, super reach A or super reach B), the process of S1407 is skipped, and the process proceeds to S1408.

  In the process of S1408, a process of sequentially shifting the data stored in the first to fourth areas of the winning information storage area 223a to the execution area side is performed (S1408). More specifically, the data in each area is shifted in the order of first area → execution area, second area → first area, third area → second area, fourth area → third area, and so on. After shifting the data, the flow shifts to the process of S1409.

  In the processing of S1409, it is determined whether or not the stop type selection flag 223d provided in the RAM 233 is ON (S1409). If it is determined that the stop type selection flag 223d is not on (that is, it is off) (S1409: No), the stop type command has not been received from the main control device 110, so that the variable display is performed. The setting process ends, and the process returns to the main process. On the other hand, when it is determined that the stop type selection flag 223d is on (S1409: Yes), the stop type selection flag 223d is turned off (S1410), and then, in the process of S1306 of the command determination process (see FIG. 104), The stop type in the fluctuation effect extracted from the stop type command is acquired from the RAM 223 (S1411).

  Next, a display stop type command for notifying the display control device 114 is generated based on the stop type specified by the stop type command from the main control device 110, and the command is transmitted to the display control device 114. (S1412), and the process ends. The display control device 114 receives the stop type command for display, so that the stop symbol corresponding to the stop type indicated by the stop type command for display is stopped and displayed on the third symbol display device 81. The stop display of the fluctuation effect is controlled.

  Here, the SW input monitoring and effect processing (S1207) executed by the MPU 221 in the audio lamp control device 113 will be described with reference to FIG. FIG. 105 is a flowchart showing the SW input monitoring and effect processing (S1207). This SW input monitoring and effect processing (S1207) is executed in the main process (see FIG. 103) executed by the MPU 221 in the audio lamp control device 113, and causes the effect based on the operation of the frame button 22 and the like. For this purpose, a display command based on the operated switch is generated and set.

  In the SW input monitoring / effect processing (S1207), first, it is determined whether or not the selected SW is valid (S1501). As described above, whether or not the selected SW is valid is set based on the high-speed fluctuation period in the processing of S1405 of the fluctuation display setting processing (see FIG. 105).

  In the processing of S1501, if it is determined that the selected SW is valid (S1501: Yes), the operation processing at the time of the super background, which is the operation processing when the super background notice is executed, is performed (S1502). To end.

  Here, the super-background operation process (S1502) will be described with reference to FIG. FIG. 105 is a flowchart showing the super background operation process (S1502). The super-background operation process (S1502) is executed in the SW input monitoring / producing process (see FIG. 106) executed by the MPU 221 in the audio lamp control device 113, and switches such as the selection switch 270 in the super-background notice This is a process of generating and setting a display command based on the operated switch in order to execute an effect based on the operation.

  In the super background operation process (S1502), first, it is determined whether or not the frame button 22 has been pressed (S1601). If it is determined in step S1601 that the frame button 22 has been pressed (S1601: Yes), a background image change command is set (S1602), and the process ends. By receiving the background image change command, the display control device 114 changes the background image (such as a super background notice image or a normal background image).

  On the other hand, if it is determined in step S1601 that the frame button 22 has not been pressed (S1601: No), it is determined whether or not the enter switch 270e has been pressed (S1603). If it is determined in step S1603 that the determination switch 270e has been pressed (S1603: Yes), a display determination SW pressing command is set (S1604), and the process ends. The display control device 114 changes the background image to the special background by receiving the display determination SW command while the specific image of the super background notice is being displayed.

  On the other hand, if it is determined in the processing of S1603 that the determination switch 270e has not been pressed (S1603: No), it is determined whether any of the selection switches 270a to 270d has been pressed (S1605). If it is determined in step S1605 that any of the selection switches 270a to 270d has been pressed (S1605: Yes), a display selection SW pressing command is set based on the pressed selection switch (270a to 270d). (S1606), this process ends. When the display control device 114 receives the display selection SW command during the display of the super background notice, the scroll direction of the super background notice is changed based on the operated selection switch.

  Returning to FIG. 106, the description will be continued. In the process of S1501, if it is determined that the current period is not the selected SW valid period (S1501: No), it is determined whether the current period is the frame SW valid period (S1503). In the process of S1503, if it is determined that the current time is not the frame SW validity period (S1503: No), a jackpot operation process, which is an operation process in a case where the jackpot effect is being executed, is performed (S1504), and the process ends. .

  Here, the jackpot operation process (S1504) will be described with reference to FIG. FIG. 108 is a flowchart showing the jackpot operation process (S1504). This jackpot operation process (S1504) is executed in the SW input monitoring and effect process (see FIG. 106) executed by the MPU 221 in the audio lamp control device 113, and the switch operation of the selection switch 270 and the like during the jackpot effect This is a process for generating and setting a display command based on an operated switch in order to execute an effect based on the switch.

  In the big hit operation process (S1504), first, it is determined whether or not the enter switch 270e is pressed (S1701). If it is determined in the processing of S1701 that the determination switch 270e has been pressed (S1701: Yes), a display determination SW pressing command is set (S1704), and this processing ends. When the display control device 114 receives this display determination SW pressing command at the time of selecting an event cell in the jackpot effect, the event cell is determined, and an effect corresponding to the cell is executed.

  On the other hand, if it is determined in the processing of S1701 that the determination switch 270e has not been pressed (S1701: No), it is determined whether any of the selection switches 270a to 270d has been pressed (S1703). If it is determined in the processing of S1703 that any of the selection switches 270a to 270d has been pressed (S1703: Yes), a display selection SW pressing command is set based on the pressed selection switch (270a to 270d). (S1704), this process ends. The display control device 114 receives the display selection SW command at the time of selecting the event mass in the big hit effect, and changes the selected event mass based on the operated selection switch.

  Returning to FIG. 106, the description will be continued. If it is determined in the process of S1503 that the current time is the frame SW valid period (S1503: Yes), the value of the frame SW valid period 223f is subtracted by 1 (S1505), and it is determined whether or not the super reach A is changing. (S1506). If it is determined in step S1506 that the super reach A is changing (S1506: Yes), it is determined whether the frame button 22 has been pressed (S1507).

  If it is determined in step S1507 that the frame button 22 has been pressed (S1508), a display valid pressing command is set (S1508), and the process ends. On the other hand, if it is determined in step S1507 that the frame button 22 has not been pressed (S1507: No), the process of step S1508 is skipped, and the process ends. When the display control device 114 receives the display effective press command set in the processing of S1508, the stop display (for example, FIG. 70 (b), FIG. 71 (a)) is performed in the effect of Super Reach A. .

  On the other hand, if it is determined in step S1506 that it is not Super Reach A (S1506: No), it is determined whether it is Super Reach B (S1509). If it is determined in step S1509 that the current mode is not Super Reach B (S1509: No), there is no process based on the switch operation, and thus the process ends.

  If it is determined in step S1509 that the game is Super Reach B (S1509: Yes), a super reach B operation process for executing a process based on a switch operation during the production of Super Reach B is executed ( S1510), this process ends.

  Here, the super reach B operation process (S1510) will be described with reference to FIG. FIG. 109 is a flowchart showing the super reach B operation process (S1510). The super reach B operation process (S1510) is executed in the SW input monitoring and effect process (see FIG. 106) executed by the MPU 221 in the audio lamp control device 113, and the operation of the frame button 22 in the super reach B This is a process of generating and setting a display command in order to execute an effect (for example, FIG. 77 (b)) based on.

  In the super reach B operation process (S1510), first, it is determined whether or not the frame SW valid period is greater than 0 (S1801). In the process of S1801, if it is determined that the frame SW valid period is greater than 0 (S1801: Yes), the process proceeds to S1803. On the other hand, if it is determined in the processing of S1801 that the frame SW validity period is not greater than 0 (that is, it is 0) (S1801: No), it is the timing to end the production of the super reach B, so the replacement is performed. The flag is turned off (S1802), and the process proceeds to S1803.

  In the processing of S1803 executed after the processing of S1801 or S1802, it is determined whether or not the frame button 22 has been pressed (S1803). In the processing of S1803, if it is determined that the frame button 22 has not been pressed (S1803: No), this processing ends.

  On the other hand, if it is determined in the processing of S1803 that the frame button 22 has been pressed (S1803: Yes), the value of the effect counter 223i is obtained (S1804), and the data of the winning information storage area 223a is obtained (S1805). The process moves to S1806.

  In the processing of S1806, it is determined whether or not the changing winning information is a big hit (S1806). In the processing of S1806, when it is determined that the winning information in the change is a big hit (S1806: Yes), then, it is determined whether or not the value of the effect counter 223i acquired in the processing of S1804 is 0 to 100. (S1807).

  In the process of S1807, when it is determined that the value of the effect counter 223i is 0 to 100, it is determined whether or not the remaining number of effective presses is 1 and the period is not the stop enabled period (S1808). In the process of S1808, if it is determined that the remaining number of effective presses is 1 and the period is not the stoppable period (S1808: Yes), a display valid press command is set (S1809), and the process proceeds to S1811. . On the other hand, when it is determined that the value of the effect counter 223i is not 0 to 100 (that is, 101 to 198) in the process of S1807, the remaining valid number of times is not 1 in the process of S1808, or the stoppage is possible. If it is determined (S1808: No), a fake display command for display is set (S1809), and the process moves to S1811.

  In the process of S1811 executed after the process of S1809 or S1810, the replacement timing is updated based on the number of remaining valid presses and the remaining frame SW valid period. Specifically, the super reach B is provided with a replacement timing. After the replacement timing, it is assumed that the number of remaining effective presses is large (that is, the number of presses of the frame button 22 is insufficient during the remaining frame SW valid period) despite the short remaining frame SW valid period. It is determined, and the effect indicating the jackpot is replaced in advance. As described above, by setting the replacement timing based on the remaining frame SW valid period and the number of remaining valid presses, it is possible to set an effect indicating a jackpot in advance, and to perform processing when the remaining frame SW valid period has elapsed. The load can be reduced.

  When the processing in S1811 is completed, it is determined whether or not the replacement flag 223h is off (S1812). In the process of S1812, when it is determined that the replacement flag 223h is not off (S1812: No), the display replacement command for replacing the effect indicating the jackpot has already been set, and thus the present process is performed as it is. To end.

  On the other hand, in the process of S1812, when it is determined that the replacement flag 223h is off (S1812: Yes), it is determined whether the replacement timing has elapsed (S1813). In the process of S1813, when it is determined that the replacement timing has not passed (S1813: No), the process is terminated because there is no need to perform replacement yet. In the process of S1813, if it is determined that the replacement timing has elapsed (S1813: Yes), a display replacement command for replacing an effect indicating a jackpot is set (S1814), and the replacement flag 223h is set. It is set to ON (S1815), and this processing ends.

  On the other hand, in the processing of S1806, when it is determined that the winning information that is changing is not a big hit (S1806: No), it is then determined whether or not the effect counter 223i is 0 to 50 (S1816). In the processing of S1816, when it is determined that the effect counter 223i is 0 to 50 (S1816: Yes), a display effective pressing command is set (S1817), and this processing ends. In the processing of S1816, when it is determined that the effect counter 223i is not 0 to 50 (that is, 51 to 198) (S1816: No), a false display press command for display is set (S1818), and this processing ends. I do.

<Control processing of display control device in first control example>
Next, each control executed by the MPU 231 of the display control device 114 will be described with reference to FIGS. The processing of the MPU 231 is roughly classified into a main processing that is repeatedly executed after the power is turned on, a command interruption processing that is executed when a command is received from the sound lamp control device 113, and a one-frame processing performed by the image controller 237. There is a V interrupt process that is executed when the MPU 231 detects a V interrupt signal transmitted every 20 milliseconds when the image rendering process is completed. The MPU 231 normally executes a main process, and executes a command interrupt process or a V interrupt process in accordance with reception of a command or detection of a V interrupt signal. If the command reception and the V interrupt signal detection are performed simultaneously, the command reception processing is executed with priority. As a result, it is possible to quickly reflect the content of the command received from the audio lamp control device 113 and execute the V interrupt processing.

  First, the main processing executed by the MPU 231 in the display control device 114 will be described with reference to FIG. FIG. 110 is a flowchart showing this main processing. The main process executes an initialization process when the power is turned on.

  The activation of the main processing is specifically performed according to the following flow. When the power is supplied to the display control device 114 from the power supply circuit 115 and the system reset is released, the MPU 231 sets the instruction pointer 231a provided in the MPU 231 to “0000H” by the hardware configuration, and , An address “0000H” indicated by the instruction pointer 231a is specified for the bus line 240. When the ROM controller 234b of the character ROM 234 detects that the address designated to the bus line 240 is “0000H”, the ROM controller 234b sets the boot program stored in the first program storage area 234d1 of the NOR ROM 234d in the buffer RAM 234c. And outputs the corresponding data (instruction code) to the MPU 231. Then, the MPU 231 starts the main processing by fetching the instruction code received from the character ROM 234 and starting execution of processing corresponding to the fetched instruction.

  Here, if all boot programs to be processed first by the MPU 231 after the system reset is released are stored in the NAND flash memory 234a, the character ROM 234 indicates that the address specified for the bus line 240 is "0000H". Upon detection, one page of data including data (instruction code) corresponding to the address "0000H" must be read from the NAND flash memory 234a and set in the buffer RAM 234c. Because of the nature of the NAND flash memory 234a, a great deal of time is required from the reading to the setting in the buffer RAM 234c. Therefore, the MPU 231 specifies the address “0000H” and then receives the instruction code corresponding to the address “0000H” Will consume a lot of waiting time. Therefore, since the time required to start the MPU 231 becomes longer, there is a problem that the control of the third symbol display device 81 in the display control device 114 may not be started immediately.

  On the other hand, as in the present control example, a predetermined number of instructions from the first to be processed by the MPU 231 after the system reset is released from the boot program are stored in the NOR ROM 234d, so that the NOR ROM can operate at high speed. Since the memory is a memory from which data can be read, when the address “0000H” is designated from the MPU 231 via the bus line 240 after the system reset is released, the character ROM 234 is immediately stored in the first program storage area 234d1 of the NOR type ROM 234d. The stored boot program can be set in the buffer RAM 234c, and the corresponding data (instruction code) can be output to the MPU 231. Therefore, since the MPU 231 can receive the instruction code corresponding to the address “0000H” in a short time after specifying the address “0000H”, the MPU 231 can start the main processing in a short time. Therefore, even if the control program is stored in the character ROM 234 composed of the NAND flash memory 234a having a low reading speed, the control of the third symbol display device 81 in the display control device 114 can be started immediately.

  When the main process is executed as described above, first, a boot process executed by a boot program is executed (S1901), and the display control device 114 is set to execute various controls on the third symbol display device 81. Start

  Here, the boot process (S1901) will be described with reference to FIG. FIG. 111 is a flowchart illustrating the boot process (S1901) executed in the main process in the MPU 231 of the display control device 114.

  As described above, in the present control example, the control program and the fixed value data executed by the MPU 231 are not stored in a dedicated program ROM provided in the conventional game machine but stored in the third symbol display device 81. The image data to be displayed is stored in a character ROM 234 provided for storing the data. Since the character ROM 234 is constituted by the NAND flash memory 234a having a small area and a large capacity, not only image data but also a control program and the like can be sufficiently stored. There is no need to provide a dedicated program ROM for storing programs and the like. Therefore, the number of components in the display control device 114 can be reduced, the manufacturing cost can be reduced, and an increase in the failure rate due to an increase in the number of components can be suppressed.

  On the other hand, since the reading speed of the NAND flash memory is particularly low when performing random access, the MPU 231 directly reads and processes the control program and fixed value data stored in the NAND flash memory 234a. Even if a high-performance processor is used, the processing performance of the display control device 114 may be degraded. Therefore, in this boot processing, the control program and the fixed value data stored in the second program storage area 234a1 of the NAND flash memory 234a are stored in the program storage area 233a and the data table provided in the work RAM 233 constituted by the DRAM. The process of transferring and storing the data to the storage area 233b is executed.

  Specifically, first, based on the hardware operation of the MPU 231 and the character ROM 234 described above, after the system reset is released, the second program is read out from the first program storage area 234d1 of the NOR ROM 234d and set in the buffer RAM 234c according to the boot program. Of the control programs stored in the two program storage area 234a1, a predetermined amount is transferred to the program storage area 233a (S2001). The predetermined amount of control program transferred here includes the remaining boot programs not stored in the first program storage area 234d1.

  Then, the instruction pointer 231a is set to the first predetermined address of the program storage area 233a, that is, the start address of the remaining boot program stored in the program storage area 233a (S2002). As a result, the MPU 231 starts executing the remaining boot program included in the control program transferred and stored in the program storage area 233a by the process of S2001.

  Also, by setting the instruction pointer 231a to a predetermined address of the program storage area 233a by the processing of S2002, the MPU 231 executes various processing while reading out the control program stored in the program storage area 233a of the work RAM 233. become. That is, the MPU 231 does not read out the control program from the NAND flash memory 234a having the second program storage area 234a1 and fetch the instruction, but reads out the control program transferred to the work RAM 233 having the program storage area 233a and fetches the instruction. Then, various processes are executed. As described above, since the work RAM 233 is configured by a DRAM, a high-speed read operation is performed. Therefore, even when the control program is stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, the MPU 231 can fetch an instruction at high speed and execute a process for the instruction.

  When the instruction pointer 231a is set by the processing of S2002, the instruction pointer 231a is subsequently stored in the second program storage area 234a1 of the NAND flash memory 234a according to the remaining boot program started to be executed by the set instruction pointer 231a. The remaining control programs and fixed value data of the control programs which have not been transferred to the program storage area 233a are transferred to the program storage area 233a or the data table storage area 233b by a predetermined amount (S2003). Specifically, the control program and some fixed data are stored in the program storage area 233a of the work RAM 233, and the various data tables (display data table, transfer data table) among the fixed value data are stored in the data table. The data is transferred to the storage area 233b.

  Then, after executing other processes necessary for the boot process (S2004), the instruction pointer 231a is executed at the second predetermined address of the program storage area 233a, that is, after the end of the boot process (see S1901 in FIG. 110). By setting the start address of the program corresponding to the power-up initialization process (see S1902 in FIG. 110) (S1905), the execution of the boot program is completed, and the boot process is completed.

  By executing the boot process (see S1901 in FIG. 110) in this manner, the control program and fixed value data stored in the second program storage area 234a1 of the NAND flash memory 234a are all configured by the DRAM. The data is transferred to and stored in the program storage area 233a and the data table storage area 233b of the work RAM 233. Then, at the end of the boot process, the instruction pointer 231a is set to the above-mentioned second predetermined address, and thereafter, the MPU 231 reads the control program transferred to the program storage area 233a without referring to the NAND flash memory 234a. And execute various processes.

  Therefore, even when the control program is stored in the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed, the control program and the fixed value data are stored in the program storage area 233a of the work RAM 233 after the system reset is released. By transferring the data to the data table storage area 233b, the MPU 231 can read out a control program and fixed value data from a work RAM constituted by a DRAM having a high readout speed and perform various controls. High processing performance can be maintained, and diversified and complicated effects can be easily executed using the auxiliary effect unit.

  On the other hand, the entire boot program is not stored in the NOR ROM 234d, but a predetermined number of instructions from the first to be processed by the MPU 231 after the system reset is released are stored. The remaining boot programs are stored in the NAND flash memory 234a. Even if the control program is stored in the second program storage area 234a1, the control program stored in the second program storage area 234a1 can be reliably transferred to the program storage area 233a. Therefore, the character ROM 234 can start the MPU 231 in a short time only by adding the NOR-type ROM 234d having a very small capacity. Can be.

  In the boot process shown in FIG. 111, the predetermined amount of control program transferred to the program storage area 233a by the process of S2001 includes all the remaining boot programs not stored in the first program storage area 234d1. Although not limited to this, the predetermined amount of control program transferred to the program storage area 233a by the process of S2001 is a boot program that executes a boot process to be processed following the process of S2002. May be part of The boot program transferred here transfers the control program including all the remaining boot programs by a predetermined amount to the program storage area 233a, and furthermore, the start address of the boot program stored in the program storage area 233a is designated by the instruction pointer. 231a may be executed. Then, the processes of S2003 to S2005 may be executed by all remaining boot programs stored in the program storage area 233a.

  The boot program transferred by the process of S2001 transfers a part of the remaining boot program to the program storage area 233a by a predetermined amount, and subsequently, the start of the boot program stored in the program storage area 233a. Processing for setting an address in the instruction pointer 231a may be executed. The part of the boot program stored in the program storage area 233a by this process further transfers a part of the remaining boot program to the program storage area 233a by a predetermined amount. The processing for setting the start address of the stored boot program in the instruction pointer 231a may be executed. Then, a part of the remaining boot program is transferred to the program storage area 233a by a predetermined amount, and subsequently, the process of setting the start address of the boot program stored in the program storage area 233a in the instruction pointer 231a is performed in S1901. After repeating the processing a plurality of times including the processing of S1902, the processing of S2003 to S2005 may be executed.

  Accordingly, even if the program size of the boot program is large and the remaining boot programs not stored in the first program storage area 234d1 cannot be transferred to the program storage area 233a at one time, the MPU 231 is already stored in the program storage area 233a. By using the boot program, the data can be transferred to the program storage area 233a by a predetermined amount.

  Further, in the present control example, a case has been described in which a part of the boot program executed by the MPU 231 at the time of system reset release is first stored in the first program storage area 234d1, but all the boot programs are stored in the first program storage area 234d1. It may be stored in one program storage area 234d1. In this case, when starting the boot process, the MPU 231 may execute the processes of S2003 to S2005 without performing the processes of S2001 and S2002. As a result, the process of transferring the boot program to the program storage area 233a becomes unnecessary, and the number of times of transferring the program to the character ROM 234 or the program storage area 233a is reduced, so that the processing time of the boot process can be reduced. Therefore, the control of the auxiliary effect section in the MPU 231 which can be performed after the boot process can be started more quickly.

  Here, the description returns to FIG. When the boot process is completed, an initialization process is executed in accordance with the control program transferred to and stored in the program storage area 233a of the work RAM 233 (S1902). Specifically, the value of the stack pointer is set in the MPU 231, and various settings for the register group in the MPU 231 and the I / O device are performed. Further, processing for clearing the storage of the work RAM 233, the resident video RAM 235, and the normal video RAM 236 is performed. Further, various flags are provided in the work RAM 233, and an initial value is set for each flag. Note that “off” or “0” is set as an initial value of each flag, unless otherwise specified.

  Further, in the initial setting process, after performing the initial setting of the image controller 237, the image controller 237 draws an image so that an image of a specific color is displayed on the entire screen on the third symbol display device 81. And execution of display processing. Thus, immediately after the power is turned on, first, an image of a specific color is displayed on the entire screen of the third symbol display device 81. Here, the color of the image displayed on the entire screen of the third symbol display device 81 immediately after the power is turned on is set to be different depending on the model of the pachinko machine. Thus, in an operation check at a factory or the like at the time of manufacturing, the pachinko machine 10 can check whether or not an image of a color corresponding to the model is displayed on the third symbol display device 81 immediately after the power is turned on. It is possible to easily and immediately determine whether or not the activation can be started normally.

  Next, a transfer instruction is transmitted to the image controller 237 to transfer the image data corresponding to the power-on main image to the power-on main image area 235a of the resident video RAM 235 (S1903). The transfer instruction includes the start address and the end address of the character ROM 234 storing the image data corresponding to the main image at power-on, the information of the transfer destination (here, the resident video RAM 235), and the transfer destination. The image data corresponding to the power-on main image is transferred from the character ROM 234 to the resident video RAM 235 by the image controller 237 in accordance with the transfer instruction. The image is transferred to the image area 235a.

  Then, when all the transfer of the image data indicated by the transfer instruction is completed, the image controller 237 transmits a transfer end signal indicating the transfer end to the MPU 231. By receiving this transfer end signal, the MPU 231 can grasp that the transfer of the image data specified by the transfer instruction has been completed. When the image controller 237 completes the transfer of the image data indicated by the transfer instruction, the image controller 237 stores the transfer end information indicating the transfer end in a register provided inside the image controller 237 or a partial area of the built-in memory. You may write it. Then, the MPU 231 reads out the information of the register or a partial area of the built-in memory at any time, detects the writing of the transfer end information by the image controller 237, and thereby grasps that the transfer of the image data specified by the transfer instruction has been completed. You may do so.

  The image data transferred to the main image area 235a when the power is turned on is held so as not to be overwritten until the power is turned off. When the transfer of the image data corresponding to the power-on main image to the power-on main image area 235a is completed based on the transfer instruction transmitted to the image controller 237 in the processing of S1903, the power-on fluctuation image Is transmitted to the image controller so that the image data corresponding to the image data is transferred to the power-on fluctuation image area 235b of the resident video RAM 235 (S1904). The transfer instruction includes the start address of the character ROM 234 storing the image data corresponding to the power-on fluctuation image, the data size of the image data, the transfer destination information (here, the resident video RAM 235). And the start address of the power-on fluctuation image area 235b, which is the transfer destination. The image controller responds to the transfer instruction and transfers the image data corresponding to the power-on fluctuation image from the character ROM 234 to the resident video RAM 235. The data is transferred to the power-on fluctuation image area 235b. The image data transferred to the power-on fluctuation image area 235b is held so as not to be overwritten until the power is turned off.

  When the transfer of the image data corresponding to the power-on fluctuation image to the power-on fluctuation image area 235b is completed based on the transmission instruction transmitted to the image controller 237 in the processing of S1904, the simple image display flag 233c Is turned on (SS1905). As a result, while the simple image display flag 233c is on, all image data to be resident in the resident video RAM 235 is transferred from the character ROM 234 to the resident video RAM 235 in a transfer setting process (see FIG. 130A) described later. A resident image transfer setting process for instructing the image controller 237 to perform the transfer is executed (see S4302 in FIG. 130A).

  Also, the simple image display flag 233c indicates that all image data to be resident in the resident video RAM 235 is transferred from the character ROM 234 to the resident video RAM 235 based on the transfer instruction to the image controller 237 by this resident image transfer setting process. It is kept on until it ends. Thereby, in the meantime, in the V interrupt processing (see FIG. 112B), the simple command determination processing (FIG. 112B) is performed so that the power-on image (power-on main image or power-on fluctuation image) is drawn. 112 (b) of S2208) and simple display setting processing (see S2209 of FIG. 112 (b)).

  As described above, since the pachinko machine 10 uses the NAND flash memory 234a as the character ROM 234, all the image data to be stored in the resident video RAM 235 is It takes a lot of time to transfer from the character ROM 234 to the resident video RAM 235. Therefore, as in the main process, after the power is turned on, first, the power-on main image and the power-on fluctuation image are transferred from the character ROM 234 to the resident video RAM 235, and the power-on main image is stored in the third video. By displaying on the symbol display device 81, while the remaining image data to be resident is transferred to the resident video RAM 235, the player or the person in charge of the hall operates at the time of turning on the power displayed on the third symbol display device 81. You can check the main image. Therefore, the display control device 114 transfers the remaining image data to be resident from the character ROM 234 to the resident video RAM 235 over time while displaying the main image at power-on on the third symbol display device 114. be able to. On the other hand, since the player or the like can recognize that some initialization processing is being performed while the main image is displayed on the third symbol display device 81 at the time of power-on, the player is resident in the remaining resident video RAM 235. Until the image data to be transferred from the character ROM 234 to the resident video RAM 235, it is possible to wait until the initialization is completed without worrying that the operation has not stopped.

  Also, in an operation check at a factory or the like at the time of manufacturing, the main image at power-on is immediately displayed on the third symbol display device 81, so that the operation of the third symbol display device 81 is started without any problem by turning on the power. Can be immediately confirmed, and the use of the NAND flash memory 234a having a low reading speed as the character ROM 234 can prevent the efficiency of the operation check from deteriorating.

  In the display control device 114 of the pachinko machine 10, since the power-on fluctuation image is transferred from the character ROM 234 to the resident video RAM 235 together with the power-on main image after the power is turned on, the power-on main image is displayed in the third symbol. When the player starts the game while being displayed on the display device 81, there is a ball (start winning) in the first winning opening 64 or the second winning opening 640, and the start instruction of the variable effect is issued by the main control device. In the case where the command is received from the voice lamp controller 113 via the sound lamp control device 113, that is, when the display variation pattern command is received, the power-on variation image is immediately displayed during the variation effect period, and a simple variation effect is performed. be able to. Therefore, even when the main image is displayed on the third symbol display device 81 when the power is turned on, the player can surely confirm that the lottery has been performed by the simple variable effect.

  As described above, while the remaining image data to be resident is being transferred from the character ROM 234 to the resident video RAM 235, the main image is displayed on the third symbol display device 81 when the power is turned on. Is constituted by the NAND flash memory 234a having a low readout speed, so that it takes time to transfer the data, so that after power-on, the time during which the main image is displayed at power-on also becomes longer. However, in the pachinko machine 10, a simple fluctuation effect can be performed using the power-on fluctuation image transferred to the resident video RAM 235 after the power is turned on. Immediately after, for example, while the main image is being displayed at the time of power-on, the player can play the game with peace of mind.

  After the processing of S1905, interruption permission is set (S1906), and thereafter, the main processing executes an infinite loop processing until the power is turned off. Thus, after the interruption permission is set by the processing of S1906, the command interruption processing and the V interruption processing are executed in accordance with the reception of the command and the detection of the V interruption signal.

  Next, a command interruption process executed by the MPU 231 of the display control device 114 will be described with reference to FIG. FIG. 112A is a flowchart showing the command interruption processing. As described above, when a command is received from the audio lamp control device 113, the MPU 231 executes a command interruption process.

  In this command interruption processing, the received command data is extracted, the extracted command data is sequentially stored in a command buffer area provided in the work RAM 233 (S2101), and the process is terminated. Various commands stored in the command buffer area by the command interrupt processing are read out by a command determination processing or a simple command determination processing of a V interrupt processing described later, and processing according to the command is performed.

  Next, with reference to FIG. 112 (b), the V interrupt processing executed by the MPU 231 of the display control device 114 will be described. FIG. 112B is a flowchart showing the V interrupt processing. In this V interrupt processing, various processing corresponding to the command stored in the command buffer area by the command interrupt processing is executed, and an image to be displayed on the third symbol display device 81 is specified, and then the drawing of the image is performed. By creating a list (see FIG. 91) and transmitting the drawing list to the image controller 237, the image controller 237 is instructed to execute drawing processing and display processing of the image.

  As described above, the execution of the V interrupt processing is started when a V interrupt signal from the image controller 237 is detected. This V interrupt signal is a signal that is generated every 20 milliseconds in the image controller 237 when the drawing processing of the image for one frame is completed, and is transmitted to the MPU 231. Therefore, by executing the V interrupt processing in synchronization with the V interrupt signal, a drawing instruction is issued to the image controller 237 every 20 milliseconds when the drawing processing of the image for one frame is completed. become. Therefore, the image controller 237 does not receive a drawing instruction of the next image at a stage where the image drawing processing or the display processing is not completed, so that the image controller 237 starts drawing a new image during drawing of the image, It is possible to prevent an image from being developed in a frame buffer in which image information being displayed is stored in accordance with a new drawing instruction.

  Here, first, an outline of the flow of the V interrupt processing will be described, and then details of each processing will be described with reference to other drawings. In this V interrupt processing, as shown in FIG. 112 (b), first, it is determined whether or not the simple image display flag 233c is on (S2201), and the simple image display flag 233c is not on, that is, If it is off (S2201: No), it means that the transfer of all image data to be resident in the resident video RAM 235 has been completed. A command determination process (S2202) is performed to cause the display device 81 to display, and then a display setting process (S2203) is performed.

  In the command determination process (S2202), the contents of the command from the audio ramp control device 113 stored in the command buffer area by the command interruption process are analyzed, and the process corresponding to the command is executed. When the display variation pattern command is stored, the demo display data table or the variation display data table corresponding to the variation pattern type is set in the display data table buffer 233d, and the transfer data corresponding to the set display data table is set. The table is set in the transfer data table buffer 233e.

  In this command determination processing, all commands stored in the command buffer area at that time are analyzed and the processing is executed. This is because the command determination processing is performed at intervals of 20 milliseconds during which the V interrupt processing is executed, and thus there is a high possibility that a plurality of commands are stored in the command buffer area during the 20 milliseconds. is there. In particular, when the start of the fluctuation effect is determined in the main control device 110, there is a high possibility that the display fluctuation pattern command, the display stop type command, and the like are simultaneously stored in the command buffer area. Therefore, by analyzing and executing these commands at once, the mode of the variable effect and the type of stop selected by the main control device 110 and the sound lamp control device 113 are quickly grasped, and the effect image according to the mode is obtained. The drawing of the image can be controlled so as to be displayed on the third symbol display device 81. The details of the command determination processing will be described later with reference to FIGS.

  In the display setting process (S2203), an image for one frame to be displayed next in the third symbol display device 81 based on the contents of the display data table set in the display data table buffer 233d by the command determination process (S2202) and the like. Specify the contents of In addition, an effect mode to be displayed on the third symbol display device 81 is determined in accordance with a processing situation or the like, and a display data table corresponding to the determined effect mode is set in the display data table buffer 233d. The details of the display setting process will be described later with reference to FIGS. 127 to 129.

  After the display setting process is executed, a task process is executed (S2204). In this task process, the image is formed based on the contents of the image for the next one frame to be displayed on the third symbol display device 81 specified by the display setting process (S2203) or the simple display setting process (S2209). The type of sprite (display object) to be specified is specified, and various parameters required for drawing, such as a display coordinate position, an enlargement ratio, and a rotation angle, are determined for each sprite.

  Next, a transfer setting process is executed (S2205). In this transfer setting process, while the simple image display flag 233c is ON, the image controller 237 transfers the image data to be resident in the resident video RAM 235 from the character ROM 234 to a predetermined area of the resident video RAM 235. Set instructions. While the simple image display flag 233c is off, predetermined image data is sent from the character ROM 234 to the image controller 237 based on the transfer data information of the transfer data table set in the transfer data table buffer 233e. In addition to setting a transfer instruction to transfer to a predetermined sub area of the image storage area 236 a of the video RAM 236, the image controller 237 also receives a continuous notice command or a rear image change command from the sound lamp control device 113. A transfer instruction is set to transfer the image data of the continuous preview image used in the preview effect and the image data of the rear image after the change from the character ROM 234 to a predetermined sub area of the image storage area 236a of the normal video RAM 236. The details of the transfer setting process will be described later with reference to FIGS. 130 and 131.

  Next, a drawing process is executed (S2206). In this drawing processing, the type of various sprites constituting one frame determined in the task processing (S2204), the parameters necessary for drawing each sprite, and the transfer instruction set in the transfer setting processing (S2205) are used. The drawing list shown in FIG. 91 is generated, and the drawing list is transmitted to the image controller 237 together with the drawing target buffer information. Thus, the image controller 237 executes the image drawing processing according to the drawing list. The details of the drawing process will be described later with reference to FIG.

  Next, a counter update process (S2207) is executed. The details of the counter updating process will be described later with reference to FIG. Then, the V interrupt processing ends. As a counter updated by the process of S2207, for example, there is a stop symbol counter (not shown) for determining a stop symbol. The value of the stopped symbol counter is stored in the work RAM 233, and is updated each time the V interrupt processing is executed. Then, in the command determination processing, when the reception of the display stop type command is detected, the stop type indicated by the display stop type command (big hit A, big hit B, reach out of front / rear, reach other than front / back out, reach out) is displayed. The corresponding stop type table and the stop type counter are compared, and the stop symbol after the variable effect displayed on the third symbol display device 81 is finally set.

  On the other hand, if it is determined in the process of S2201 that the simple image display flag 233c is ON (S2201: Yes), it means that transfer of all image data to be resident in the resident video RAM 235 has not been completed. Therefore, in order to display the power-on image on the third symbol display device 81, the simple command determination process (S2208) is executed, then the simple display setting process (S2209) is executed, and the process proceeds to S2204.

  Next, details of the above-described command determination processing (S2202), which is one processing of the V interrupt processing executed by the MPU 231 of the display control device 114, will be described with reference to FIGS. First, FIG. 113 is a flowchart showing this command determination processing.

  In this command determination process, as shown in FIG. 113, first, it is determined whether there is an unprocessed new command in the command buffer area (S2301). If there is no unprocessed new command (S2301: No), The command determination process ends, and the process returns to the V interrupt process. On the other hand, if there is an unprocessed new command (S2301: Yes), a new command flag for notifying the display setting process (S2203) that the new command has been processed in the ON state is set to ON (S2302). For all unprocessed commands stored in the buffer area, the types of the commands are analyzed (S2303).

  First, it is determined whether or not there is a display variation pattern command among the unprocessed commands (S2304). If there is a display variation pattern command (S2304: Yes), the variation pattern command processing is executed. (S2305), and returns to the process of S2301.

  Here, the details of the variation pattern command processing (S2305) will be described with reference to FIG. FIG. 114A is a flowchart showing the variation pattern command processing. This variation pattern command processing executes processing corresponding to the display variation pattern command received from the audio lamp control device 114.

  In the variation pattern command processing, first, the data in the game state storage area is updated based on the received command (S2401). Next, the received variation pattern is stored in the variation history storage area (S2402), a variation display data table corresponding to the variation effect pattern indicated by the display variation pattern command is determined, and the determined variation display data table is stored in the data. The data is read from the fluctuating effect table storage area of the table storage area 233b (see FIG. 17) and set in the display data table buffer 233d (S2403).

  Here, since the determination of the start of the fluctuation in the main controller 110 is always made at least several seconds apart, no more than two display fluctuation pattern commands are received within 20 milliseconds. When executing, it is impossible that two or more display variation pattern commands are stored in the command buffer area. However, part of the command changes due to the influence of noise or the like, and another command is incorrectly displayed. It may be interpreted as a fluctuation pattern command. In the process of S2403, when it is determined that two or more display variation pattern commands are stored in the command buffer area in preparation for such a case, the variation display data table corresponding to the variation pattern with the shortest variation time. Is set in the display data table buffer 233d.

  If a fluctuation display data table corresponding to a fluctuation pattern having a long fluctuation time is set in the display data table buffer 233d, a fluctuation effect having a fluctuation time shorter than the set display data table actually occurs in the main control device. When instructed by 110, the next display variation pattern command is received from main controller 110 while the variation effect according to the set variation display data table is being displayed on third symbol display device 81. As a result, another variable display is suddenly started, and there is a possibility that the player may feel uncomfortable.

  On the other hand, by setting the fluctuation display data table corresponding to the fluctuation pattern with the shortest fluctuation time in the display data table buffer 233d as in the present control example, the fluctuation data longer than the set display data table is actually set. Even when the fluctuation effect having a time is instructed by the main controller 110, as described later, after the fluctuation effect according to the display data table buffer 233d is completed, the main controller 110 returns to the next display. Until the pattern command is received, the display of the third symbol display device 81 is controlled by the display setting process so that the demonstration effect is displayed. You can keep watching the fluctuations of the three symbols.

  Next, a transfer data table corresponding to the display data table set in S2403 is determined, read from the data table storage area 233b, and set in the transfer data table buffer 233e (S2404). Then, among the data table determination flags provided for each variation display data table corresponding to each variation pattern, the data table determination flag corresponding to the variation display data table set in the process of S2403 is turned on, and other variation table data is set. The data table determination flag corresponding to the display data table is set to off (S2405). In the display setting process, by referring to the data table determination flag set in the process of S2405, it is easy to determine which variation pattern the variation display data table set in the display data table buffer 233d corresponds to. You can judge.

  Next, based on the fluctuation time of the fluctuation pattern corresponding to the fluctuation display data table set in the display data table buffer 233d by the processing of S2403, time data representing the fluctuation time is set in the time counter 233h (S2406), and the pointer is set. 233f is initialized to 0 (S2407). Then, both the demonstration display flag and the confirmed display flag are set to OFF (S2408), the super background effect processing is executed (S2409), and the process returns to the command determination processing.

  By executing the variation pattern command processing, in the display setting processing, while updating the pointer 233f initialized by the processing of S2407, the display data table buffer 233d set in the display data table buffer 233d by the processing of S2403 is updated. , Extract the drawing content specified at the address indicated by the pointer 233f, specify the content of the image for one frame to be displayed next in the third symbol display device 81, and at the same time, execute the transfer data table buffer 233e by the process of S2404. The transfer data information specified at the address indicated by the pointer 233f is extracted from the transfer data table set in the variable ROM display data table, and the sprite image data required in the set variable display data table is previously stored in the character ROM 234 from the normal video R. To be transferred to the image storage area 236a of M236, to control the image controller 237.

  In the display setting process, the time of the variation effect specified in the variation display data table is measured using the time counter 233h in which the time data is set by the process of S2406, and when the variation effect in the variation display data table ends. When it is determined, the setting of the stop display is controlled so that the stop symbol corresponding to the display stop type command from the main control device 110 is displayed on the third symbol display device 81.

  Here, the super-background effect process (S2409) will be described with reference to FIG. FIG. 115 is a flowchart showing the super background effect processing (S2409). In the super-background effect process (S2409), when the background in the door in the super-background notice is displayed, whether to end the background in the door according to the number of times of the variable display performed during the display of the background in the door. This is a process for determining whether to continue.

  In the super-background effect processing, first, it is determined whether or not the in-door variation counter 233y is greater than 0 (S2601). In the process of S2601, if it is determined that the in-door change number counter 233y is 0 (S2601: No), the process is terminated as it is because the in-door background is not being displayed.

  On the other hand, in the process of S2601, when it is determined that the in-door variation number counter 233y is greater than 0 (S2601: Yes), the in-door variation number counter 233y is decremented by 1 (S2602), and the in-door variation number counter 223y is determined. It is determined whether the value is 0 (S2603).

  In the process of S2603, if it is determined that the in-door variation number counter 223y is not 0 (S2603: No), this process ends because it is not the end timing of the in-door background. On the other hand, in the process of S2603, when it is determined that the in-door change frequency counter 223y is 0 (S2603: Yes), the data of the winning information storage area 233k is obtained (S2604), and the value of the display effect counter 233o is obtained. Then (S2605), and shifts to the processing of S2606.

  In the processing of S2606, it is determined from the data in the winning information storage area 233k acquired in the processing of S2604 whether or not there is a jackpot in the hold (S2606). If it is determined in the processing of S2606 that there is a jackpot in the hold (S2606: Yes), it is then determined whether or not the value of the display effect counter 233o obtained in the processing of S2605 is 0 to 150 ( S2607).

  In the process of S2607, when it is determined that the value of the display effect counter 233o is 0 to 150, the same rear image determination flag as the currently displayed background inside the door is set to ON (S2608), and the process proceeds to S2612. Move on to processing. On the other hand, in the process of S2607, when it is determined that the value of the display effect counter 233o is not 0 to 150 (that is, 151 to 198) (S2607: No), a door different from the currently displayed background in the door is displayed. The back image determination flag corresponding to the inner background is set to ON (S2609), and the flow shifts to the process of S2612.

  On the other hand, if it is determined in the process of S2606 that there is no big hit in the hold (S2606: No), then it is determined whether or not the display effect counter 233o is 0 to 30 (S2610). In the process of S2610, when it is determined that the display effect counter 233o is 0 to 30, the back image determination flag corresponding to the in-door background different from the currently displayed in-door background is set to ON (S2611). , To S2612. On the other hand, in the process of S2610, when it is determined that the value of the display effect counter 233o is not 0 to 30 (that is, 31 to 198) (S2611: No), the rear image corresponding to the background other than the background in the door The determination flag is set to ON (S2613), and the flow shifts to the process of S2614.

    In the process of S2612 executed after S2608, S2609 or S2611, the in-door variation counter 223y is set to 20, and the process proceeds to S2614.

  In the processing of S2614 executed after S2612 or S2613, the back image change flag 233q is set to ON (S2614), and this processing ends.

  Returning to FIG. 113, the description will be continued. In the process of S2304, if it is determined that there is no display variation pattern command (S2304: No), then it is determined whether or not there is a display stop type command among unprocessed commands (S2306). If there is a display variation type command (S2306: Yes), stop type command processing is executed (S2307), and the process returns to S2201.

  Here, the details of the stop type command processing (S2307) will be described with reference to FIG. 114 (b). FIG. 114B is a flowchart showing the stop type command processing. The stop type command process executes a process corresponding to the display variation type command received from the audio lamp control device 114.

  In the stop type command processing, first, a stop type table corresponding to the stop type information (any one of the jackpot A, the jackpot B, the front-rear reach, the reach other than the front-rear miss, and the complete miss) indicated by the display stop type command is determined. (S2501), the stop type table is compared with the value of the stop type counter updated each time the V interrupt processing (see FIG. 42 (b)) is executed, and displayed on the third symbol display device 81. The stop symbol after the variable effect is finally set (S2502).

  Then, among the stop symbol determination flags provided for each stop symbol, the stop symbol determination flag corresponding to the stop symbol set by the process of S2502 is turned on, and the stop symbol determination flag corresponding to the other stop symbols is turned off. Is set to (S2503), and this processing ends.

  Here, as described above, in the variation display data table, after a lapse of a predetermined time from the start of the variation based on the data table, as the type information for specifying the third symbol to be displayed on the third symbol display device 81. , Offset information (symbol offset information) from the stop symbol set by the processing of S2502. In the above-described task process (S2204), after a predetermined time has elapsed from the start of the fluctuation, the stop symbol set by the process of S2502 is specified from the stop symbol determination flag set in S2503, and the specified stop is specified. The third symbol to be actually displayed is specified by adding the symbol offset information acquired by the display setting process to the symbol. Then, the address at which the image data corresponding to the specified third symbol is stored is specified. The image data corresponding to the third symbol is stored in the third symbol area 235d of the resident video RAM 235 as described above.

  Note that the start of the change is always determined at least several seconds in the main control device 110, so that no more than two display stop type commands are received within 20 milliseconds. In this case, it is impossible that two or more display stop type commands are stored in the command buffer area, but some of the commands change due to the influence of noise or the like, and another command is erroneously stopped for display. It may be interpreted as a type command. In the process of S2501, if it is determined that two or more display stop type commands are stored in the command buffer area in preparation for such a case, it is assumed that the stop type is completely out of order and the stop type is determined. Determine the table. Thereby, a stop symbol corresponding to complete departure is set by the processing of S2502.

  If a stop symbol corresponding to the "special symbol jackpot" is set, the third symbol display device 81 displays the "special symbol" even if it is actually "missing the special symbol". The stop symbol corresponding to the "big hit" is displayed, and the player mistakes the pachinko machine 10 for the "special symbol big hit", which may reduce the reliability of the pachinko machine 10. On the other hand, as in the present control example, the stop symbol corresponding to the complete departure is set, and in fact, if the "special symbol jackpot" is reached, the departure stop of the complete departure is displayed on the third symbol display device 81. Even if a symbol is displayed, the pachinko machine 10 becomes a “special symbol jackpot”, and thus the player can be pleased.

  Returning to FIG. 113, the description will be continued. In the process of S2306, if it is determined that there is no stop type command for display (S2306: No), then a reach-related command process is executed among unprocessed commands (S2309), and the process returns to S2301. .

  Here, the details of the reach-related command processing (S2309) will be described with reference to FIG. FIG. 116 is a flowchart showing the reach-related command processing (S2309). The reach-related command processing (S2309) executes processing corresponding to the reach-related command received from the audio ramp control device 114.

  In the reach-related command processing (S2309), first, it is determined whether or not the changing effect is super reach A (S2701). If it is determined that the effect is super reach A (S2701: Yes), the effective press is performed. It is determined whether there is a command (S2702).

  If it is determined in step S2702 that there is a valid press command, the stop display table is set in the display data table buffer 233d (S2703), and the process ends. Here, the processing of S2703 is executed based on the pressing of the frame button 22 during the super reach A effect. By setting the stop display table in the display data table buffer 233d, a stop display (see FIG. 70 (b)) is displayed in the super-reach A effect.

  On the other hand, in the process of S2701, when it is determined that the effect during the change is not the super reach A (that is, the super reach B) (S2701: No), the display super reach B process is executed (S2704). Then, the present process ends.

  Here, the display super reach B process (S2704) will be described in detail with reference to FIG. FIG. 117 is a flowchart showing the display super reach B process (S2704). This display super reach B process (S2704) is executed in the command determination process (see FIG. 43) executed by the MPU 231 of the display control device 114, and switches such as the selection switch 270 during the super reach B effect. This is a process for performing a process based on the operation.

  In the display super reach B process, first, it is determined whether or not there is a valid press command (S2801). In the process of S2801, when it is determined that there is a valid press command (S2801: Yes), it is determined whether or not the symbol is a big hit (that is, whether or not the next valid effect will be a big hit) (S2802). .

  In the process of S2802, when it is determined that the symbol is a big hit (that is, a big hit in the next effective effect) (S2802: No), the stop display table is set in the display data table buffer 233d (S2803). This processing ends. On the other hand, in the process of S2802, when it is determined that the symbol is not a big hit (that is, no big hit in the next effective effect) (S2802: No), the throwing display table is set in the display table buffer (S2804), The process ends.

  On the other hand, in the process of S2801, if it is determined that there is no valid command (S2801: No), it is determined that there is a false press command (S2805). If it is determined in the processing of S2805 that there is a false press command (S2805: Yes), the false throw display table is set in the display data table buffer 233d, and this processing ends.

  In the process of S2805, when it is determined that there is no false press command (S2805: No), it is next determined whether or not there is a replacement command (S2807). In the process of S2807, if it is determined that there is a replacement command (S2807: Yes), the replacement table is set in the display data table buffer 233d (S2808), and this process ends.

  On the other hand, if it is determined in the processing of S2807 that there is no replacement command (S2807), there is no processing based on the switch operation during the production of Super Reach B, so this processing ends as it is.

  Returning to FIG. 113, the description will be continued. In the process of S2308, when it is determined that there is no reach-related command (S2308: No), it is determined whether there is a jackpot-related command (S2810). In the process of S2810, when it is determined that there is a jackpot-related command (S2810: Yes), the jackpot-related command process is executed (S2811), and the process returns to S2301.

  Here, the details of the jackpot-related command processing (S2811) will be described with reference to FIG. FIG. 118 is a flowchart showing the jackpot-related command processing (S2811). The jackpot-related command processing (S2811) executes processing corresponding to the display command related to the jackpot effect received from the audio lamp control device 114.

  In the jackpot-related command processing, first, it is determined whether or not there is a display opening command (S2901). If it is determined in step S2901 that there is an opening command for display, an opening command process is executed (S2902), and the flow advances to step S2903. On the other hand, when it is determined that there is no opening command for display, the process of S2902 is skipped, and the process proceeds to S2903.

  Here, the opening command processing (S2902) will be described in detail with reference to FIG. FIG. 118A is a flowchart showing the opening command processing. The opening command process executes a process corresponding to the display opening command received from the audio lamp control device 114.

  In the opening command process, first, a map setting process for setting a map to be displayed in the big hit effect is executed (S3001). Details of the map setting process (S3001) will be described later with reference to FIG. When the processing of S3001 is completed, the opening display data table is read from the opening effect table storage area (see FIG. 17) of the data table storage area 233b, and is set in the display data table buffer 233d (S3002). Next, a transfer data table corresponding to the display data table set in the processing of S3002 is determined, read from the data table storage area 233b, and set in the transfer data table buffer 233e (S3003).

  Then, based on the opening display data table set in the display data table buffer 233d by the processing of S3002, time data representing the effect time is set in the time counter 233h (S3004), and the pointer 233f is initialized to 0 (S3004). S3005). Then, both the demonstration display flag and the confirmed display flag are set to OFF (S3006), the opening command processing is completed, and the processing returns to the command determination processing.

  By executing this opening command processing, in the display setting processing, while updating the pointer 233f initialized by the processing of S3005, the display data table set in the display data table buffer 233d by the processing of S3002 is updated. The drawing contents specified at the address indicated by the pointer 233f are extracted, and the contents of the image for one frame to be displayed next in the third symbol display device 81 are specified. The transfer data information specified at the address indicated by the pointer 233f is extracted from the set transfer data table, and the sprite image data required in the set opening display data table is stored in advance in the character ROM 234. As will be transferred to the image storage area 236a of the normal video RAM 236, and controls the image controller 237.

  When the opening command processing is executed, the opening transfer data table is set in the transfer data table buffer 233e. As a result, while the opening effect is being performed on the third symbol display device 81, image data necessary for the round effect and the ending effect can be transferred from the character ROM 234 to the normal video RAM 236. As described above, since the pachinko machine 10 uses the NAND flash memory 234a as the character ROM 234, it produces a big hit effect (opening effect, round effect, ending effect) due to its slow reading speed. It takes a lot of time for the image data to be used to be transferred from the character ROM 234 to the normal video RAM 236.

  Since the display round number command indicating the newly started round number is transmitted from the sound lamp control device 113 at the timing when the opening effect in the third symbol display device 81 is completed, the first round is indicated. If the image data necessary for the round effect is transferred from the character ROM 234 to the normal video RAM 236 after receiving the display round number command, a lot of waiting time is required from the end of the opening effect to the start of the round effect. There is a possibility that time will be generated, and the player will feel uneasy as to whether or not the operation has stopped, or give a sense of incongruity.

  In addition, since the display ending command for instructing the start of the ending effect is transmitted from the audio lamp control device 113 at the timing when all the round effects on the third symbol display device 81 (16 rounds) are completed, If the image data necessary for the ending effect is transferred from the character ROM 234 to the normal video RAM 236 after receiving the display ending command, a long waiting time is required between the end of the round effect and the start of the ending effect. This may cause the player to feel uneasy as to whether or not the operation has stopped, or to give the player a sense of discomfort.

  Therefore, in the present control example, when the opening command for display is received, the transfer of the data necessary for the round effect and the ending effect is started from there, and until the fluctuation display of the big hit is completed on the third symbol display device 81. , And the transfer of the data necessary for the round effect and the ending effect is controlled to end. Thus, when the opening effect is completed on the third symbol display device 81, the round effect can be immediately started on the third symbol display device 81, and all of the round effects on the third symbol display device 81 (16 rounds). ) When the game is over, the ending effect can be immediately started on the third symbol display device 81, so that the player does not have anxiety as to whether or not the operation is stopped, and does not give a sense of discomfort. Therefore, the player can be relieved.

  As described above, in the present control example, when the stop type information indicated by the display stop type command is determined to be the jackpot stop type, transfer of image data used in the opening effect is started from there. The control is performed so that the transfer of the image data used in the opening effect is completed by the end of the variable effect that becomes a big hit in the third symbol display device 81. With this, when the variable effect that becomes a big hit on the third symbol display device 81 ends, the opening effect can be immediately started on the third symbol display device 81, and the player is concerned that the operation is not stopped. And it doesn't make you feel uncomfortable. Therefore, the player can be relieved.

  Here, the map setting process (S3001) will be described in detail with reference to FIG. FIG. 120 is a flowchart showing the map setting process (S3001). The map setting process (S3001) is executed in the jackpot-related command process (see FIG. 118) executed by the MPU 231 of the display control device 114, and is a process for setting a map displayed in the jackpot effect.

  In the map setting process, first, the data of the game state storage area 233m is acquired (S3301), and it is determined whether the acquired game state is in the process of probable change or reduction in time (S3302). In the process of S3302, when it is determined that the gaming state is in the process of changing probability or working hours (S3302: Yes), the continuation counter 223p is incremented by 1 (S3303), and the data of the previous map is read from the map storage area 233s. (S3304), a mass event is selected and set from the continuous mass setting table 233t2 based on the value of the continuous counter 233p and the value of the display effect counter (S3305), and the process ends.

  On the other hand, in the process of S3302, when it is determined that the gaming state is not in the probability change or the time reduction (S3302: No), it is determined whether or not there is a continuity passage history by referring to the route history storage area 233w. (S3306).

  In the process of S3306, when it is determined that there is no continuous history passing history (S3306: Yes), since there is no map to continue, the first map is read (S3307), and the big hit variation pattern and the value of the display effect counter 233o are read. Based on this, a mass event is selected and set from the normal mass setting table 233t1 (S3308), and the process ends.

  On the other hand, if it is determined in the process of S3306 that there is a continuum passing history (S3306: No), it is determined whether or not there is a non-passing cell (S3309). In the process of S3309, when it is determined that there is a non-passed cell (S3309: Yes), the previous map and the event cell are read from the map storage area 233s to perform the effect continuously from the previous map (S3310). ), The restart point is set to the continuum of the route having the unpassed cell closest to the start (S3311), and this processing ends.

  In the process of S3309, when it is determined that there is no unpassed cell (S3309: No), a map different from the previous map is read from the map storage area 233s to move to a new map (S3312), and the big hit variation pattern is displayed. A mass event is selected and set from the normal mass setting table 233t1 based on the value of the effect counter 233o (S3313), and the process ends.

  Returning to FIG. 118, the description will be continued. In the processing of S2901, if it is determined that there is no display opening command (S2901: No), then it is determined whether or not there is a display round number command among unprocessed commands (S2903). If there is a round number command for use (S2903: Yes), round number command processing is executed (S2904), and this processing ends.

  Here, the details of the round number command processing (S2904) will be described with reference to FIG. 119 (b). FIG. 119 (b) is a flowchart showing the round number command processing. This round number command process executes a process corresponding to the display round number command received from the audio lamp control device 114.

  In the round number command processing, first, the round number display data table is determined based on the round number indicated by the display round number command and the data in the mass event storage area 233u, and the determined round number display data table is stored in the data table. It is read from the round effect table storage area of the storage area 233b (see FIG. 86) and set in the display data table buffer 233d (S3101). Next, the contents are cleared by writing Null data in the transfer data table buffer 233e (S3102).

  Then, based on the round number display data table set in the display data table buffer 233d by the process of S3101, time data representing the effect time is set in the time counter 233h (S3103), and the pointer 233f is initialized to 0. (S3104). Then, both the demonstration display flag and the confirmed display flag are set to off (S3105), the round number command processing is ended, and the processing returns to the command determination processing.

  Here, the description returns to FIG. In the process of S2903, if it is determined that there is no display round number command (S2903: No), then it is determined whether or not an unprocessed command includes a display ending command (S2905). If there is an ending command for use (S2905: Yes), ending command processing is executed (S2906), and this processing ends. On the other hand, in the process of S2905, if there is no ending command for display (S2905: No), the process of S2906 is skipped, and this process ends.

  Here, the ending command processing (S2906) will be described in detail with reference to FIG. FIG. 121 is a flowchart showing the ending command processing. This ending command processing is to execute processing corresponding to the display ending command received from the audio lamp control device 114.

  In the ending command process, first, it is determined whether or not there is a big hit in the hold in the data of the winning information storage area 233k (S3401). If it is determined in the process of S3401 that there is a jackpot in the hold (S3401: Yes), the mass event is updated based on the information of the jackpot hold and the display effect counter 233o (S3402), and the process of S3403 is performed. Move to. In the process of S3402, for example, when there is a jackpot in the hold, a square two squares ahead of the current location square (that is, a square that can be reached by generating two jackpots) is set as a special square (FIG. 74 ( b)). By setting the two squares as the special squares, the player expects at least two more jackpots to continue the game.

  Next, an ending display data table corresponding to the display mode of the ending effect indicated by the display ending command is determined (S3403), and the determined ending display data table is stored in the ending effect table storage area of the data table storage area 233b (FIG. 86, and is set in the display data table buffer 233d (S3404). Next, the contents are cleared by writing Null data in the transfer data table buffer 233e (S3405). Then, based on the ending display data table set in the display data table buffer 233d by the processing of S3401, time data representing the presentation time is set in the time counter 233h (S3406), and the pointer 233f is initialized to 0 (S3406). S3407). Then, both the demonstration display flag and the confirmed display flag are set to OFF (S3408), the ending command process is completed, and the process returns to the command determination process.

  By executing the ending command processing, the ending effect can be displayed on the third symbol display device 81 when the special symbol big hit ends, so that the player recognizes that the big hit has ended. Can be done.

  Returning to the description of FIG. 113, the description is continued. In the processing of S2310, if it is determined that there is no ending command for display (S2310: No), then it is determined whether or not there is a back image change command among the unprocessed commands (S2312). If there is a change command (S2312: Yes), a back image change command process is executed (S2313), and the process returns to S2301.

  Here, the details of the back image change command processing (S2313) will be described with reference to FIG. FIG. 122 is a flowchart showing the back image change command processing. The rear image change command process executes a process corresponding to the rear image change command received from the audio lamp control device 114.

  In the rear image change command process, first, a rear image change flag for notifying the normal image transfer setting process (see FIG. 131) of the change of the rear image due to the reception of the rear image change command in the ON state is set to ON (see FIG. 131). S3501). Then, based on the current background image and the background addition flag 223x, a back image type (back A to C, super back notice, background in door, etc.) is selected, and a back image discrimination flag corresponding to the selected back image type. Is turned on, the back image discrimination flags corresponding to the other back image types are set to off (S3503), and the process shifts to S3504.

  In the process of S3504, it is determined whether or not the selected back image type is the super background notice (S3504). If it is determined in the processing of S3504 that it is a super background notice, the super background flag 233r is set to ON (S3505), and this processing ends. On the other hand, if it is determined in step S3504 that the notice is not the super background notice, the process in step S3505 is skipped, and the process ends. By turning on the super background flag 233r in the process of S3505, the super background SW process (S3602) that performs the process based on the switch operation during the super background in the SW related command process (see FIG. 123) described later. Can be performed.

  In the normal image transfer setting process, upon detecting that the rear image change flag set in the process of S3501 is turned on, the rear image type after the change is identified from the rear image determination flag set in the process of S3502. . If the specified rear image type is the rear surface B or the rear surface C, as described above, a part of the image data corresponding to those rear images is resident in the rear image area 235c of the resident video RAM 235. Since the image data corresponding to the rear image in the predetermined range is not transferred, a transfer instruction is set to the image controller 237 so as to transfer the image data corresponding to the rear image from the character ROM 234 to the predetermined sub-area of the image storage area 236a of the normal video RAM 236.

  Also, in the task processing (S2204), when it is specified that any one of the back A to C, the super back notice, the background in the door, and the like is displayed according to the back type of the back image specified in the display data table. , The type of the rear image to be displayed at that time is specified from the rear image determination flag set by the processing of S3502, and the range of the rear image to be displayed is specified in accordance with the elapse of time. The RAM type (resident video RAM 235 or normal video RAM 236) storing the image data corresponding to the range and the address of the RAM are specified.

  Since the player does not continuously operate the frame button 22 for less than 20 milliseconds, the player does not receive two or more rear image change commands within 20 milliseconds. In this case, there should be no case where two or more back image change commands are stored in the command buffer area, but some of the commands change due to the influence of noise or the like, and another command erroneously changes the back image. It may be interpreted as a command. In the process of S3502, when it is determined that two or more rear image commands are stored in the command buffer area, the rear image type indicated by the previously received rear image command may be selected, or the rear image type received later may be selected. The back image type indicated by the back image command may be selected. Alternatively, one arbitrary back image change command may be extracted, and the back image type indicated by the command may be selected. Since the change of the back image does not directly affect the game value of the pachinko machine 10, it is preferable to appropriately set the change according to the characteristics and operability of the pachinko machine 10.

  Here, the description returns to FIG. In the process of S2312, when it is determined that there is no rear image change command (S2312: No), it is then determined whether there is a SW-related command among the unprocessed commands (S2314). In the process of S2314, when it is determined that there is a SW-related command (S2314: Yes), a SW-related command process is executed (S2315), and the process returns to S2301.

  Here, the details of the SW-related command processing (S2315) will be described with reference to FIG. FIG. 123 is a flowchart showing the SW-related command processing (S2315). The SW-related command processing (S2315) executes processing corresponding to a command based on a switch operation received from the audio lamp control device 114.

  In the SW-related command processing, first, it is determined whether or not the super background flag 233r is on (S3601). If it is determined in the processing of S3601 that the super background flag 233r is ON (S3601: Yes), the super background notice is being displayed, and the super background middle SW that performs processing based on the switch operation during the super background is displayed. The processing is executed (S3602), and this processing ends.

  Here, with reference to FIG. 124, details of the super background middle SW process (S3602) will be described. FIG. 124 is a flowchart showing the super background middle SW process (S3602). The super background middle SW process (S3602) is a process for executing an effect based on the operation of the selection switch 270 or the like while the super background notice is being displayed.

  In the super background middle SW process, first, it is determined whether or not the decision switch 270e is pressed (S3701). In the process of S3701, when it is determined that the determination switch 270e is pressed (S3701: Yes), the display data of the currently displayed background image is obtained (S3702), and it is determined whether or not the display is capable of shifting. (S3703). Here, the display indicating that transition is possible indicates a case where the specific image is displayed in the rear image, and a case where the image of the door is blinking in the present control example (see FIG. 67).

  In the process of S3703, when it is determined that the display is not during the transferable display (S3703: No), the process ends as it is. On the other hand, if not (S3703: Yes), the value of the in-door change frequency counter 223y is set to 20 (S3704), the data of the winning information storage area 233k is obtained (S3705), and the value of the display effect counter 233o is obtained. Is acquired (S3706), and the process proceeds to S3707.

  In the processing of S3707, it is determined whether or not there is a big hit in the hold in the data of the winning information storage area 233k acquired in the processing of S3705 (S3707). If it is determined that there is a big hit in the hold (S3707) : Yes), then, it is determined whether or not the value of the display effect counter 233o acquired by the process of S3706 is 0 to 100 (S3708).

  In the process of S3708, when it is determined that the display effect counter 233o is 0 to 100 (S3708: Yes), the rear image determination flag corresponding to the high expectation inside door background is set to ON (S3709), The process shifts to S3714. On the other hand, when it is determined that the display effect counter 233o is not 0 to 100 (that is, 101 to 198) (S3708: No), the rear image determination flag corresponding to the low expectation inside the door is set to ON. Then, the flow shifts to the processing of S3714.

  On the other hand, if it is determined in the process of S3707 that there is no big hit in the hold (S3707: No), then it is determined whether the value of the display effect counter 233o is 0 to 30 (S3711).

  In the process of S3711, when it is determined that the display effect counter 233o is 0 to 30 (S3711: Yes), the rear image determination flag corresponding to the high expectation inside door background is set to ON (S3712). The process shifts to S3714. On the other hand, when it is determined that the display effect counter 233o is not 0 to 30 (that is, 31 to 198) (S3711: No), the rear image determination flag corresponding to the low expectation inside the door is set to ON. Then, the flow shifts to the processing of S3714.

  In the processing of S3714 executed after S3709, S3710, S3712 or S3713, the back image change flag 233q is set to ON (S3714), and this processing ends. By setting the back image change flag 233q to ON in the processing of S3714, the back image of the background in the door set in any of S3709, S3710, S3712 or S3713 can be displayed.

  Note that the back image data is set in the normal image transfer setting process (see FIG. 131) by the back image change flag 233q set to ON in the process of S3714, and the back image is changed. The timing at which the data of the rear image is set may be synchronized with the timing at which the next variable display is started, or may be synchronized with the timing at which the currently executed variable display ends. good. As a method of synchronizing with each of the above-mentioned timings, a method of adjusting the timing of setting the back image change flag 233q to on in the processing of S3714, or a method of setting the back image data in the normal image transfer setting processing (see FIG. 131). For example, a method of adjusting the timing to be performed is exemplified. Specifically, in the process of S3714, a time difference from the synchronization timing is calculated, and after the calculated time elapses, the rear image change flag 233q is set to ON to adjust the timing at which the rear image is changed. be able to.

  Here, by the processing of S3707, S3708, and S3709, the ratio of setting the high expectation inside-door background is different depending on whether there is a jackpot in the hold. In other words, the display content of the background in the door for the player is one of the information for predicting the possibility that there is a big hit in the hold. Thereby, the player who wants to know this information plays the game while paying attention to the display of the specific image, which is the timing at which the background inside the door can be displayed. As a result, the interest of the player can be improved.

  On the other hand, if it is determined in the processing of S3701 that the determination switch 270e has not been pressed (S3701: No), then it is determined whether any of the selection switches (up switch 270a to left switch 270d) has been pressed. It is determined (S3715).

  In the process of S3715, if it is determined that any of the selection switches (up switch 270a to left switch 270d) has been pressed (S3715: Yes), it is determined based on the pressed selection switch (up switch 270a to left switch 270d). Then, the display coordinates are reset (S3716), and this process ends. If not (S3715: No), the process ends.

  Here, the scroll display of the back image is executed based on the set display coordinates. More specifically, display coordinates for displaying the rear image are stored in chronological order, and the rear images corresponding to the display coordinates are displayed in the order in which they are stored. For example, if the display coordinates are stored so as to increase only in the horizontal direction, the rear image is scroll-displayed in the horizontal direction (to the right of the third symbol display device 81).

  In the process of S3716, for example, the display coordinates set to increase only in the horizontal direction are fixed at the current value in the horizontal direction based on the depression of the upper switch 270a, and the display direction is increased in the vertical direction. Reset the display coordinates as follows. Thus, the rear image scrolled horizontally (to the right of the third symbol display device 81) can be changed so as to be scrolled vertically (toward the third symbol display device 81).

  As a result, it is possible to give the player a feeling as if he or she is searching within the back image of the super background notice displayed on the third symbol display device 81 by his / her own operation. Can be improved. Further, the background image of the super background notice includes a specific image (an image of the door in the present control example) necessary for displaying the in-door background as described above. Thereby, the player who wants to display the in-door background performs a search in the back image of the super-background notice with more interest in order to find the specific image, so that the interest of the player can be improved.

  Returning to FIG. 123, the description will be continued. If it is determined in the processing of S3601 that the super background flag 233r is not turned on (S3601: No), then it is determined whether or not a jackpot effect is being produced (S3603). If it is determined in the processing of S3603 that a jackpot effect is being produced (S3603: Yes), a jackpot medium SW process is executed (S3604), and this process ends. Otherwise (S3603: No), the process of S3604 is skipped, and the process ends.

  Here, with reference to FIG. 125, details of the big hit SW process (S3604) will be described. FIG. 125 is a flowchart showing the big hit SW process. The big hit SW process executes a process corresponding to a display command based on the operation of the selection switch 270 and the like received from the audio lamp control device 114 during the big hit effect.

  In the big hit SW process, first, it is determined whether or not it is a SW valid period within a round (S3801). If it is determined in the processing of S3801 that the current period is not the SW valid period within the round (S3801: No), the processing is terminated as it is not the timing to perform the effect based on the switch operation.

  On the other hand, if it is determined in the processing of S3801 that the current period is the SW valid period within the round (S3801: Yes), it is then determined whether any of the selection switches (up switch 270a to left switch 270d) has been pressed. (S3802).

  In the process of S3802, if it is determined that any of the selection switches (up switch 270a to left switch 270d) has been pressed (S3802: Yes), it is determined whether the selection is normal (S3803). Specifically, when the movable direction in the map of the jackpot effect is down or right (see FIG. 72A), the case where the down switch 270c or the left switch 270d is pressed is a normal selection. Is determined.

  If it is determined in the processing of S3803 that the selection is normal (S3803: Yes), the pointer 233f is set so that the display moves by one cell in the selection direction (S3804), and the flow shifts to the processing of S3805.

  On the other hand, if it is determined in step S3803 that the selection is not normal (S3803: No), the process skips step S3804 and shifts to step S3805.

  In the process of S3805, it is determined whether or not the decision switch 270e has been pressed (S3805). In the process of S3805, when it is determined that the determination switch 270e is pressed (S3805: Yes), it is determined whether a determinable cell is selected (S3806). Specifically, when the same cell as the previous cell is selected, it is determined that no determinable cell is selected.

  In the process of S3806, if it is determined that a determinable cell is not selected (S3806: No), the process ends as it is. On the other hand, if not (S3806: Yes), the event of the determined cell is stored in the cell event storage area 233u (S3807), and the determined cell is added to the route history storage area (S3808), and the process proceeds to S3809. Transition.

  By the processing of S3807, a round effect by the round number command processing (see FIG. 119 (b)) can be executed based on the mass event stored in the mass event storage area 233u. Also, in the process of S3808, based on the route history stored in the route history storage area 233w, the above-described map setting process (see FIG. 120) determines whether there is a non-passing cell (whether a new map is displayed or not). Discrimination) becomes possible.

  In the processing of S3809 executed after the processing of S3808, it is determined whether or not the determined mass event is background addition (S3809). In the processing of S3809, when it is determined that the mass event is background addition (S3809: Yes), the background addition flag 233x is set on based on the display effect counter 233o (S3810). Specifically, when the display effect counter 233o is 0 to 100, the background addition flag 233x is set to ON. The present invention is not limited to this. A plurality of backgrounds to be added (for example, additional background A, additional background B) are prepared, and when the display effect counter 233o is 0 to 50, the background addition flag 233x for adding the additional background A is turned on. When the display effect counter 233o is 51 to 100, the background addition flag 233x for adding the additional background B may be set to ON.

  On the other hand, if it is determined in the process of S3809 that the event is not a background addition (S3809: No), the process ends.

  Here, the description returns to FIG. In the process of S2314, if it is determined that there is no SW-related command (S2314: No), then, it is determined whether or not there is a winning command for display among unprocessed commands (S2216). In the process of S2216, if there is a winning command for display (S2216: Yes), winning information based on the received command is stored in the winning information storage area 233k (S2317), and the process returns to S2301.

  The winning information stored in the winning information storage area 233k by the processing of S2317 is used for selecting a display effect in the above-described super background effect process (see FIG. 115).

  On the other hand, if it is determined in the processing of S2316 that there is no winning command for display (S2316: No), it is then determined whether or not there is an error command among the unprocessed commands (S2318). If there is (S2318: Yes), an error command process is executed (S2319), and the process returns to S2301.

  Here, the error command processing (S2319) will be described in detail with reference to FIG. FIG. 126 is a flowchart showing the error command processing. This error command process executes a process corresponding to the error command received from the audio lamp control device 114.

  In the error command processing, first, an error occurrence flag indicating that an error has occurred in the ON state is set to ON (S3901). Then, among the error determination flags provided for each error type, the error determination flag corresponding to the error type indicated by the error command is turned on, and the other error determination flags are set to off (S3902). The process ends, and returns to the command determination process.

  In the display setting process, when the occurrence of an error is detected based on the error occurrence flag set in the process of S3901, the type of error that occurred based on the error determination flag set in the process of S3902 is determined, and the corresponding error type is determined. The processing is executed so that the warning image to be displayed is displayed on the third symbol display device 81.

  If it is determined that two or more error commands are stored in the command buffer area, in step S3902, error determination flags corresponding to all error types indicated by the respective error commands are set to ON. As a result, warning images corresponding to all error types are displayed on the third symbol display device 81, so that a player or a person related to the hall can correctly grasp the occurrence state of the error.

  Here, the description returns to FIG. If it is determined in the processing of S2318 that there is no error command (S2318: No), then processing corresponding to other unprocessed commands is executed (S2320), and the processing returns to S2301.

  In the processing of S2301 executed again after the processing of each command is executed, it is determined again whether or not there is an unprocessed new command in the command buffer area, and if there is an unprocessed new command (S2301: Yes) ), And execute the processing of S2302 to S2320 again. Until there is no unprocessed new command in the command buffer area, the processing of S2301 to S2320 is repeatedly executed. If it is determined in the processing of S2301 that there is no unprocessed new command in the command buffer area, this command determination is performed. The process ends.

  Note that the simple command determination process (S2209) executed when the simple image display flag 233c is ON in the V interrupt process (see FIG. 112B) is similar to the command determination process. However, in the simple command determination process, only the commands necessary for displaying the image at power-on, that is, the display variation pattern command and the display stop type command are extracted from the unprocessed commands stored in the command buffer area. Extraction and execution of variation pattern command processing (see FIG. 114 (a)) and stop type command processing (see FIG. 114 (b)), which are processing corresponding to each command, are performed. Then, a process for discarding the command without executing the process corresponding to the command is performed.

  Here, in the fluctuation pattern command processing (see FIG. 114A) executed in this case, in the processing of S2402, the display data table buffer corresponding to the display of the power-on fluctuation image is stored in the display data table buffer 233d. The image data of the power-on main image and the power-on fluctuation image which are set and necessary in that case are stored in the power-on main image area 235a and the power-on fluctuation image area 235b of the resident video RAM 235. Therefore, in the process of S2302, a process of writing Null data in the transfer data table buffer 233b and clearing the contents is performed.

  Next, the details of the above-described display setting process (S2203), which is one process of the V interrupt process executed by the MPU 231 of the display control device 114, will be described with reference to FIGS. 127 to 129. FIG. 127 is a flowchart showing this display setting process.

  In this display setting process, as shown in FIG. 127, it is determined whether or not the new command flag is on (S4001), and if the new command flag is not on, that is, off (S4001: No), In the previously executed command determination process, it is determined that the new command has not been processed, and the process of S4002 to S4004 is skipped, and the process proceeds to S4005. On the other hand, if the new command flag is on (S4001: Yes), it is determined that the new command has been processed in the previously executed command determination processing, the new command flag is set to off (S4002), and then S4003 to S4004. The processing corresponding to the new command is executed.

  In the process of S4003, it is determined whether or not the error occurrence flag is on (S4003). If the error occurrence flag is on (S4003: Yes), a warning image setting process is executed (S4004).

  Here, the warning image setting process will be described in detail with reference to FIG. FIG. 128 is a flowchart showing the warning image setting process. This process is a process for developing image data for displaying a warning image corresponding to an error that has occurred on the third symbol display device 81. First, referring to the error determination flag, all error determinations for which ON is set are set. The warning image data for displaying the error warning image corresponding to the flag on the third symbol display device 81 is developed (S4101).

  In the task processing (S2204), based on the expanded warning image data, the type of the sprite (display object) constituting the warning image is specified, and the display coordinate position, enlargement ratio, rotation angle, and the like are specified for each sprite. Determine various parameters required for drawing.

  Then, in the warning image setting process, after the process of S4101, the error occurrence flag is set to off (S4102), and the process returns to the display setting process.

  Here, the description returns to FIG. 127. After the warning image setting process (S4004) or in the process of S4003, if it is determined that the error occurrence flag is not on, that is, it is off (S4003: No), the process proceeds to S4005.

  In S4005, a pointer update process is performed (S4005). Here, the details of the pointer update processing will be described with reference to FIG. FIG. 129 is a flowchart showing the pointer update processing. This pointer updating process acquires the corresponding drawing content or transfer data information of the transfer target image data from the display data table and the transfer data table stored in the display data table buffer 233d and the transfer data table buffer 233e, respectively. This is a process of updating the pointer 233f specifying the address to be set.

  In this pointer update process, first, 1 is added to the pointer 233f (S4201). That is, the pointer 233f is updated in principle such that it is incremented by one each time the V interrupt processing is executed. As described above, in the various data tables, the start information is described at the address “0000H”, and the entity of each data is defined after the address “0001H”. When the value of the pointer 233f is initialized to 0 in accordance with being stored in the data table buffer 233d, the value is updated to 1 by this pointer update processing. Substantial data can be read from the data table.

  After the value of the pointer 233f is updated by the processing of S4201, next, in the display data table set in the display data table buffer 233d, it is determined whether or not the data at the address indicated by the updated pointer 233f is End information. Is determined (S4202). As a result, if it is End information (S4202: Yes), it means that the pointer 233f has been updated past the address where the actual data is described in the display data table set in the display data table buffer 233d.

  Therefore, it is determined whether or not the display data table stored in the display data table buffer 233d is a demo display data table (S4203). If the display data table is a demo display data table (S4203: Yes), the display data table buffer is determined. The time data corresponding to the presentation time of the demonstration display data table set in 233d is set in the time counter 233h (S4204), the pointer 233f is set to 1 and initialized (S4205), and the present processing is terminated and the display is completed. Return to the setting process. Thus, in the display setting process, the rendering contents can be developed in order from the top of the demonstration display data table, so that the third symbol display device 81 can repeatedly display the demonstration effect.

  On the other hand, if it is determined in the process of S4203 that the display data table stored in the display data table buffer 233d is not the demonstration display data table (S4203: No), the value of the pointer 233f is decremented by 1 (S4206). ), End this processing, and return to the display setting processing. Thereby, in the display setting process, when a display data table other than the demonstration display data table, for example, a variable display data table is set in the display data table buffer 233d, the previous address of the end information is described. Since the drawing content is always developed, the third symbol display device 81 can display the last image defined by the display data table in a stopped state. On the other hand, in the process of S4202, if the data of the address indicated by the updated pointer 233f is not End information (S4202: No), the process ends, and the process returns to the display setting process.

  Here, returning to FIG. 127, the description will be continued. After the pointer updating process, the drawing content of the address indicated by the pointer 233f updated by the pointer updating process is developed from the display data table set in the display data table buffer 233d (S4006). In the task process (S2204), the type of sprite (display object) constituting the image is specified based on the drawing content expanded in the process of S4006 together with the previously expanded warning image and the like. Various parameters required for drawing, such as a display coordinate position, an enlargement ratio, and a rotation angle, are determined.

  Next, the value of the time counter 233h is decremented by 1 (S4007), and it is determined whether or not the value of the time counter 233h after the subtraction is 0 or less (S4008). Then, when the value of the time counter 233h is 1 or more (S4008: No), the display setting process is ended and the process returns to the V interrupt process. On the other hand, when the value of the time counter 233h is 0 or less (S4008: Yes), it means that the effect time of the effect corresponding to the display data table set in the display data table buffer 233d has elapsed. At this time, if the variable display data table is set in the display data table buffer 233d, it is the timing to end the variable display and perform the stop display, so it is confirmed whether or not the confirmed display flag is on. (S4009).

  As a result, if the confirmed display flag is off (S4009: No), the effect of the confirmed display has not been performed yet, and it is the timing to perform the effect of the confirmed display. First, the confirmed display data table is stored in the display data table buffer 233d. The setting is made (S4010), and then the contents are cleared by writing Null data in the transfer data table buffer 233e (S4011). Then, time data corresponding to the presentation time in the confirmed display data table is set in the time counter 233h (S4012), and the value of the pointer 233f is initialized to 0 (S4013). Then, after the final display flag indicating that the final display effect is being performed in the ON state is set to ON (S4014), the content of the stop symbol determination flag is directly copied to the previous stop symbol determination flag provided in the work RAM 233. (S4015), and returns to the V interrupt processing.

  Thus, in the case where the variable display data table is set in the display data table buffer 233d, the final display effect of the stop symbol in the variable effect is displayed on the third symbol display device 81 in accordance with the end of the effect. Thus, the drawing content can be set. Further, by simply changing the display data table set in the display data table buffer 233b to the confirmed display data table, the effect to be displayed on the third symbol display device 81 can be easily changed to the confirmed display effect. Compared with the case where the display content is changed by activating another program as in the related art, the program is not complicated and bloated, so that no great load is applied to the MPU 231. Regardless of the processing capability of the display control device 114, various effect images can be displayed on the third symbol display 81.

  Note that the last stop symbol determination flag set by the process of S4015 is used to specify the third symbol to be displayed on the third symbol display device 81 in the next variable effect. That is, as described above, the display of the third symbol in the variable effect changes according to the stop symbol of the variable effect performed immediately before, and in the variable display data table, the change based on the data table is not changed. Until a predetermined time has elapsed from the start, the symbol offset information from the stop symbol of the variable effect performed immediately before is described. In the task process (S2204), until the predetermined time has elapsed since the start of the fluctuation, the stop symbol of the fluctuation effect performed immediately before is specified from the previous stop symbol determination flag set in S4015, and By adding the symbol offset information acquired by the display setting process to the specified stopped symbol, the third symbol to be actually displayed is specified. Thereby, the variable effect is started from the stop symbol in the immediately preceding variable effect.

  On the other hand, in the process of S4009, if the confirmed display flag is not on but off (S4009: No), it is determined whether the demonstration display flag is on (S4016). If the demonstration display flag is off (S4016: Yes), it means that the value of the clock counter 233h has become 0 or less with the end of the finalized display effect, so that the demonstration display data table is displayed in the display data table. The contents are set in the buffer 233d (S4017), and then the contents are cleared by writing Null data in the transfer data table buffer 233e (S4018). Then, time data corresponding to the effect time in the demonstration display data table is set in the time counter 233h (S4019). Then, the pointer 233f is initialized to 0 (S3320), the demonstration display flag indicating that the demonstration is being performed in the ON state is set to ON (S4021), and the present process ends, and the process returns to the V interrupt process.

  Thereby, when the display variation pattern command indicating the start of the next variation effect is not received after the final display effect is completed, the demonstration effect is automatically displayed on the third symbol display device 81. Can be set the drawing content.

  In the process of S4016, if the demonstration display flag is ON (S4016: No), the demonstration effect is performed after the finalized display effect ends, and this means that the demonstration effect has ended, so the display setting process ends as it is. Then, the process returns to the V interrupt processing. Then, in this case, as described above, various settings are performed by the pointer update process executed in the next V interrupt process so that the demonstration effect is started again. Until a new display variation pattern command is received, the demonstration effect can be repeatedly displayed on the third symbol display device 81.

  Note that the same processing as the display setting processing is also performed in the simple display setting processing (S2209) executed when the simple image display flag 233c is ON in the V interrupt processing (see FIG. 112B). However, in the simple display setting process, after the effect time of the fluctuation effect by the power-on fluctuation image ends, for a predetermined time, a simple power-on fluctuation image according to the stop symbol set based on the display stop type command. A process of setting a display data table that defines that the image is stopped and displayed in the display data table buffer 233d is performed.

  Next, with reference to FIG. 130 and FIG. 131, details of the above-described transfer setting process (S2205), which is one process of the V interrupt process executed by the MPU 231 of the display control device 114, will be described. First, FIG. 130A is a flowchart showing the transfer setting process.

  In this transfer setting process, first, it is determined whether or not the simple image display flag 233c is on (S4301). If the simple image display flag 233c is on (S4301: Yes), all image data to be resident in the resident video RAM 235 has not been transferred from the character ROM 234 to the resident video RAM 235, so the resident image transfer setting process Is executed (S4302), the transfer setting process ends, and the process returns to the V interrupt process. Thereby, a transfer instruction is set to the image controller 237 to transfer the image data to be resident in the resident video RAM 235 from the character ROM 234 to the resident video RAM 235. The details of the resident image transfer setting process will be described later with reference to FIG.

  On the other hand, as a result of the processing in S4301, if the simple image display flag 233c is not on, that is, if it is off (S4301: No), all the image data to be resident in the resident video RAM 235 is transferred from the character ROM 234 to the resident video. The data has been transferred to the RAM 235. In this case, the normal image transfer setting process is executed (S4303), the transfer setting process ends, and the process returns to the V interrupt process. As a result, a transfer instruction is set so that the subsequent transfer of image data from the character ROM 234 is performed to the normal video RAM 236. The details of the normal image transfer setting process will be described later with reference to FIG.

  Next, the resident image transfer setting process (S4302), which is one of the transfer setting processes (S2205) executed by the MPU 231 of the display control device 114, will be described with reference to FIG. FIG. 130B is a flowchart showing the resident image transfer setting process (S4302).

  In the resident image transfer setting process, first, it is determined whether or not an instruction to transfer untransferred image data has been issued to the image controller 237 (S4401). If the transfer instruction has been transmitted (S4401: Yes) Further, it is determined whether or not the image data transfer process performed by the image controller 237 based on the transfer instruction has been completed (S4402). In the process of S4402, after instructing the image controller 237 to transfer the image data, if a transfer end signal indicating the end of the transfer process is received from the image controller 237, it is determined that the transfer process has ended. . If it is determined that the transfer process is not completed by the process of S4402 (S4402: No), since the image transfer process is continuously performed in the image controller 237, the resident image transfer setting process is performed. finish. On the other hand, when it is determined that the transfer process has been completed (S4402: Yes), the process proceeds to S4403. Also, as a result of the process of S4401, if the transfer instruction of the untransferred image data has not been transmitted to the image controller 237 (S4401: No), the process proceeds to S4403.

  In the process of S4403, it is determined whether or not all the resident target image data to be resident in the resident video RAM 235 has been transferred (S4403). If there is an untransferred resident target image data (S4403: No), the process proceeds to S4403. A transfer instruction to the image controller 237 is set to transfer the resident image data to be transferred from the character ROM 234 to the resident video RAM 235 (S4404), and the resident image transfer setting process ends.

  As a result, the drawing list transmitted to the image controller 237 in the drawing processing includes the transfer data information on the untransferred resident target image data, and the image controller 237 transmits the transfer data described in the drawing list. The resident object image data can be transferred from the character ROM 234 to the resident video RAM 236 based on the data information. The transfer data information includes the start address and the end address of the character ROM 234 in which the resident target image data is stored, the information of the transfer destination (in this case, the resident video RAM 235), and the transfer destination (the transfer is performed here). The head address of an area provided in the resident video RAM 235 where the resident target image data is to be stored is included. The image controller 237 executes an image transfer process based on the transfer data information, reads out the image data specified in the transfer process from the character ROM 234, temporarily stores the read image data in the buffer RAM 237a, and then stores the image data in the unused period of the resident video RAM 236. Then, the data is transferred to the designated address of the resident video RAM 236. Then, when the transfer is completed, a transfer end signal is transmitted to the MPU 231.

  As a result of the processing in S4403, if all the resident target image data has been transferred (S4403: Yes), the simple image display flag 233c is set to off (S4405), and the resident image transfer setting processing ends. Thus, in the V interrupt processing (see FIG. 112 (b)), the command is not the simple command determination processing (see S2208 in FIG. 112 (b)) and the simple display setting processing (see S2209 in FIG. 112 (b)). Since the determination process (see FIGS. 113 to 126) and the display setting process (see FIGS. 127 to 129) are performed, the drawing of the image in the normal state is set. Displays the normal image. Further, the subsequent transfer of image data from the character ROM 234 is performed to the normal video RAM 236 by the normal image transfer setting process (see FIG. 131) (see S4301: No in FIG. 130A).

  By executing the resident image transfer setting process, the MPU 231 performs all resident operations to be resident in the resident video RAM 235 except for the power-on main image and the power-on fluctuation image that have already been transferred in the main process. The target image data can be transferred from the character ROM 234 to the resident video RAM 235. Then, the MPU 231 controls the image data transferred to the resident video RAM 235 so as to be maintained without being overwritten during power-on. Thus, the image data transferred to the resident video RAM 235 by the resident image transfer setting process is resident in the resident video RAM 235 while the power is on.

  Therefore, after all the image data to be resident in the resident video RAM 235 is transferred to the resident video RAM 235, the display control device 114 uses the image data resident in the resident video RAM 235 while using the image controller 237. Can perform image drawing processing. As a result, if the image data used for the drawing process is resident in the resident video RAM 235, it is not necessary to read the corresponding image data from the character ROM 234 constituted by the NAND flash memory 234a having a low reading speed when drawing an image. Therefore, the time required for the reading can be omitted, the image can be drawn immediately, and the drawn image can be displayed on the third symbol display device 81.

  In particular, the resident video RAM 235 stores image data of frequently displayed images such as a rear image, a third symbol, a character symbol, and an error message, the main controller 110, the sound lamp controller 113, and the display controller 114. After the display is determined by, for example, the image data of the image to be displayed is made resident immediately. Therefore, even if the character ROM 234 is configured by the NAND flash memory 234a, various operations performed at an arbitrary timing by the player can be performed. In addition, the responsiveness until a certain image is displayed on the third symbol display device 81 can be kept high.

  Next, the normal image transfer setting process (S4303), which is one of the transfer setting processes (S2205) executed by the MPU 231 of the display control device 114, will be described with reference to FIG. FIG. 131 is a flowchart showing the normal image transfer setting process (S4303).

  In the normal image transfer setting process, first, a pointer 233f updated from the transfer data table set in the transfer data table buffer 233e by the pointer update process (S4005) of the previously executed display setting process (S2203). The information described at the indicated address is obtained (S4501). Then, it is determined whether or not the acquired information is the transfer data information (S4502). If the obtained information is the transfer data information (S4502: Yes), the character ROM 234 storing the transfer target image data is obtained from the transfer data information. (The storage source start address) and the end address (storage source end address), and the start address of the transfer destination (normal video RAM 236), and store them in the transfer data buffer provided in the work RAM 233 ( (S4503) Further, the transfer start flag provided in the work RAM 233 and indicating that there is image data to be transferred in the ON state is set to ON (S4504), and the process proceeds to S4505.

  Also, in the process of S4502, if the acquired information is not transfer data information but Null data (S4502: No), the processes of S4503 and S4504 are skipped, and the process proceeds to S4505. In the process of S4505, it is determined whether a new image data transfer instruction has been set to the image controller 237 after the previous image data transfer has been completed (S4505), and the transfer instruction is set. If the transfer has been completed (S4505: Yes), it is further determined whether or not the transfer of the image data performed by the image controller 237 has been completed based on the transfer instruction (S4506).

  In the process of S4506, after setting a transfer instruction of image data to the image controller 237 and receiving a transfer end signal indicating the end of the transfer process from the image controller 237, it is determined that the transfer process has ended. . If it is determined in step S4506 that the transfer process has not been completed (S4506: No), the image controller 237 continues the image transfer process. finish. On the other hand, if it is determined that the transfer process has been completed (S4506: Yes), the process proceeds to S4507. Also, as a result of the processing in S4505, if the image data transfer instruction has not been set to the image controller 237 after the end of the previous transfer processing (S4505: No), the process proceeds to S4507.

  In the process of S4507, it is determined whether or not the transfer start flag is on (S4507). If the transfer start flag is on (S4507: Yes), there is image data to be transferred, so the transfer start flag is set. Is turned off (S4508), the image data of the sprite indicated by the various kinds of information stored in the transfer data buffer by the processing of S4503 is set as the transfer target image data, and then the process proceeds to S4513. On the other hand, if the transfer start flag is not on but off (S4507: No), then it is determined whether the back image change flag is on (S4509). If the back image change flag is not on but off (S4509: No), there is no image data to be transferred, and the normal image transfer setting process ends as it is.

  On the other hand, if the back image change flag is on (S4509: Yes), it means that the back image is changed. Therefore, after setting the back image change flag to off (S4510), the back image provided for each back image type is set. Among the determination flags, the image data of the rear image corresponding to the rear image determination flag in the ON state is specified, and the image data is set as the transfer target image data (S4511). Furthermore, the start address (storage source start address) and the end address (storage source end address) of the character ROM 234 storing the image data of the back image corresponding to the back image determination flag in the ON state, and the transfer destination (normal) The start address of the video RAM 236) is acquired (S4512), and the process proceeds to S4513.

  If the back image discrimination flag in the ON state is that of the back A, all the corresponding image data is resident in the back image area 235c of the resident video RAM 235, and the image to be transferred to the normal video RAM 236 is stored. No data exists. Therefore, in the process of S4511, if the rear image discrimination flag in the ON state is that of the rear surface A, the normal image transfer process ends.

  In the process of S4513, it is determined whether or not the transfer target image data has already been stored in the normal video RAM 236 (S4513). The determination in the process of S4513 is performed by referring to the stored image data determination flag 233i. That is, the storage state corresponding to the sprite set as the transfer target image data is read out from the storage image data determination flag 233i, and if the storage state is “ON”, the image data of the transfer target sprite is the normal video data. It is determined that the data is stored in the RAM 236, and if the storage state is “off”, it is determined that the image data of the transfer target sprite is not stored in the normal video RAM 236.

  Then, as a result of the processing in S4513, if the image data to be transferred is stored in the normal video RAM 236 (S4513: Yes), there is no need to transfer the image data from the character ROM 234 to the normal video RAM 236. Then, the normal image transfer setting process ends. As a result, unnecessary transfer of image data from the character ROM 234 to the normal video RAM 236 can be suppressed, and the processing load on each unit of the display control device 114 and the traffic on the bus line 240 can be reduced. Can be planned.

  On the other hand, as a result of the processing in S4513, if the transfer target image data is not stored in the normal video RAM 236 (S4513: No), the transfer instruction of the transfer target image data is set (S4514). Thereby, the transfer data information of the transfer target image data is included in the drawing list transmitted to the image controller 237 in the drawing processing, and the image controller 237 transmits the transfer data information described in the drawing list. Based on this, the image data of the transfer target image can be transferred from the character ROM 234 to the normal video RAM 236. The transfer data information includes the start address and the end address of the character ROM 234 storing the image data of the transfer target image, information on the transfer destination (in this case, the normal video RAM 236), and the transfer destination (here, the transfer destination). The head address of the sub area provided in the image storage area 236a of the normal video RAM 236 in which the image data of the transfer target image to be transferred is stored is included. The image controller 237 executes an image transfer process based on the transfer data information, reads out the image data designated by the transfer process from the character ROM 234, and designates the designated video RAM (here, the normal video RAM 236). To the specified address. Then, when the transfer is completed, a transfer end signal is transmitted to the MPU 231.

  After the processing in S4514, the stored image data determination flag 233i is updated (S4515), and the normal transfer setting processing ends. As described above, the stored image data determination flag 233i is updated by setting the storage state corresponding to the sprite that has become the transfer target image data to “ON”, and by setting the sub state of the image storage area 236a that is the same as the one sprite. This is performed by setting the storage state corresponding to other sprites to be stored in the area to “off”.

  As described above, by executing the normal image transfer processing, the processing corresponding to the display stop type command is executed in the previously executed command determination processing, and as a result, the display stop type command When it is determined that the indicated stop type information is the jackpot type, the image data used in the fanfare effect can be transferred from the character ROM 234 to the normal video RAM 236 without delay. If the back image is changed based on the reception of the back image change command in the previously executed command determination process, the back image of the resident video RAM 235 of the image data used in the back image is used. Image data not stored in the image area 235c can be transferred from the character ROM 234 to the normal video RAM 236 without delay.

  In the present control example, the display data table is stored in the display data table buffer 233d according to a command (for example, a display variation pattern command) transmitted from the audio ramp control device 113 based on a command or the like from the main control device 110. Is set to the transfer data table corresponding to the display data table in the transfer data table buffer 233e. Then, the MPU 231 executes the normal image transfer setting process, and sends the image data to the image controller 237 in accordance with the transfer data information described in the area indicated by the pointer 233f of the transfer data table set in the transfer data table buffer 233e. Since the transfer instruction of the transfer target image data is set, the image data of the sprite used in the display data table set in the display data table buffer 233d is surely transferred from the character ROM 234 to the normal video RAM 236 at a desired timing. Can be.

  Here, in the transfer data table, the image data of the transfer target image data is stored so that the image data corresponding to the predetermined sprite is stored in the image storage area 236a by the time the drawing of the predetermined sprite is started according to the display data table. Since the transfer data information is defined for a predetermined address, the image data is transferred from the character ROM 234 to the image storage area 236a in accordance with the transfer data information defined in the transfer data table, and thus, the predetermined data is defined in accordance with the display data table. When rendering a sprite, image data that is not resident in the resident video RAM 235 and that is required for rendering the sprite can be stored in the image storage area 236a without fail.

  Thus, even if the character ROM 234 is constituted by the NAND flash memory 234a having a low reading speed, an image necessary for display can be read from the character ROM 234 in advance without delay and transferred to the normal video RAM 236. The corresponding effect can be displayed on the third symbol display device 81 while drawing the image of each sprite specified in the data table. Further, by describing the transfer data table, only the non-resident image data in the resident video RAM 235 can be easily and reliably transferred from the character ROM 234 to the normal video RAM 236.

  In the transfer data table, transfer data information is defined so that image data is transferred from the character ROM 234 to the normal video RAM 236 for each image data corresponding to a sprite. Thus, the transfer of the image data can be managed and controlled for each sprite, so that the processing related to the transfer can be easily performed. By controlling the transfer of image data from the character ROM 234 to the normal video RAM 236 on a sprite basis, the image data transfer can be controlled in detail while facilitating the processing. Therefore, it is possible to efficiently suppress an increase in load on transfer.

  Next, with reference to FIG. 132 (a), details of the above-described drawing processing (S2206), which is one processing of the V interrupt processing executed by the MPU 231 of the display control device 114, will be described. FIG. 132A is a flowchart showing this drawing processing.

  In the drawing process, the types of various sprites constituting one frame determined in the task process (S2204) and parameters necessary for drawing each sprite (display position coordinates, enlargement ratio, rotation angle, translucent value, α blending information , Color information, filter designation information) and the transfer instruction set by the transfer setting process (S2205), to generate a drawing list shown in FIG. 91 (S4601). That is, in the process of S4601, the storage RAM type and the address where the image data of the sprite is stored are specified for each sprite from the types of various sprites constituting one frame determined in the task process (S2204). The parameters necessary for the sprite determined in the task processing are associated with the specified storage RAM type and address. Then, the sprites are rearranged in the order of the sprite to be arranged from the rearmost side to the front side in the image of one frame, and the details of the sprites are arranged in the order of the rearranged sprites. A drawing list is generated by describing the type and address of a storage RAM in which image data of the sprite is stored as detailed drawing information (detailed information) and parameters necessary for drawing the sprite. If a transfer instruction is set by the transfer setting process (S2205), the leading address (storage source top address) of the character ROM 234 where transfer target image data is stored as transfer data information at the end of the drawing list. And the last address (storage source final address) and the start address of the transfer destination (normal video RAM 236).

  As described above, for each sprite, the area of the resident video RAM 235 where the image data of the sprite is stored, or the sub-area of the image storage area 236a of the normal video RAM 236 is fixed, so that the MPU 231 According to the sprite type, the storage RAM type and the address where the image data of the sprite is stored can be immediately specified, and the information can be easily included in the detailed information of the drawing list.

  When the drawing list is generated, the generated drawing list and the drawing target buffer information specified by the drawing target buffer flag 233j are transmitted to the image controller (S4602). Here, when the drawing target buffer flag 233j is 0, the drawing target buffer flag 233j is 1 including information for instructing to develop the image drawn in the first frame buffer 236b as the drawing target buffer information. Includes information instructing to develop an image drawn in the second frame buffer 236c as drawing target buffer information.

  Based on the drawing list received from the MPU 231, the image controller 237 draws images in order from the sprite described at the head of the drawing list, and develops the images by overwriting the frame buffer specified by the drawing target buffer information. Thereby, in the image of one frame generated by the drawing list, the sprite drawn first can be arranged at the rearmost side, and the sprite drawn last can be arranged at the frontmost side.

  When transfer data information is included in the drawing list, the transfer data information is used to determine the start address (storage source start address) and the end address (storage source end address) of the character ROM 234 in which transfer target image data is stored. ) And the head address of the transfer destination (normal video RAM 236) is extracted, and the image data stored from the storage source start address to the storage source end address is sequentially read from the character ROM 234 and temporarily stored in the buffer RAM 237a. After that, when the normal video RAM 236 is in an unused state, the image data stored in the buffer RAM 237a is sequentially transferred to the area indicated by the transfer destination start address of the normal video RAM 236. Then, the image data stored in the normal video RAM 236 is used based on the drawing list transmitted from the MPU 231 thereafter, and the image is drawn according to the drawing list.

  Note that the image controller 237 reads out image information of the previously developed image from a frame buffer different from the frame buffer indicated by the drawing target buffer information, and stores the image information together with the drive signal in the third symbol display device 81. Send to This allows the third symbol display device 81 to display the image developed in the frame buffer. In addition, the image drawn from one frame buffer can be displayed on the third symbol display 81 while the image drawn in one frame buffer is expanded, so that the drawing process and the display process can be performed simultaneously and in parallel. Can be.

  In the drawing process, after the process of S4602, the drawing target buffer flag 233j is updated (S4603). Then, the drawing process ends, and the process returns to the V interrupt process. The drawing target buffer flag 233j is updated by inverting its value, that is, by setting it to “1” when the value is “0” and by setting it to “0” when it is “1”. Done. Thus, the drawing target buffer is alternately set between the first frame buffer 236b and the second frame buffer 236c every time the drawing list is transmitted.

  Here, the transmission of the drawing list is performed by the MPU 231 based on the V interrupt signal transmitted from the image controller 237 every 20 milliseconds when the drawing process and the display process of the image for one frame are completed. It is performed every time the drawing process of the embedding process (see FIG. 112B) is executed. As a result, at a certain timing, the first frame buffer 236b is specified as a frame buffer for developing an image of one frame, and the second frame buffer 236c is specified as a frame buffer from which image information of one frame is read. Is performed, the second frame buffer 236c is designated as a frame buffer for developing the image of one frame 20 ms after the completion of the rendering process of the image of one frame, The first frame buffer 236b is designated as the frame buffer from which the image information of the minute is read. Therefore, the image information of the image previously developed in the first frame buffer 236b can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the second frame buffer 236c. .

  Then, after the next 20 milliseconds, the first frame buffer 236b is designated as a frame buffer for developing an image of one frame, and the second frame buffer 236c is designated as a frame buffer from which image information of one frame is read. Is done. Therefore, the image information of the image previously developed in the second frame buffer 236c can be read and displayed on the third symbol display device 81, and at the same time, a new image is developed in the first frame buffer 236b. . Thereafter, the frame buffer for expanding the image for one frame and the frame buffer from which the image information for one frame is read out are changed to one of the first frame buffer 236b and the second frame buffer 236c every 20 milliseconds. By alternately designating, one frame of image display processing can be continuously performed in units of 20 milliseconds while one frame of image drawing processing is being performed.

  Next, with reference to FIG. 132 (b), details of the above-described counter update processing (S2207), which is one processing of the V interrupt processing executed by the MPU 231 of the display control device 114, will be described. FIG. 132 (b) is a flowchart showing the counter updating process.

  In the counter updating process, first, the display effect counter 233o is updated (S4701). Next, an update process of various counters provided in the display control device 114 is executed (S4702), and this process ends.

<Modification of First Embodiment>
Next, a modification of the first embodiment will be described with reference to FIGS. 133 to 137. In the modification of the first embodiment, a rescue timing is provided during the super-reach B effect period. If the frame button 22 is not pressed during the effect of Super Reach B and this rescue timing has elapsed, a rescue effect is executed. Here, as described above, the super reach B is an effect in which a large hit is notified by pressing the frame button 22 a plurality of times. Therefore, if the period during which the frame button 22 can be input is reduced, there may be cases where the pressing of the frame button 22 cannot be completed in time. However, in the present modified example, when the inputtable period of the frame button 22 is reduced (after the rescue timing has elapsed), the rescue effect is executed, and the press of the frame button 22 necessary for notifying the big hit is performed. The number of times decreases. As a result, the above-described problem can be avoided.

  With reference to FIG. 133, a description will be given of the timing at which the effect of Super Reach B is executed in the present modification. FIG. 133 is a schematic diagram schematically showing the execution timing of the super reach B effect.

  First, referring to FIG. 133 (a), the frame button 22 is not pressed until the first rescue timing and the second rescue timing elapse during the production of the super reach B, and thereafter, the frame button 22 is stopped during the stoppable period. The case where the stop display effect is executed by pressing the button 22 will be described.

  When the reach effect of Super Reach B (reach with the symbol of 7) is started, a screen in which the girl character in the center of the screen holds the symbol of 4 is displayed, as in the first embodiment described above. (See FIG. 77 (a)). In this state, when the frame button 22 is not pressed and the first rescue timing elapses, a rescue effect is executed, and the screen in which the character holds the symbol 5 and the symbol 5 as shown in FIG. Is changed to Similarly, when the frame button 22 is not pressed and the second rescue timing has elapsed, the rescue effect is executed again, and the character is a symbol of 4, a symbol of 5, and a symbol of 6 as shown in FIG. Will be changed to the screen holding the hand.

  In this state, when the frame button 22 is pressed during the stoppable period, an effect of throwing a symbol of 4, a symbol of 5, and a symbol of 6 is executed, and an effect of notifying a big hit is executed. As described above, in the present modification, the remaining number of effective effects required for the notification of the jackpot is reduced every time the rescue timing elapses. Thereby, in the reach effect, even if the player notices the pressing of the frame button 22 late, the number of times the necessary frame button 22 is pressed is reduced, so that the frame button 22 is pressed in time for the jackpot notification. Pressing can be performed.

  In addition, although the depression of the frame button 22 has been executed, the rescue effect is executed in the same manner as described above even when the rescue timing has elapsed without the effective effect. Thus, even if the throwing effect, which is an effective effect, is not displayed even though the frame button 22 is pressed, the effect proceeds at the rescue timing. As a result, it is possible to prevent the effect from proceeding even though the frame button 22 is pressed, and reduce complaints from the player.

  FIG. 133 (b) is a diagram showing the timing when the frame button 22 is pressed before the elapse of each of the above-described rescue timings. If the frame button 22 is pressed before the first rescue timing elapses and an effective effect is executed, the rescue effect is not executed even after the first rescue timing has elapsed, and the same applies to the second rescue timing.

  Next, details of the contents of the data table storage area 233b in the modification of the first control example will be described with reference to FIG. 135. FIG. 135 is a schematic diagram schematically showing the contents of the data table storage area 233b in this modification. The only difference between the data table storage area 233b and the first control example is that various display data tables for rescue display are provided in the fluctuating effect table storage area. Since they are the same, a detailed description thereof will be omitted.

  Each of the display data tables for rescue display stores the display data for rescue effects as shown in FIGS. 134 (a) and 134 (b) described above. The display data for the rescue effect is stored in the data table storage area 223b by the process of S2003 of the boot process (see FIG. 111) of the display control device 114, similarly to other display data tables. Then, in a display super reach B process (see FIG. 137) described later, when a rescue command is received, a rescue display display data table is set in the display data table buffer 233d.

  Next, the super reach B operation process (S1510) executed by the MPU 221 of the audio lamp control device 113 will be described with reference to FIG. FIG. 136 is a flowchart showing the super reach B operation process (S1510). The super reach B operation process (S1510) in the present modified example includes the first control example described above, determination whether the rescue timing has passed (S1830), and a rescue command for display when the rescue timing has passed. The difference is in the part to be set (S1831), and the other processing is the same, so that the detailed description is omitted.

  Specifically, in the process of S1803, if it is determined that the frame button 22 has not been pressed (S1803: No), it is determined whether the rescue timing corresponding to the remaining number of valid presses has elapsed (S1830). ). For example, as shown in FIG. 133 (a), in the case where the effective effect has never been executed (the number of remaining effective presses is three), the case where the first relief timing has elapsed corresponds to the case. In addition, when the first relief timing has elapsed and the relief effect has been performed once (the number of remaining effective pressings is two), the case where the second relief timing has elapsed corresponds to the case.

  In the processing of S1830, if it is determined that the rescue timing has not elapsed, the processing ends. On the other hand, if not, a display rescue command is set based on the elapsed timing (S1831). For example, if the first rescue timing has passed, a command for executing an effect with two symbols is set as shown in FIG. 134 (a), and if the second rescue timing has passed as shown in FIG. ), A command for executing an effect with three symbols is set. The rescue command set here is transmitted to the display control device 114, and the display of the rescue effect is performed by the display super reach B process (see FIG. 137) of the display control device 114 that has received the command. Become.

  Next, the display super reach B process executed by the MPU 231 of the display control device 114 will be described with reference to FIG. FIG. 137 is a flowchart showing the display super reach B process (S2704). The display super reach B process (S2704) in this modified example includes the above-described first control example, determination as to whether there is a rescue command (S2830), and displaying a rescue display display data table when a rescue command is present. The processing (S2831) for setting in the data table buffer 233d is different, and the other processing is the same, so that the detailed description is omitted.

  Specifically, when it is determined that there is no replacement command in the process of S2807 (S2807: No), it is determined whether there is a rescue command (S2830). If it is determined in step S2830 that there is no rescue command, the process ends.

  On the other hand, if it is determined in step S2830 that there is a rescue command, the rescue display data table is set in the display data table buffer 233d, and the process ends.

  As a result, a relief effect is executed based on the elapse of the relief timing. As a result, even if the period during which the frame button 22 can be input is reduced, a case where the pressing of the frame button 22 cannot be pushed in time can be relieved by executing the rescue effect.

  Hereinafter, the concept of various inventions included in the above-described embodiment in addition to the gaming machine of the present invention will be described.

  Effect executing means for executing a predetermined effect based on establishment of a start condition, display means for displaying an effect mode of the predetermined effect executed by the effect executing means, and operating means operable by a player And identification means for identifying a signal output by operating the operation means, and identification means for determining whether a specific condition is satisfied when a specific identification result is identified by the identification means. When the determination means determines that the specific condition is satisfied, the effect mode executed by the effect execution means based on the next established start condition is changed to a specific effect mode until a predetermined condition is satisfied. A gaming machine A1 comprising: an effect variable setting means for setting the variable.

  According to the gaming machine A1, an effect executing means for executing a predetermined effect based on establishment of a start condition, a display means for displaying an effect mode of the predetermined effect executed by the effect executing means, Means that can be operated by a person, identification means for identifying a signal output by operating the operation means, and a specific condition is satisfied when a specific identification result is identified by the identification means. Determination means for determining whether or not a specific condition is satisfied by the determination means. And effect variable setting means for setting the variable to a specific effect mode until the effect is changed. Therefore, when the specific condition is satisfied, the effect mode executed by the effect executing means can be changed to the specific effect mode based on the operation of the player, thereby improving the interest of the player. be able to.

  In the gaming machine A1, a back display means for displaying a back display mode displayed on the back side of the predetermined effect displayed on the display means, and the back display mode is determined based on a result of identification by the identification means. A gaming machine A2, comprising: scroll display means for scrolling display in the direction of. The specific condition is satisfied when a specific back symbol is displayed in the back display mode.

  According to the gaming machine A2, in addition to the effect of the gaming machine A1, the back display means for displaying the back display mode displayed on the back side of the predetermined effect displayed on the display means, and the identification by the identification means. Scroll display means for scrolling the rear display mode in a predetermined direction based on the result, wherein the specific condition is satisfied when a specific rear symbol is displayed in the rear display mode. is there. Therefore, the back display mode can be scroll-displayed based on the operation of the player. As a result, the interest of the player can be improved.

  In the gaming machine A2, the rear display means normally scrolls and displays the rear display mode in a predetermined direction, and when the predetermined identification result is determined by the identification means, A gaming machine A3 wherein the scroll display in the predetermined direction is changed to a scroll display in a direction based on the identification result.

  According to the gaming machine A3, in addition to the effect provided by the gaming machine A2, the back display means normally scrolls and displays the back display mode in a predetermined direction, and displays the identification means. When the predetermined identification result is determined, the scroll display in the predetermined direction is changed to the scroll display in the direction based on the identification result. Therefore, the scroll display is performed in a predetermined direction based on the operation of the player, and the operation may be performed again when the direction of the scroll display is changed. As a result, the burden on the player for executing the scroll display can be reduced.

  In any one of the gaming machines A1 to A3, the operation unit includes a plurality of operation units, and the plurality of operations includes a direction operation unit that instructs a scroll direction of the rear display mode, the specific identification result, A gaming machine A4 comprising at least an identified specific operation unit.

  According to the gaming machine A4, in addition to the effect provided by any one of the gaming machines A1 to A1, the operation means is constituted by a plurality of operation sections, and the plurality of operations instructs a scroll direction of the rear display mode. It comprises at least a direction operation unit and a specific operation unit identified as the specific identification result. Therefore, the scroll direction can be changed by operating the direction operation unit, and the effect can be changed by operating the specific operation unit. As a result, a gaming machine that is easy for the player to understand can be provided.

  Effect executing means for executing an effect of a game, display means for displaying an effect mode executed by the effect executing means, and effect mode selection for selecting an effect mode executed by the effect executing means from a plurality of effect modes A game machine having operating means that can be operated by a player, and operating the operating means each time a predetermined condition is satisfied, as an effect mode selected by the effect mode selecting means. A route effect mode in which the effect mode is changed by the player selecting one route from a plurality of routes is set, and when the route effect mode is executed, the route effect mode is executed in the previously executed route effect mode. A gaming machine B1 having auxiliary means for assisting in selecting a route other than the selected route.

  According to the gaming machine B1, an effect executing means for executing an effect of a game, a display means for displaying an effect mode executed by the effect executing means, and a plurality of effect modes for the effect mode executed by the effect executing means. And a production mode selection means for selecting from the modes, wherein the production mode has an operation means operable by a player, and the production mode selected by the production mode selection means is defined as: A route effect mode in which the effect mode is changed by the player selecting one route from a plurality of routes by operating the operation means is set, and when the route effect mode is executed, the route effect mode is previously executed. Auxiliary means for assisting in selecting a route other than the route selected in the route effect mode. This assists the player to select a route other than the previously selected route when selecting a route in the route effect mode. As a result, the operation load on the player when selecting a route other than the previously selected route can be reduced.

  In the gaming machine B1, a determination unit for performing a determination based on the satisfaction of a determination condition, a dynamic display unit for dynamically displaying identification information indicating determination information by the determination unit on the display unit, When the identification information indicating the specific determination information is displayed, in a gaming machine having privilege game execution means for executing a privilege game that is advantageous to the player, A gaming machine B2 for selecting the route effect mode based on execution of a bonus game by means.

  According to the gaming machine B2, in addition to the effect played by the gaming machine B1, a determining means for executing a determination based on the satisfaction of a determination condition and identification information indicating the determination information by the determining means are dynamically displayed on the display means. In the gaming machine having a dynamic display means and a bonus game execution means for executing a bonus game advantageous to the player when the identification information indicating the specific determination information is displayed on the display means, The effect mode selection means selects the route effect mode based on execution of a bonus game by the bonus game execution means. Therefore, the player can select the route effect mode during execution of the bonus game. As a result, the interest of the player during the execution of the privilege game can be improved.

  The gaming machine B3, wherein in the gaming machine B2, the effect executing means causes the display means to display the route effect mode selected by the effect mode selecting means during execution of the privilege game.

  According to the gaming machine B3, in addition to the effect played by the gaming machine B2, the effect executing means displays the route effect mode selected by the effect mode selecting means on the display means during execution of the privilege game. It is. Therefore, during execution of the bonus game, the route effect mode based on the operation of the player is displayed. As a result, the interest of the player during the execution of the privilege game can be improved.

  In any of the gaming machines B1 to B3, the route effect mode is such that a plurality of set squares are set on the route, and the set squares are set to the set squares by passing the set squares or stopping at the set squares. A gaming machine B4 having a route privilege granting means for granting a privilege that has been set.

  According to the gaming machine B4, in addition to the effects played by the gaming machines B1 to B3, in the route effect mode, a plurality of set squares are set on the route, and the set squares pass or stop at the set squares. Thus, a route privilege granting means for granting the privilege set in the set cell is provided. Therefore, when the route effect mode is displayed, it is possible to make the player expect that the privilege is given. As a result, the interest of the player can be improved.

  In the gaming machine B4, the route privilege granting means sets a privilege to be assisted by the assisting means so that the route privilege granting means can be started from the start of the next privilege game from the set cell passed or stopped as the privilege. A gaming machine B5, characterized in that:

  According to the gaming machine B5, in addition to the effect played by the gaming machine B4, the route privilege providing means can be started from the start of the next privilege game from the set cell passed or stopped as the privilege. The privilege to be assisted by the assisting means is set. Therefore, at the start of the next privilege game, the player can start from the set cell that has passed or stopped in the previous privilege game. As a result, it is possible to give the player an impression as if it were an effect continued from the previous privilege game, and it is possible to improve the interest of the player.

  Lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display means capable of dynamically displaying the identification information; And a bonus granting means for granting a privilege advantageous to a player when the lottery result by the lottery means is displayed with the identification information indicating that the lottery result is a specific lottery result. The information is configured by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained, and the dynamic display means And displaying a reach display mode in which one of the plurality of symbol rows is displayed in a state where one symbol row is dynamically displayed, and sets and displays a plurality of specific symbols as a combination indicating the specific lottery result. Also And a symbol changing means for changing the specific symbol of the symbol row dynamically displayed in the reach display mode to a specific display mode, and a specific variable changed by the symbol variable section based on establishment of a predetermined condition. A gaming machine C1 comprising: re-variable means for varying a symbol to an original display mode.

  According to the gaming machine C1, lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display of the identification information can be provided. Possible dynamic display means, and privilege providing means for providing a benefit advantageous to the player when the lottery result by the lottery means is displayed with the identification information indicating a specific lottery result. In the gaming machine, the identification information is constituted by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained. , The dynamic display means displays a reach display mode in which one of the plurality of symbol rows is displayed in a dynamically displayed state, and a specific symbol which is a combination indicating the specific lottery result Duplicate A symbol changing means for changing the specific symbol of the symbol row dynamically displayed in the reach display mode to a specific display mode, and changing the symbol based on establishment of a predetermined condition. Re-variable means for varying the specific symbol changed by the means to the original display mode. Therefore, even when there are a plurality of specific symbols that result in a specific lottery during the display of the reach display mode, the specific symbols are changed to the specific display mode by the symbol variable unit. Here, the specific symbol changed to the specific display mode is changed to the original display mode by the re-variable unit. As a result, during the display of the reach display mode in which there are a plurality of specific symbols serving as specific lottery results, the player need only pay attention to the specific display mode. Therefore, it is possible to provide a gaming machine that is easy for the player to understand.

  In the gaming machine C1, the player has operation means that can be operated by the player, and the dynamic display means dynamically displays the specific symbol changed by the symbol variable means and the symbols other than the specific symbol in the reach display mode. And a stop display means for stopping the dynamic display of the symbol row dynamically displayed in the reach display mode based on the operation of the operation means. Gaming machine C2.

  According to the gaming machine C2, in addition to the effect played by the gaming machine C1, the game machine C2 has operating means operable by the player, and the dynamic display means is configured to be the specific display variable by the symbol variable means in the reach display mode. A dynamic display of a symbol and a symbol other than the specific symbol is performed, and based on the operation of the operation means, the dynamic display of the symbol row dynamically displayed in the reach display mode is stopped and displayed. It has stop display means. Therefore, even when there are a plurality of specific symbols that result in a specific lottery during the display of the reach display mode, the specific symbols are changed to the specific display mode by the symbol variable unit. As a result, the player may perform an operation while paying attention to the changed specific display mode. Therefore, it is possible to provide a gaming machine that is easy for the player to understand.

  In the gaming machine C2, when the lottery result by the lottery means is a specific lottery result, the stop display means displays one of the specific symbols in the reach display mode at a timing when the operation means is operated. The gaming machine C3, wherein the stop display is performed so that the stop display is performed at a position where the display can be performed in combination with the symbol that is stopped and displayed in the above.

  According to the gaming machine C3, in addition to the effect of the gaming machine C2, when the lottery result by the lottery means is a specific lottery result, the stop display means sets the timing at which the operation means is operated. The stop display is performed so that one of the specific symbols is displayed at a position where it can be displayed in combination with the symbol that is stopped and displayed in the reach display mode. Therefore, the symbols which are stopped and displayed based on the operation of the player and which have been re-changed to the original display mode by the re-change means are displayed in combination with the symbols stopped in the reach display mode. As a result, the player can easily recognize whether or not the stopped and displayed symbol is a specific lottery result. Therefore, it is possible to provide a gaming machine that is easy for the player to understand.

  In the gaming machines C1 to C3, the reach display mode is configured to be a display mode in which two or more symbol columns are stopped and displayed with the same symbol and one symbol column is dynamically displayed. Gaming machine C4.

  According to the gaming machine C4, in addition to the effect provided by any one of the gaming machines C1 to C3, the reach display mode causes two or more symbol columns to be stopped and displayed with the same symbol, and one symbol column to be dynamically displayed. It is configured in a display mode. Therefore, the interest of the player can be improved.

  In any one of the gaming machines C1 to C4, the symbol changing means is configured to change and display the plurality of specific symbols in the specific display mode, which is the same display mode, and display the symbols. .

  According to the gaming machine C5, in addition to the effect provided by any of the gaming machines C1 to C4, the symbol variable means causes the plurality of specific symbols to be changed and displayed in the specific display mode that is the same display mode. Things. Therefore, even when there are a plurality of specific symbols that result in a specific lottery during the display of the reach display mode, the specific symbols are changed to the same specific display mode by the symbol variable unit. As a result, the player only needs to pay attention to one specific display mode during the display of the reach display mode in which there are a plurality of specific symbols serving as specific lottery results. Therefore, it is possible to provide a gaming machine that is easy for the player to understand.

  Lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display means capable of dynamically displaying the identification information; And a bonus granting means for granting a privilege advantageous to a player when the lottery result by the lottery means is displayed with the identification information indicating that the lottery result is a specific lottery result. The information is configured by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained, and the dynamic display means Displaying the one symbol row of the plurality of symbol rows in a dynamically displayed state in a reach display mode, and setting and displaying a specific symbol which is a combination indicating the specific lottery result. so Operating means that can be operated by a player, and the dynamic display is performed based on the operation of the operating means when the identification information is displayed in the reach display mode by the dynamic display means. Symbol varying means for varying the symbol of the symbol row being displayed, determining means for determining the remaining period of the period displayed in the reach display mode, and within the period determined by the determining means, the symbols are changed by the symbol varying means. The symbol variable determining means for determining whether or not the specific symbol can be changed, and when the symbol variable determining means determines that the specific symbol cannot be changed, the specific symbol is displayed in the remaining period of the reach display mode. A gaming machine D1 comprising: a special effect setting means for setting a specific effect to be displayed.

  According to the gaming machine D1, the lottery means for executing the lottery based on the establishment of the lottery condition, the display means for displaying the identification information indicating the lottery result by the lottery means, and the identification information can be dynamically displayed. Possible dynamic display means, and privilege providing means for providing a benefit advantageous to the player when the lottery result by the lottery means is displayed with the identification information indicating a specific lottery result. In the gaming machine, the identification information is constituted by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained. The dynamic display means displays a specific symbol row in a state of dynamically displaying one of the plurality of symbol rows in a reach display mode, so that the specific symbol is a combination indicating the specific lottery result. Set Operating means that can be operated by a player; and that the operating means is operated when the identification information is displayed in the reach display mode by the dynamic display means. A symbol varying means for varying the symbol of the symbol row dynamically displayed, a determining means for determining the remaining period of the period displayed in the reach display mode, and Symbol variable determining means for determining whether the symbol can be changed to the specific symbol by the symbol variable means, and when the symbol variable determining means determines that the specific symbol cannot be changed, the remaining period of the reach display mode And a specific effect setting means for setting a specific effect for displaying the specific symbol. Therefore, during execution of the reach display, the symbol can be changed to the specific symbol based on the operation of the player. Here, when the symbol cannot be changed based on the operation of the player during the remaining time of the reach display being executed, a specific effect for displaying the specific symbol is set. Thereby, even when there is no or little operation by the player, a specific symbol that is a combination indicating a specific lottery result can be set and displayed. As a result, in the execution of the reach display, even when there is no or little operation by the player, a specific symbol can be displayed to indicate that a specific lottery result has been obtained.

  In the gaming machine D1, in the specific effect, after the symbol row dynamically displayed in the reach display mode is stopped and displayed with a symbol different from the specific symbol, the stopped symbol is replaced with the specific symbol. A gaming machine D2 comprising an effect to be displayed.

  According to the gaming machine D2, in addition to the effect played by the gaming machine D1, the specific effect is to stop and display the symbol row dynamically displayed in the reach display mode with a symbol different from the specific symbol, This is an effect of replacing the stopped and displayed symbol with a specific symbol and displaying it. Therefore, when the symbol cannot be changed based on the operation of the player because there is no or little operation by the player, first, the symbol is stopped and displayed with a symbol different from the specific symbol. After that, the stopped and displayed symbol is replaced with a specific symbol. Thereby, even when there is no or little operation by the player, it is possible to execute an effect with less discomfort.

  In the gaming machine D1 or D2, when the lottery result by the lottery means is different from the specific lottery result, the symbol of the symbol row dynamically displayed in the reach display mode is specified regardless of the operation of the operation means. A gaming machine D3 having a prohibiting means for prohibiting changing to a symbol.

  According to the gaming machine D3, in addition to the effect played by the gaming machine D1 or D2, when the lottery result by the lottery means is different from the specific lottery result, the symbol of the symbol row dynamically displayed in the reach display mode is displayed. A prohibition unit for prohibiting changing to the specific symbol regardless of an operation of the operation unit. Therefore, it is possible to prevent a specific symbol indicating a specific lottery result from being displayed even though the lottery result is not the specific lottery result.

  Lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display means capable of dynamically displaying the identification information; And a bonus granting means for granting a privilege advantageous to a player when the lottery result by the lottery means is displayed with the identification information indicating that the lottery result is a specific lottery result. The information is configured by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained, and the dynamic display means Displaying the one symbol row of the plurality of symbol rows in a dynamically displayed state in a reach display mode, and setting and displaying a specific symbol which is a combination indicating the specific lottery result. so Operating means that can be operated by a player, and the dynamic display is performed based on the operation of the operating means when the identification information is displayed in the reach display mode by the dynamic display means. Symbol changing means for changing the symbol of the symbol row to a different symbol in a predetermined order, a determining means for determining the remaining period of the period displayed in the reach display mode, and a period determined by the determining means, A symbol variable determining unit that determines whether the symbol can be changed to the specific symbol by the symbol variable unit; and if the symbol variable determining unit determines that the symbol cannot be changed to the specific symbol, the symbol is determined in the remaining period. A gaming machine D4 having special symbol changing means for changing the symbol in an order in which the symbol can be changed.

  According to the gaming machine D4, lottery means for executing a lottery based on the establishment of the lottery condition, display means for displaying identification information indicating a lottery result by the lottery means, and dynamic display of the identification information can be provided. Possible dynamic display means, and privilege providing means for providing a benefit advantageous to the player when the lottery result by the lottery means is displayed with the identification information indicating a specific lottery result. In the gaming machine, the identification information is constituted by a plurality of symbol rows and is displayed in a combination of specific symbols, so that the lottery result by the lottery means is set to indicate that the specific lottery result is obtained. , The dynamic display means displays a specific symbol row of the plurality of symbol rows in a dynamically displayed state in a reach display mode, and displays a specific symbol indicating a specific lottery result. Set Operating means that can be operated by a player; and that the operating means is operated when the identification information is displayed in the reach display mode by the dynamic display means. A symbol changing means for changing the symbols of the dynamically displayed symbol row to different symbols in a predetermined order, a discriminating means for discriminating a remaining period of a period displayed in a reach display mode, and discriminating by the discriminating means. Within the period to be performed, a symbol variable determining means for determining whether the symbol can be changed to the specific symbol by the symbol variable means, when it is determined that the specific symbol is not variable by the symbol variable determining means, Special symbol changing means for changing the symbol in an order that can be changed to the specific symbol in the remaining period. Therefore, during execution of the reach display, the symbol can be changed to the specific symbol based on the operation of the player. Here, if the symbol cannot be changed based on the operation of the player during the remaining time of the reach display being executed, the symbols are changed in the order in which the symbols can be changed to the specific symbols during the remaining period. Thereby, even if the start of the operation by the player is delayed, the symbol can be changed to the specific symbol based on the operation of the player.

  In the gaming machine D4, the special symbol changing means is configured to change and display the symbols in an order in which symbols to be changed in a plurality of orders among the predetermined order changed by the symbol changing means are combined. A gaming machine D5.

  According to the gaming machine D5, in addition to the effect played by the gaming machine D4, the special symbol variable unit combines symbols to be changed in a plurality of orders among the predetermined order changed by the symbol variable unit. The symbols are variably displayed in order. Therefore, even if the start of the operation by the player is delayed, the player can easily recognize that the symbol can be changed to the specific symbol based on the operation of the player.

  In addition, as a member protruded from the board surface, a nail, a windmill, a through gate, and the like are exemplified.

  In any one of the gaming machines A1 to A5, B1 to B6, C1 to C6, D1 to D8, and E1 to E15, the gaming machine is a slot machine. Above all, the basic configuration of the slot machine is as follows: "variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information is provided. The dynamic display of the identification information is started, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (stop button) or after a predetermined time elapses. And a special game state generating means for generating a special game state advantageous to the player on condition that the confirmed identification information is the specific identification information. In this case, coins and medals are typical examples of the game medium.

  In any of the gaming machines A1 to A5, B1 to B6, C1 to C6, D1 to D8, and E1 to E15, the gaming machine F2 is a pachinko gaming machine. Among them, as a basic configuration of a pachinko gaming machine, an operation handle is provided, and a ball is fired to a predetermined game area in accordance with the operation of the operation handle, and the ball is provided in an operation port arranged at a predetermined position in the game area. The requirement for winning (or passing through the operating port) is that the identification information dynamically displayed on the display means is fixedly stopped after a predetermined time. In addition, when a special game state occurs, a variable winning device (specific winning opening) disposed at a predetermined position in the game area is opened in a predetermined mode so that balls can be won, and a value corresponding to the winning number is obtained. A value (including data written on a magnetic card as well as a prize ball) is given.

In any of the gaming machines A1 to A5, B1 to B6, C1 to C6, D1 to D8, and E1 to E15, the gaming machine is a combination of a pachinko gaming machine and a slot machine. Machine F3. Among them, the basic configuration of the integrated gaming machine is as follows: "variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information, and starting operation means (for example, an operation lever) The change of the identification information is started due to the operation of, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (for example, the stop button) or after a predetermined time elapses. A special game state generating means for generating a special game state advantageous to the player on condition that the fixed identification information at the time of stop is specific identification information, and using a ball as a game medium, , A predetermined number of balls are required at the start of the dynamic display, and a large number of balls are paid out when a special game state occurs.
<Others>
In a gaming machine such as a pachinko machine, there is a gaming machine that prevents the effect display during a jackpot from being monotonous by diversifying the effect pattern in a round effect of a jackpot (for example, Patent Document 1: JP 2007-2007 -117660 gazette).
However, the above-described conventional gaming machine has a problem that there is room for improvement in a method of preventing the effect display during the big hit from becoming monotonous.
The present technical idea has been made in order to solve the above-described problems, and has as its object to provide a gaming machine capable of improving a method of preventing the effect display from becoming monotonous during a big hit.
<Means>
In order to achieve this object, the gaming machine of the technical idea 1 comprises: an effect executing means for executing an effect of a game; a display means for displaying an effect mode executed by the effect executing means; A staging mode selecting means for selecting a staging mode to be executed from a plurality of staging modes, wherein the staging mode selected by the staging mode selecting means has an operating means operable by a player. Each time a predetermined condition is satisfied, a route effect mode in which the effect mode is changed by the player selecting one route from a plurality of routes by operating the operation means is set, and the route effect mode is set. Is executed, there is an auxiliary means for assisting in selecting a route other than the route selected in the previously performed route effect mode.
<Effect>
According to the gaming machine described in the technical idea 1, it is possible to improve the method of preventing the effect display during the big hit from becoming monotonous.

10 pachinko machines (game machines)
22 frame button (operation means )
81 3rd symbol display device (display means)
S105 lottery means
114 display control device (dynamic display means)
S904 privilege granting means
S1813 determination means
S2803, S2804 symbol display means
S1814, S2808 Specific effect setting means

Claims (1)

Effect execution means for executing an effect of a game,
Display means for displaying an effect mode executed by the effect execution means;
In a gaming machine having an effect mode selecting means for selecting an effect mode executed by the effect executing means from a plurality of effect modes,
Having operation means operable by the player,
As an effect mode selected by the effect mode selecting means, a route in which the effect mode is changed by the player selecting one route from a plurality of routes by operating the operation means each time a predetermined condition is satisfied. The production mode is set,
A gaming machine having assisting means for assisting in selecting a route other than the route selected in the previously executed route effect mode when the route effect mode is executed. .

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