JP2019154500A - Game machine - Google Patents

Abstract

To provide a game machine capable of suppressing current consumption.SOLUTION: A pachinko game machine PY1 includes a performance control microcomputer 121 capable of controlling a performance, a frame lamp 212 and a board lamp 54 that can emit light, and a central movable body 401 that can be moved to a lowered position and a lifted position. When it is determined that a peak current of a power source of a performance motor is smaller than 3000 mA on the basis of a current restriction determination table, the performance control microcomputer 121 supplies a predetermined normal current (a current based on frame lamp data and a current based on board lamp data) to the frame lamp 212 and the board lamp 54 to cause the frame lamp 212 and the board lamp 54 to emit light. In the meanwhile, when it is determined that the peak current of the power source of the performance motor is 3000 mA or greater, and the central movable body 401 is moved to the lowered position, the performance control microcomputer does not supply a current to the frame lamp 212 or the board lamp 54 so as not to cause the frame lamp 212 or the board lamp 54 to emit light.SELECTED DRAWING: Figure 19

Description

  The present invention relates to a gaming machine such as a pachinko gaming machine or a revolving type gaming machine (pachislot gaming machine).

  Conventionally, a pachinko gaming machine which is one of gaming machines is provided with various driving means as described in Patent Document 1 below, for example. The drive of these drive means is controlled by the effect control means (effect control microcomputer). Examples of the driving means include a movable movable body and a light emitting means capable of emitting light, and these driving means are driven by supplying a current. Thus, for example, when notifying the winning of the big hit, the effect control means controls the drive means to be supplied with current and drives the drive means. Thereby, it is possible to enhance the interest of the effect given to the player.

JP 2003-290453 A

  By the way, in recent gaming machines, a very large number of driving means are provided, and the total value of currents required to drive each driving means is very large. That is, if many driving means are driven at the same time, there is a fear that the current is insufficient. Therefore, it is desired to reduce current consumption for the entire gaming machine.

  The present invention has been made in view of the above circumstances. In other words, the problem is to provide a gaming machine capable of suppressing current consumption.

The gaming machine of the present invention is
In a gaming machine that controls to a special gaming state advantageous to a player based on establishment of a predetermined control condition,
Production control means capable of controlling production;
Drivable first driving means;
Second driving means movable to a predetermined origin position or operation position,
The production control means includes
The first driving means can be driven by supplying a predetermined normal current to the first driving means,
When the second drive means moves to the origin position, the first drive means is driven by supplying a small current smaller than the normal current to the first drive means, or the first drive means The gaming machine is characterized in that the first driving means can be prevented from being driven by supplying no current.

  According to the gaming machine of the present invention, current consumption can be suppressed.

1 is a perspective view of a gaming machine according to an embodiment of the present invention. It is a disassembled perspective view of the gaming machine frame provided in the gaming machine. It is a front view of the gaming machine. It is a right view of the gaming machine. It is a front view of the game board with which the gaming machine is provided. It is a figure which shows the mechanism board which attaches a character movable body and a ball movable body so that a movement is possible. FIG. 6 is an enlarged view of a portion A shown in FIG. 5, and is a diagram showing display devices provided in the gaming machine. It is a perspective view which shows the relationship between the upper side decoration unit with which the game machine is provided, and a base frame. It is a front view when the center upper unit with which the game machine is located in a raise position. (A) is a right side view when the central upper unit is in the lowered position, and (B) is a right side view when the central upper unit is in the raised position. (A) is a figure which shows the drive mechanism of the raising / lowering unit when a center upper unit exists in a lowered position, (B) is a figure which shows the drive mechanism of the raising / lowering unit when a center upper unit exists in a raise position. It is a front view when the left side movable body with which the game machine is equipped, and the right side movable body are in an open position. It is a figure which shows the drive mechanism of a left movable body. It is a block diagram which shows the electrical structure by the side of the game control board of the same gaming machine. It is a block diagram which shows the electrical structure by the side of the production control board of the same gaming machine. It is a block diagram which shows the electrical structure by the side of the subdrive board | substrate of the same gaming machine. It is a figure for demonstrating a bipolar type stepping motor. It is a figure for demonstrating two-phase excitation. It is a current limiting judgment table. It is a hit type determination table. It is a table | surface which shows the various random numbers which the microcomputer for game control acquires. (A) is a jackpot determination table, (B) is a reach determination table, (C) is an ordinary symbol determination table, and (D) is an ordinary symbol variation pattern selection table. It is a special figure fluctuation pattern determination table. It is an open pattern determination table of electric Chu. It is a flowchart of a main side timer interruption process. It is a flowchart of a sub-side 1 ms timer interrupt process. It is a flowchart of a drive control process. It is a flowchart of a central movable body drive control process. It is a flowchart of a central movable body drive control process. It is a flowchart of a left movable body drive control process. It is a flowchart of a left movable body drive control process. It is a flowchart of a right movable body drive control process. It is a flowchart of a right movable body drive control process. It is a flowchart of a character movable body drive control process. It is a flowchart of a character movable body drive control process. It is a flowchart of a ball movable body drive control process. It is a flowchart of a ball movable body drive control process. It is a flowchart of a lamp data output process. It is a flowchart of a lamp data output process. It is a flowchart of a sub-side 10 ms timer interruption process. It is a flowchart of a received command analysis process. It is a flowchart of a change production start process. It is a flowchart of a change start forced return determination process.

1. Structure of gaming machine A pachinko gaming machine according to an embodiment of the present invention will be described with reference to the drawings. In the following description, the left-right direction of each part of a pachinko gaming machine as an example of a gaming machine will be described in accordance with the left-right direction for a player facing the pachinko gaming machine. In addition, the front direction of each part of the pachinko gaming machine will be described as a direction approaching a player facing the pachinko gaming machine, and the backward direction of each part of the pachinko gaming machine will be described as a direction away from the player facing the pachinko gaming machine.

  As shown in FIG. 1, the pachinko gaming machine PY1 according to the embodiment includes a gaming machine frame 2 that constitutes an outline of the pachinko gaming machine PY1. As shown in FIG. 2, the gaming machine frame 2 includes an outer frame 22, an inner frame 21, and a front door (front frame) 23. The outer frame 22 is a vertical rectangular frame that forms the outer portion of the pachinko gaming machine PY1. The inner frame 21 is a vertical rectangular frame that is disposed inside the outer frame 22 and attaches a game board 1 described later. The front door 23 is disposed on the front side of the outer frame 22 and the inner frame 21 and has a vertical rectangular shape that protects the game board 1. The front door 23 is a part directly facing the player and is decorated in various ways.

  The gaming machine frame 2 includes a hinge portion 24 on the left end side. By this hinge portion 24, the front door 23 is rotatable with respect to the outer frame 22 and the inner frame 21, and the inner frame 21 is rotatable with respect to the outer frame 22 and the front door 23, respectively. It has become. An opening 23a is formed at the center of the front door 23, and a transparent transparent plate 23t is attached to the opening 23a so that a player can visually recognize a game area 6 described later. Of the transparent plate 23t attached to the opening 23a, a portion located inside the opening 23a is referred to as a window 23m (see FIG. 1). The transparent plate 23t is a glass plate in this embodiment, but may be a transparent synthetic resin plate. That is, the transparent plate 23t only needs to be able to visually recognize the game area 6 from the front.

  As shown in FIGS. 1, 3, and 4, the front door 23 includes an upper decoration unit 200, a left decoration unit 210, a right decoration unit 220, and an operation mechanism unit 230. Each of these units is attached to the front side of the base frame 23w (see FIG. 2) of the front door 23.

  The operation mechanism unit 230 is disposed below the front door 23. The operation mechanism unit 230 includes a handle 72k (launch operation unit) for launching a game ball with a launch intensity corresponding to the rotation angle at the lower right. The upper portion 38 of the operation mechanism unit 230 is provided with an upper plate 34 for storing game balls (rented balls and prize balls). An input section (effect button) 40k and a select button (cross key) 42k that can be operated are provided. Further, a deployment release button 44k is provided on the right side of the input unit 40k in the upper part 38 of the operation mechanism unit 230. The function of the unfolding button 44k will be described later. A lower plate 35 for storing game balls that cannot be accommodated in the upper plate 34 is provided below the operation mechanism unit 230.

  Further, a lower left decorative portion 231 is provided on the left front portion of the upper portion 38 of the operation mechanism unit 230. The lower left decorative portion 231 is made of a translucent synthetic resin member, and transmits light emitted from a frame lamp 212 described later. Further, a lower right decorative portion 233 is provided in front of the upper side portion 38 of the operation mechanism unit 230. The lower right decorative portion 233 is made of a light-transmitting synthetic resin member and transmits light emitted from a frame lamp 212 described later.

  The left decoration unit 210 is arranged on the left side of the window portion 23 m in the front door 23. The left decorative unit 210 includes a left middle decorative portion 211 made of a translucent synthetic resin member, and a frame lamp 212 that allows light to enter the left middle decorative portion 211 from the rear. The left middle decoration part 211 decorates the left side of the window part 23m in the front door 23 along the vertical direction. Note that an escape portion 219 (a portion that does not protrude forward from the left middle decorative portion 211) is provided in the lower portion of the left decorative unit 210. The escape portion 219 is for securing a space for arranging a device (a device commonly referred to as an “elephant nose”) installed in the hall for supplying a game ball to the upper plate 34.

  The right decoration unit 220 is arranged on the right side of the window portion 23 m in the front door 23. The right decoration unit 220 includes a right middle decoration part 221 made of a translucent synthetic resin member, and a frame lamp 212 that allows light to enter the right middle decoration part 221 from behind. The right middle decorative portion 221 decorates the right side of the window portion 23m in the front door 23 along the vertical direction.

  The upper decoration unit 200 is disposed on the upper side of the front door 23, and protrudes forward from the left decoration unit 210, the right decoration unit 220, and the operation mechanism unit 230 (see FIG. 4). The upper decoration unit 200 includes a central upper unit 400 disposed in the center in the left-right direction, a left upper unit 500 disposed on the left side of the central upper unit 400, and an upper right unit disposed on the right side of the central upper unit 400. 550.

  An upper left decorative part 525 made of a translucent synthetic resin member is provided in a front portion of the upper left unit 500, and a frame lamp 212 for allowing light to enter the upper left decorative part 525 from behind is provided. In addition, an upper right decorative portion 575 made of a translucent synthetic resin member is provided in a front portion of the upper right portion unit 550, and a frame lamp 212 that allows light to enter the upper right decorative portion 575 from behind is provided. .

  When various frame lamps 212 (specific drive means) emit light, the upper and lower lines from the upper right to the lower right of the front door 23 (specifically, the center in the vertical direction is curved so that it is located behind the upper and lower ends. And the upper and lower lines (except for the escape portion 219) from the upper left to the lower left of the front door 23 are emphasized to emit light. In addition, you may comprise so that each decoration part of the left side may be connected in a shape, without providing the escape part 219. FIG.

  A gaming board 1 shown in FIG. 5 is attached to the gaming machine frame 2. As shown in FIG. 5, the game board 1 is formed with a game area 6 in which game balls launched by the operation of the handle 72 k flow down are surrounded by rail members 62. The game board 1 is provided with a number of board lamps 54 (specific drive means) described later. In the game area 6, a plurality of game nails for guiding a game ball are provided. The game board 1 includes a plate-like member that forms the game area 6 on the front side, and a back unit in which various control boards, an image display device 50 described later, and the like are unitized behind the plate-like member. Configured.

  Further, an image display device 50 (effect display means) which is a liquid crystal display device is provided near the center of the game area 6. The image display device may be another image display device such as an organic EL display device. The display screen 50a (display unit) of the image display device 50 has an effect symbol display area for performing variable display of an effect symbol EZ (decorative symbol) synchronized with variable display of a first special symbol and a second special symbol which will be described later. . Note that the effect of displaying the effect symbol EZ is referred to as an effect symbol variation effect. The effect design variation effect may be referred to as “decoration design variation effect” or simply “change effect”.

  The effect symbol display area includes, for example, three effect symbol display areas of “left”, “middle”, and “right”. The left effect symbol display area displays the left effect symbol EZ1, the middle effect symbol display area displays the middle effect symbol EZ2, and the right effect symbol display area displays the right effect symbol EZ3. Each of the effect symbols EZ is composed of a plurality of symbols representing numbers “1” to “8”, for example. The image display device 50 includes a first special symbol display 81a and a second special symbol display 81b, which will be described later, by a combination of the left effect symbol EZ1, the middle effect symbol EZ2, and the right effect symbol EZ3. And the result of variable display of the second special symbol (that is, the result of the big hit lottery) is displayed in an easy-to-understand manner.

  For example, when winning a jackpot, the effect symbol is stopped and displayed with a doublet such as “777”. Further, if it is out of place, the effect symbol is stopped and displayed with a variation such as “637”. This makes it easier for the player to grasp the progress of the game. That is, the player generally grasps the result of the jackpot lottery by the image display device 50, not by the first special figure display 81a or the second special figure display 81b. In addition, the position of the effect symbol display area may not be fixed. In addition, as a variation display mode of the effect design, for example, there is a mode of scrolling in the vertical direction.

  The image display device 50 displays, in addition to the effect symbol variation effect using the effect symbol EZ as described above, a jackpot effect performed in parallel with the jackpot game, a demonstration effect for customer waiting (customer wait effect), and the like. 50a is displayed. In the effect design variation effect, effect images other than the effect design EZ such as background images and character images are displayed in addition to the effect design EZ such as numbers.

  The display screen 50a of the image display device 50 has a hold icon display area for displaying a hold icon HA (production hold image) according to the number of first special figure hold and second special figure hold described later. By displaying the hold icon HA, the stored number of first special figure hold displayed on the first special figure hold indicator 83a described later or the second special figure displayed on the second special figure hold indicator 83b described later. The number of stored figure can be shown to the player in an easy-to-understand manner.

  A center frame (inner wall portion) 61 is disposed near the center of the game area 6 and in front of the image display device 50. A stage 61s is formed at the lower part of the center frame 61. The stage 61s can guide a game ball rolling on the upper surface to a first starting port 11 described later. A warp 61w is provided at the left of the center frame 61. The warp 61w allows a game ball to flow in from the entrance and flow out from the exit to the stage 61s.

  A character movable body 55k that is movable in the vertical direction is provided on the upper portion of the center frame 61. The character movable body 55k is an effect movable body that imitates the character of this pachinko gaming machine PY1, and overlaps with a standby position (see FIG. 5) located above the display screen 50a and the center of the display screen 50a in the front-rear direction. It can move between driving positions (see the two-dot chain line in FIG. 6). A movable ball body 56k that can move in the left-right direction and the up-down direction is provided at the lower right portion of the center frame 61. The ball movable body 56k is an effect movable body that imitates a soccer ball, and can move leftward and upward from a retreat position (see FIG. 5) that is not visible to the player at the lower right of the display screen 50a. (See the two-dot chain line in FIG. 6). An arbitrary position where the ball movable body 56k moves from the retracted position and is visible to the player will be referred to as an “exposed position”.

  Here, FIG. 6 is a view showing a mechanism plate 1A for movably attaching the character movable body 55k and the ball movable body 56k. The mechanism plate 1A is visible when a plate-like member disposed on the front side of the game board 1 is removed, and is disposed on the front side of the image display device 50 in the back unit. As shown in FIG. 6, the mechanism plate 1 </ b> A includes a vertical movement mechanism 51 and an XY movement mechanism 52.

  The vertical movement mechanism 51 is a mechanism for allowing the character movable body 55k to move in the vertical direction. The vertical movement mechanism 51 includes a holder 53 that holds the movable character body 55k, a left drive shaft 57L that supports the left side of the holder 53 so as to be movable in the vertical direction, and a right side that supports the right side of the holder 53 so as to be movable in the vertical direction. A drive shaft 57R, and a character moving motor 58 that can rotate the left drive shaft 57L and the right drive shaft 57R are provided. The character moving motor 58 is provided on each of the left and right sides and the lower side of the mechanism plate 1A, and moves the left and right sides of the holder 53 in the vertical direction by rotating the left drive shaft 57L and the right drive shaft 57R, respectively. It is something to be made.

  Thus, in the vertical movement mechanism 51, when each character moving motor 58 is driven from the state shown in FIG. 6, the holder 53 is moved downward, and the character movable body 55k is moved from the standby position to the driving position indicated by the two-dot chain line in FIG. It is possible to move to. Thereafter, when the character moving motor 58 is driven in the opposite direction, the holder 53 is moved upward, and the character movable body 55k can be moved (returned) from the driving position indicated by the two-dot chain line in FIG. .

  The XY moving mechanism 52 is a mechanism that enables the ball movable body 56k to move in the vertical direction and the horizontal direction. The XY movement mechanism 52 includes a rack and pinion mechanism 91 that allows the ball movable body 56k to move (slide) in the left-right direction, and a ball left-right movement motor 92 that is attached to the ball movable body 56k. In the rack and pinion mechanism 91, a rack 91 a that extends in the left-right direction meshes with a pinion (not shown) that is attached to the rotation shaft of the ball left-right movement motor 92. Therefore, when the ball left / right movement motor 92 is driven, the ball movable body 56k is movable in the left / right direction along the rack 91a.

  The XY movement mechanism 52 includes a left rotation shaft 93L that supports the left side of the rack and pinion mechanism 91 so as to be movable in the vertical direction, a right rotation shaft 93R that supports the right side of the rack and pinion mechanism 91 so as to be movable in the vertical direction, and a left side. A ball up-and-down movement motor 94 is provided that enables the rotation shaft 93L and the right rotation shaft 93R to rotate. The ball vertical movement motor 94 is provided at the lower left portion of the mechanism plate 1A, is connected to the left rotation shaft 93L, and rotates to the right via a rotation linkage mechanism 95 provided below the mechanism plate 1A. It is connected to the shaft 93R. Therefore, the ball vertical movement motor 94 can move the rack and pinion mechanism 91 and the ball movable body 56k integrally in the vertical direction by rotating the left rotation shaft 93L and the right rotation shaft 93R, respectively.

  In this way, in the vertical movement mechanism 51, when the ball horizontal movement motor 92 is driven from the state shown in FIG. 6 and the ball vertical movement motor 94 is driven, the ball movable body 56k is shown by, for example, a two-dot chain line in FIG. It can be moved to the exposure position. Thereafter, the ball movable body 56k can move (return) to the retracted position when each of the ball left / right movement motors 92 and the ball vertical movement motor 94 is driven in the opposite direction. In this embodiment, by adjusting the driving force of each ball left / right moving motor 92 and the driving force of the ball up / down moving motor 94, the ball movable body 56k can be moved in various ways other than the exposed position indicated by the two-dot chain line in FIG. It is possible to move to a position (exposure position). Further, the ball movable body 56k can move only in one of the vertical direction and the horizontal direction if only one of the ball horizontal movement motor 92 or the ball vertical movement motor 94 is driven.

  Returning to the description of FIG. As shown in FIG. 5, below the image display device 50 in the game area 6, there is provided a first start winning device 11 </ b> D having a first start port 11 where the ease of entering a game ball does not always change. . The first start port 11 is also referred to as a first entrance port, a fixed entrance port, a first start winning port, and a first start area. The first start winning device 11D is also referred to as a first winning means, a fixed winning means, or a first starting winning device. The winning of the game ball to the first starting port 11 is an opportunity for the lottery of the first special symbol (the jackpot lottery, that is, the determination that the jackpot random number is acquired).

  The electric chew 12D includes an electric chew opening / closing member 12k (entrance opening / closing member) that takes an open state and a closed state, and opens and closes the second starting port 12 by the operation of the electric chew opening / closing member 12k. The electric chew opening / closing member 12k is driven by an electric chew solenoid 12s described later. When the electric chew opening / closing member 12k is in the open state, it is possible to enter the game ball into the second starting port 12, and when it is in the closed state, it is impossible to enter the game ball into the second starting port 12. Become. That is, the 2nd starting opening 12 is a starting opening from which the ease of entering a game ball can change. In addition, if the electric chew is easier to enter the second starting port when the electric chew opening / closing member is in the open state than when it is in the closed state, 2 It is not necessary to make it impossible to enter the starting port.

  In addition, on the right side of the first start opening 11 in the game area 6, a large winning device (special electric accessory) 14D having a large winning opening 14 is provided. The special winning opening 14 is also referred to as a special winning opening. The large winning device 14D is also called an attacker (AT), special winning means, or a special variable winning device. The big prize device 14D includes an AT opening / closing member 14k (special prize opening opening / closing member) that takes an open state and a closed state, and opens / closes the big prize opening 14 by the operation of the AT opening / closing member 14k. The AT opening / closing member 14k is driven by an AT solenoid 14s described later. The special winning opening 14 allows a game ball to enter only when the AT opening / closing member 14k is in an open state.

  A gate 13 through which a game ball can pass is provided on the right side of the center frame 61. The gate 13 is also referred to as a passage opening or a passage region. The passage of the game ball to the gate 13 triggers the execution of a normal symbol lottery (that is, acquisition and determination of a normal symbol random number (per random number)) that determines whether or not to open the electric chew 12D. Further, a plurality of general winning ports 10 are provided in the lower part of the game area 6. Further, at the bottom of the game area 6, there is provided an out port 19 through which game balls that have been driven into the game area 6 but have not won any winning holes are discharged out of the game area 6.

  Thus, in the game area 6 in which various winning openings are arranged, the left game area 6L (first game area) on the left side of the center in the left-right direction and the right game area 6R (second game area) on the right side. There is. The method of hitting a game ball so that the game ball flows down in the left game area 6L is called left-handed. On the other hand, a method of hitting a game ball so that the game ball flows down in the right game area 6R is referred to as a right hit. In the pachinko gaming machine PY1 of this embodiment, the flow path where the game ball flows down when playing left-handed is referred to as a first flow path R1, and the flow path where the game ball flows down when playing right-handed This is referred to as a second flow path R2.

  A first start port 11, an electric chew 12D, and an out port 19 are provided on the first flow path R1. The player can aim to win the first starting port 11 by driving a game ball so as to flow down the first flow path R1. In addition, since the gate is not arranged on the first flow path R1, the electric Chu 12D is not opened when left-handed.

  On the other hand, on the second flow path R2, a gate 13, a prize winning device 14D, an electric chew 12D, and an out port 19 are provided. The player can aim to pass to the gate 13 and win the second starting port 12 and the big winning port 14 by driving a game ball so as to flow down the second flow path R2.

  Further, as shown in FIG. 5, a display device 8 is arranged at the lower right portion of the game board 1. As shown in FIG. 7, the display device 8 includes a first special symbol display 81a for variably displaying the first special symbol, a second special symbol indicator 81b for variably displaying the second special symbol, and a normal symbol. A universal display 82 for variably displaying (normal) is included. The first special symbol is also referred to as a first special symbol or a special diagram 1, and the second special symbol is also referred to as a second special symbol or a special diagram 2. Ordinary symbols are also called ordinary symbols.

  In addition, the display unit 8 holds the operation number of the first special figure display unit 83a and the second special figure display unit 81b, which display the number of stored operations of the first special figure display unit 81a. A second special figure hold indicator 83b for displaying the stored number of (second special figure hold), and a universal figure hold indicator 84 for displaying the number of stored operation hold (common figure hold) of the general figure display 82 are included. It is.

  The variable display of the first special symbol is performed in response to the winning of a game ball at the first start port 11. The variable display of the second special symbol is performed in response to the winning of a game ball at the second start port 12. In the following description, the first special symbol and the second special symbol may be collectively referred to as a special symbol (special symbol). The first special figure display 81a and the second special figure display 81b may be collectively referred to as a special figure display 81 (design display means). The first special figure hold indicator 83a and the second special figure hold indicator 83b may be collectively referred to as a special figure hold indicator 83. The first special figure hold and the second special figure hold may be collectively referred to as a special figure hold.

  The special symbol display 81 displays a special symbol variably (variable display) and then stops and displays a lottery (special symbol lottery, jackpot lottery) based on winning at the first starting port 11 or the second starting port 12 Inform the results. The special symbol that is stopped and displayed (the special symbol that is derived and displayed as the display result of the stop symbol and variable display) is one special symbol that is selected from a plurality of types of special symbols by the special symbol lottery. When the stop symbol is a predetermined special symbol (a special symbol of a specific stop mode, that is, a jackpot symbol), an open pattern corresponding to the type of the special symbol that is stopped and displayed (that is, the type of the winning jackpot) is displayed. A big hit game (an example of a special game) is performed in which the special winning opening 14 is opened. In addition, the opening pattern of the special winning opening in the special game will be described later.

  Specifically, the special figure indicator 81 is composed of, for example, eight LEDs (Light Emitting Diodes) arranged side by side, and displays a special symbol corresponding to the result of the big hit lottery depending on the lighting mode. is there. For example, if you win a jackpot (one of several types of jackpots to be described later), 1, 2, from the left such as “○ ●●● ○○ ●●” (○: lit, ●: unlit) The jackpot symbol in which the fifth and sixth LEDs are lit is displayed. In the case of a loss, a lost symbol in which only the rightmost LED is lit, such as “●●●●●●● ○”, is displayed. You may employ | adopt the aspect which light-extinguishes all LED as a loss pattern. Note that the lost symbol is not a specific special symbol. Further, before the special symbol is stopped and displayed, the special symbol is variably displayed over a predetermined variation time. The variation display mode is, for example, that each LED is lit so that light repeatedly flows from left to right. It is an aspect. The mode of the variable display may be anything such as all the LEDs blinking at once as long as each LED is not stopped (lighted display in a specific mode).

  In this pachinko gaming machine PY1, when there is a winning game ball (win ball) in the first starting port 11 or the second starting port 12, various random number values (numerical information such as jackpot random numbers) acquired for the winning game , Information for determination) is temporarily stored in a special figure holding storage unit 105 described later. Specifically, if a prize is awarded to the first start port 11, the first special figure is stored as a first special figure reservation storage unit 105a, which will be described later. As figure hold, it is stored in a second special figure hold storage unit 105b described later. There is an upper limit to the number of special figure holds that can be stored in each special figure hold storage unit 105, and the upper limit value in this embodiment is “4”.

  The special figure hold stored in the special figure hold storage unit 105 is digested when the variable display of the special symbol based on the special figure hold becomes possible. Digesting a special figure hold means that a jackpot random number corresponding to the special figure hold is determined, and a special symbol variable display for indicating the determination result is executed. Accordingly, in this pachinko gaming machine PY1, when the variable display of the special symbol based on the winning of the game ball to the first start port 11 or the second start port 12 cannot be performed immediately after the winning, that is, the execution of the variable symbol variable display Even if there is a prize during the execution of a special game or during a special game, the right of lottery for the prize can be reserved up to a predetermined number.

  The number of special figure hold is displayed on the special figure hold indicator 83. Specifically, each special figure hold indicator 83 is composed of, for example, four LEDs, and displays the number of special figure holds by turning on the LEDs by the number of special figure holds.

  The variable display of the normal symbol is performed when the game ball passes to the gate 13 as an opportunity. The general symbol display 82 notifies the result of the normal symbol lottery based on the passing of the game ball to the gate 13 by variably displaying the normal symbol (variation display) and then displaying the stop symbol. A normal symbol that is stopped and displayed (a normal symbol that is derived and displayed as a variable display result) is one normal symbol selected from a plurality of types of normal symbols by a normal symbol lottery. When the stop-displayed normal symbol is a predetermined specific symbol (a normal symbol of a predetermined stop mode, that is, a normal winning symbol), the second start port 12 is opened in an opening pattern corresponding to the current gaming state. An auxiliary game to be performed is performed. The opening pattern of the second start port 12 will be described later.

  Specifically, the general symbol display 82 is composed of, for example, two LEDs (see FIG. 7), and displays a normal symbol corresponding to the result of the normal symbol lottery depending on the lighting state. For example, when the lottery result is a win, a normal winning symbol in which both LEDs are lit is displayed, such as “◯◯” (◯: lit, ●: unlit). Further, when the lottery result is a loss, a normal lose symbol in which only the right LED is lit is displayed as “● ○”. You may employ | adopt the aspect which light-extinguishes all LED as a normal lose pattern. Note that the normal lose symbol is not a specific normal symbol. Before the normal symbol is stopped and displayed, the normal symbol is displayed for a predetermined variation time. The variation display mode is, for example, a mode in which both LEDs are alternately lit. The mode of the variable display may be anything such as all the LEDs blinking at once as long as each LED is not stopped (lighted display in a specific mode).

  In this pachinko gaming machine PY1, when a game ball passes to the gate 13, the value of the normal symbol random number (per random number) obtained for the passage is stored in the general figure hold storage unit 106, which will be described later, as a general figure hold. Once memorized. There is an upper limit to the number of pending map holds that can be stored in the pending map storage unit 106, and the upper limit value in this embodiment is “4”.

  The general map reservation stored in the general map storage unit 106 is digested when the variable display of the normal symbol based on the general map storage becomes possible. The digestion of the general symbol hold means that a normal symbol random number (per random number) corresponding to the general symbol hold is determined and variable symbol display for displaying the determination result is executed. Accordingly, in this pachinko gaming machine PY1, when the variable display of the normal symbol based on the passage of the game ball to the gate 13 cannot be performed immediately after the passage, that is, during the execution of the variable symbol display of the normal symbol or the execution of the auxiliary game Even if there is, there is a predetermined number as the upper limit, and the right of normal symbol lottery for the passage can be reserved.

  The number of the general map hold is displayed on the general map hold display 84. Specifically, the general-purpose hold indicator 84 is composed of, for example, four LEDs, and displays the number of general-purpose holds by turning on the LEDs as many times as the number of general-purpose holds.

2. Configuration of Upper Decoration Unit Next, the configuration of the upper decoration unit 200 will be described with reference to FIGS. 3 and 8 to 13. As shown in FIG. 8, the upper decoration unit 200 is attached to the upper part of the base frame 23 w of the front door 23. The upper decoration unit 200 includes an elevating unit 300, a central upper unit 400, a left upper unit 500, and an upper right unit 550. The central upper unit 400, the upper left unit 500, and the upper right unit 550 are assembled to a mounting base 331 disposed on the front side of the elevating unit 300.

  The elevating unit 300 performs the elevating operation of the upper decorative unit 200 (see FIGS. 3 and 9). The upper left unit 500 and the upper right unit 550 perform an opening / closing operation (see FIGS. 9 and 12). Hereinafter, when the upper left unit 500 and the upper right unit 550 are described together, they may be referred to as an “opening / closing unit 600”. The opening / closing unit 600 is assembled to the central upper unit 400.

  First, the raising / lowering operation in the upper decoration unit 200 will be described. The central upper unit 400 and the opening / closing unit 600 on the movable side of the upper decorative unit 200 are raised (moved) from the lowered position (origin position) shown in FIG. 3 to the raised position (operating position) shown in FIG. ) Is possible. In the side view, the central upper unit 400 and the opening / closing unit 600 can be moved from the lowered position shown in FIG. 10A to the raised position shown in FIG. Of course, the central upper unit 400 and the opening / closing unit 600 can be lowered (moved) to the lowered position.

  As shown in FIGS. 11A and 11B, the lifting unit 300 includes a lifting motor 310 (see a two-dot chain line) that is a stepping motor, a first gear 311, a second gear 312, and a third gear 313. It has. Therefore, when the elevating motor 310 is driven, the first gear 311, the second gear 312, and the third gear 313 rotate in order. Further, the elevating unit 300 is formed with an arc-shaped long hole 314 (see a two-dot chain line) that extends long in the vertical direction. A shaft pin 411 of a slide member 410 (described later) is inserted into the long hole 314 so as to be slidable in the vertical direction.

  As shown in FIG. 3, the central upper unit 400 includes a central movable body 401 (movable body, driving means) at the center as a production movable object, and as shown in FIGS. In addition, a slide member 410 is provided. A shaft pin 411 inserted through the long hole 314 described above is provided at the lower end of the slide member 410. The central upper unit 400 is provided with a link mechanism 420. The link mechanism 420 has the slide member 410 assembled thereto, and the slide member 410 can be moved along the long hole 314 by the rotation of the third gear 313 described above.

  Thus, when the lifting motor 310 is driven when the central upper unit 400 (central movable body 401) and the opening / closing unit 600 are in the lowered position shown in FIG. 3, the first gear 311, the second gear 312 and the third gear 313 are driven. And rotate. As a result, the link mechanism 420 is operated, and the shaft pin 411 of the slide member 410 slides upward along the long hole 314 from the position shown in FIG. 11A to the position shown in FIG. As a result, the central upper unit 400 (central movable body 401) in which the slide member 410 is assembled and the opening / closing unit 600 are raised to the raised position shown in FIG.

  Here, as shown in FIGS. 3 and 9, an annular touch electrode 430 is attached to the front side of the central movable body 401. The touch electrode 430 is electrically connected to a touch sensor 431 (not shown in FIGS. 3 and 8) provided inside the central movable body 401. The touch sensor 431 detects contact of a human body (such as a player) with the touch electrode 430, and is specifically a capacitive touch sensor that uses a high-frequency oscillation circuit. That is, when the human body comes into contact with the touch electrode 430, the high-frequency sine wave voltage oscillated by the high-frequency oscillation circuit decreases based on the electrostatic capacitance (human body capacitance) with respect to the ground of the human body. The touch sensor 431 detects that the human body has touched the touch electrode 430 by detecting the decrease in the high-frequency sine wave voltage. Note that the touch sensor 431 can detect not only the contact of the human body with the touch electrode 430 but also the approach of the human body to the touch electrode 430 by adjusting the sensitivity by setting.

  In this embodiment, when the detection by the touch sensor 431 is performed, the central movable body 401 (central upper unit 400) can be stopped. Therefore, if the human body (player or the like) contacts the touch electrode 430 while the central movable body 401 is moving, the central movable body 401 can be stopped. Thereby, it is possible to avoid a human body being sandwiched between the moving central movable body 401 and other effects. If the human body is in contact with the touch electrode 430, the central movable body 401 continues to stop at the standby position even when the central movable body 401 at the standby position starts to drive to the drive position. If the human body is in contact with the touch electrode 430, the central movable body 401 continues to stop at the driving position even when the central movable body 401 at the driving position starts to drive to the standby position.

  As shown in FIGS. 3 and 9, a contact notification lamp 432 is provided above the touch electrode 430 in the central movable body 401. The contact notification lamp 432 can emit light when detection by the touch sensor 431 is being performed. Therefore, when the player touches the touch electrode 430, the contact notification lamp 432 emits light so that it is better not to touch the touch electrode 430 (the human body may be caught by the central movable body 401). It is possible to make it easier for the player to grasp.

  Next, the opening / closing operation in the upper decoration unit 200 will be described. The opening / closing unit 600 (specifically, a left movable body 510 and a right movable body 560 described later) opens (moves) from the closed position (origin position) shown in FIG. 9 to the open position (operating position) shown in FIG. Is possible. The opening / closing unit 600 opens and closes with respect to the central upper unit 400. 9 and 12, the opening / closing operation of the opening / closing unit 600 is shown when the central upper unit 400 is in the raised position, but the opening / closing unit 600 is opened / closed even when the central upper unit 400 is in the lowered position. Is possible. The upper left unit 500 and the upper right unit 550 have symmetrical shapes, and the components are the same. Therefore, hereinafter, the upper left unit 500 will be described, and a detailed description of the upper right unit 550 will be omitted.

  As shown in FIG. 13, the upper left unit 500 includes a left movable body 510 (movable body, drive means) and an opening / closing drive unit 530 for driving the left movable body 510. The opening / closing drive unit 530 meshes with the upper left motor 531 which is a stepping motor, the drive gear 532 attached to the rotation shaft of the upper left motor 531, the driven gear 533 meshed with the drive gear 532, and the driven gear 533. The fan-shaped gear part 534 is provided. The sector gear portion 534 is fixed to the left movable body 510. Therefore, when the upper left motor 531 is driven, the drive gear 532, the driven gear 533, and the sector gear portion 534 are interlocked, and the left movable body 510 rotates about the shaft member 511 as a rotation center.

  The left movable body 510 is a combination of an inner member 512 that is not visible to the player when in the closed position (see FIG. 9) and an outer member 520 that is visible to the player when in the closed position. . The inner member 512 includes a circular inner lens portion 513 and an inner main body portion 515 that surrounds the inner lens portion 513. The outer member 520 includes a circular outer lens portion 521 (see FIG. 9) and an outer portion. And an outer main body portion 523 surrounding the lens portion 521. The inner main body 515 and the outer main body 523 are made of a synthetic resin having translucency.

  Regarding the upper right unit 550, the configuration corresponding to the left movable body 510 is referred to as a right movable body 560 (movable body, driving means), the configuration corresponding to the upper left motor 531 is referred to as an upper right motor 581, and the remaining configuration is referred to. The names and symbols are the same as those in the upper left unit 500. In this embodiment, the left movable body 510 and the right movable body 560 may open / close at the same time, or only one of them may open / close. Further, the opening operation of the left movable body 510 (movement from the closed position to the opening position) ⇒ the opening operation of the right movable body 560 ⇒ the closing operation of the left movable body 510 (movement from the opening position to the closing position) ⇒ right movable body 560 The left movable body 510 and the right movable body 560 may operate in the order of the closing operations.

  Here, the function of the unfolding button 44k will be described. In this embodiment, during the execution of SP reach (strong SP reach), which has a particularly high expectation of winning among SP reach described later, the unfolding drive effect by the central upper unit 400 and the opening / closing unit 600 can be executed. When the unfolding drive effect is executed, first, the central movable body 401 (central upper unit 400) moves from the lowered position shown in FIG. 3 to the raised position shown in FIG. Thereafter, the left movable body 510 and the right movable body 560 move from the closed position shown in FIG. 9 to the open position shown in FIG. By executing the unfolding drive effect in this way, it is possible to further enhance the effect of the effect as an effect with a high degree of winning expectation.

  However, when the unfolding drive effect is executed, it is difficult for the player to see the upper side than the pachinko gaming machine PY1 as shown in FIG. Specifically, the central movable body 401, the left movable body 510, and the right movable body 560 that are widely deployed above the pachinko gaming machine PY1 are obstructed and arranged above the pachinko gaming machine PY1. It may be difficult to see the data counter or the like. Therefore, in this embodiment, the left movable body 510 and the right movable body 560 (opening / closing unit 600) are moved (returned) to the closed position by pressing the unfolding release button 44k, and the central movable body 401 (the central upper unit 400). ) Can be moved to the lowered position. Thus, even when the deployment drive effect is being executed, the player can make the upper side (data counter or the like) easier to see than the pachinko gaming machine PY1 by pressing the deployment release button 44k.

  When the central movable body 401 is not in the lowered position, the central movable body 401 is moved to the lowered position by pressing the unfolding release button 44k regardless of the position of the left movable body 510 and the right movable body 560. The left movable body 510 and the right movable body 560 can be moved to the closed position. Further, when any one of the central movable body 401, the left movable body 510, and the right movable body 560 is moving, the central movable body 401 can be moved to the lowered position by pressing the unfolding release button 44k. It is possible and the left movable body 510 and the right movable body 560 can be moved to the closed position.

3. Next, the electrical configuration of the pachinko gaming machine PY1 will be described with reference to FIGS. As shown in FIG. 14 and FIG. 15, the pachinko gaming machine PY1 relates to a game control board 100 (main control board) that performs control related to game profits such as jackpot lottery and game state transition, and effects that are executed as the game progresses. An effect control board 120 (sub control board) that performs control, a payout control board 170 that performs control related to payout of game balls, and the like are provided. The game control board 100 constitutes a main control part, and the effect control board 120 constitutes a sub control part together with an image control board 140, a sound control board 161, and a sub drive board 162 described later.

  The sub-control unit includes at least an effect control board 120 and effects means (image display device 50, speaker 610, panel lamp 54, frame lamp 212, central movable body 401, left movable body 510, right movable body 560, character The game effect using the movable body 55k, the ball movable body 56k, and the like may be controlled.

  The pachinko gaming machine PY1 includes a power supply board 190. The power supply board 190 supplies power to the game control board 100, the effect control board 120, and the payout control board 170, and supplies necessary power to other devices via these boards. A backup power supply circuit 192 is provided on the power supply board 190. When power is not supplied to the pachinko gaming machine PY1, the backup power supply circuit 192 is connected to a game RAM (Random Access Memory) 104 of the game control board 100 and an effect RAM 124 of the effect control board 120 described later. Supply power. Accordingly, the information stored in the game RAM 104 of the game control board 100 and the effect RAM 124 of the effect control board 120 is retained even when the pachinko gaming machine PY1 is disconnected. A power switch 191 is connected to the power board 190. By turning on / off the power switch 191, power on / off is switched. Note that a backup power supply circuit for the game RAM 104 of the game control board 100 may be provided in the game control board 100, or a backup power supply circuit for the effect RAM 124 of the effect control board 120 may be provided in the effect control board 120.

  As shown in FIG. 14, a game control board 100 is mounted with a game control one-chip microcomputer (hereinafter referred to as “game control microcomputer”) 101 that controls the progress of the game of the pachinko gaming machine PY1 according to a program. In the game control microcomputer 101, a game ROM (Read Only Memory) 103 storing a program for controlling the progress of the game, a game RAM 104 used as a work memory, and a program stored in the game ROM 103 are stored. A game CPU (Central Processing Unit) 102 to be executed and a game I / O (Input / Output) port 118 for inputting and outputting data and signals are included. The gaming RAM 104 is provided with the above-described special figure reservation storage unit 105 (the first special figure reservation storage unit 105a and the second special figure reservation storage unit 105b) and the general figure reservation storage unit 106. The game ROM 103 may be externally attached.

  Various sensors and solenoids are connected to the game control board 100 via a relay board 110. Therefore, a signal is input from the respective sensors to the game control board 100, and a signal is output from the game control board 100 to each solenoid. Specifically, as the sensors, the first start port sensor 11a, the second start port sensor 12a, the gate sensor 13a, the big winning port sensor 14a, and the general winning port sensor 10a are connected.

  The first start port sensor 11 a is provided in the first start port 11 and detects a game ball that has won the first start port 11. The second start port sensor 12 a is provided in the second start port 12 and detects a game ball won in the second start port 12. The gate sensor 13 a is provided in the gate 13 and detects a game ball that has passed through the gate 13. The special winning opening sensor 14 a is provided in the special winning opening 14 and detects a game ball that has won the special winning opening 14. The general winning opening sensor 10 a is provided in the general winning opening 10 and detects a game ball that has won the general winning opening 10.

  As solenoids, an electric chew solenoid 12s and an AT solenoid 14s are connected. The electric chew solenoid 12s drives the electric chew opening / closing member 12k of the electric chew 12D. The AT solenoid 14s drives the AT opening / closing member 14k of the special winning device 14D.

  Further, on the game control board 100, a special figure display 81 (first special figure display 81a and second special figure display 81b), a general figure display 82, a special figure hold display 83 (first special figure hold display). 83a, the second special figure hold indicator 83b), and the universal figure hold indicator 84 are connected. That is, display control of these display devices 8 is performed by the game control microcomputer 101.

  The game control board 100 transmits various commands and signals to the payout control board 170 and receives signals from the payout control board 170 for payout monitoring. On the payout control board 170, a card unit CU (installed adjacent to the pachinko gaming machine PY1 and capable of lending a ball based on information such as an inserted prepaid card) and a prize ball payout device 73 are provided. In addition to being connected, a launching device 72 is connected via a launch control circuit 175. The launcher 72 includes a handle 72k (see FIG. 1).

  The payout control board 170 drives the prize ball motor 73m of the prize ball payout device 73 based on a signal from the game control microcomputer 101 and a signal from the card unit CU connected to the pachinko gaming machine PY1. Paying out or paying out rental balls. The game balls to be paid out are detected by the prize ball sensor 73a for counting, and a detection signal from the prize ball sensor 73a is output to the payout control board 170.

  When the player operates the handle 72k (see FIG. 1) of the launch device 72, the touch switch 72a detects contact with the handle 72k, and the launch volume 72b detects the amount of rotation of the handle 72k. Then, the firing solenoid 72s is driven so that the game ball is fired with a strength corresponding to the magnitude of the detection signal of the firing volume 72b. In this pachinko gaming machine PY1, one game ball is launched in about 0.6 seconds.

  In addition, the game control board 100 transmits various commands to the effect control board 120. The connection between the game control board 100 and the effect control board 120 is a unidirectional communication connection that can only transmit signals from the game control board 100 to the effect control board 120. That is, a not-shown unidirectional circuit (for example, a circuit using a diode) is interposed between the game control board 100 and the effect control board 120 as communication direction regulating means.

  As shown in FIG. 15, an effect control one-chip microcomputer (hereinafter “effect control microcomputer”) 121 that controls the effect of the pachinko gaming machine PY <b> 1 according to a program is mounted on the effect control board 120. The effect control microcomputer 121 executes an effect ROM 123 storing a program for controlling the effect as the game progresses, an effect RAM 124 used as a work memory, and a program stored in the effect ROM 123. An effect CPU 122 and an effect I / O port 138 for inputting and outputting data and signals are included. The production ROM 123 may be externally attached.

  As shown in FIG. 15, an image control board 140 and an audio control board 161 (audio control circuit) are connected to the effect control board 120. An image display device 50 is connected to the image control board 140, and a speaker 610 is connected to the sound control board 161. As shown in FIGS. 15 and 16, a sub drive board 162 (sub drive circuit) is connected to the effect control board 120.

  As shown in FIG. 16, the sub-drive board 162 has a frame lamp 212, a panel lamp 54, a character movement motor 58 (character movable body 55k), a ball horizontal movement motor 92, and a ball vertical movement motor 94 (ball movable body 56k). Is connected. Further, the sub drive board 162 is connected to the lifting motor 310 provided in the lifting unit 300, the contact notification lamp 432 and the touch sensor 431 provided in the central movable body 401 via the on-frame relay board 180. Has been. Further, the sub drive board 162 is connected to the upper left motor 531 of the upper left unit 500 and the upper right motor 581 of the upper right unit 550 via the on-frame relay board 180.

  As shown in FIG. 15, the effect control microcomputer 121 (effect control means) of the effect control board 120 sends the image display device 50 of the image display device 50 to the image CPU 141 of the image control board 140 based on the command received from the game control board 100. Let control take place. The image control board 140 includes an image ROM 142 storing a program for controlling image display and the like, an image RAM 143 used as a work memory, and an image CPU 141 executing the program stored in the image ROM 142. I have. In the image ROM 142, still image data and moving image data displayed on the image display device 50, specifically, characters, items, figures, characters, numbers, symbols, etc. (including effect designs), background images, etc. Image data is stored.

  Further, the effect control microcomputer 121 outputs voice, music, sound effect, etc. from the speaker 610 via the voice control board 161 based on the command received from the game control board 100. Sound data such as voice output from the speaker 610 is stored in the effect ROM 123 of the effect control board 120. Note that a CPU may be mounted on the voice control board 161, and in that case, the CPU may execute voice control. Furthermore, in this case, a ROM may be mounted on the voice control board 161, and acoustic data may be stored in the ROM. Further, the speaker 610 may be connected to the image control board 140, and the image CPU 141 of the image control board 140 may execute sound control. Further, in this case, acoustic data may be stored in the image ROM 142 of the image control board 140.

  As shown in FIGS. 15 and 16, the effect control microcomputer 121 receives various frame lamps 212, via the sub drive board 162 and the on-frame relay board 180, based on the command received from the game control board 100. Lighting control of lamps such as the panel lamp 54 and the contact notification lamp 432 is performed. Specifically, the production control microcomputer 121 creates light emission pattern data (data for determining lighting / extinction and light emission color, also referred to as lamp drive data) that determines the light emission mode of each lamp, and the light emission of each lamp according to the light emission pattern data. To control. Note that the data stored in the effect ROM 123 of the effect control board 120 is used to create the light emission pattern data.

  Specifically, the frame lamp 212, the panel lamp 54, and the contact notification lamp 432 are LEDs mounted on the circuit board. The frame lamp 212, the panel lamp 54, and the contact notification lamp 432 can emit light according to the magnitude of the drive current flowing in the LED circuit on the circuit board. That is, the larger the drive current flowing through the LED circuit on the circuit board, the brighter the frame lamp 212, the panel lamp 54, and the contact notification lamp 432 can emit light. In this embodiment, the production control microcomputer 121 can adjust the magnitude of the drive current flowing in the LED circuit of the circuit board of the frame lamp 212 and the panel lamp 54 based on the lamp data transmitted to the sub drive board 162. Yes. In the LED circuit, in order to change the brightness without changing the color of the LED, PWM control (pulse width modulation control) based on a PWM (Pulse Width Modulation) signal is executed.

  Here, in this embodiment, when the touch sensor 431 detects the contact of the human body with the touch electrode 430, a detection signal is input from the touch sensor 431 to the effect control board 120 via the on-frame relay board 180 and the sub drive board 162. . At this time, the effect control microcomputer 121 transmits the contact notification lamp data to the sub drive board 162. As a result, the sub drive board 162 that has received the contact notification lamp data causes the contact notification lamp 432 to emit light via the on-frame relay board 180.

  Further, the effect control microcomputer 121 controls the driving of the character movable body 55k and the ball movable body 56k via the sub drive board 162 based on the command received from the game control board 100, and also controls the sub drive board 162 and the frame on the frame. Drive control of the central movable body 401, the left movable body 510, and the right movable body 560 is performed via the relay substrate 180. Specifically, the production control microcomputer 121 creates operation pattern data (also referred to as drive data) that determines the operation mode of each movable body, and in accordance with the operation pattern data, the character movement motor 58, the ball left / right movement motor 92, and the ball vertical movement Drive control of the motor 94, the raising / lowering motor 310, the upper left motor 531 and the upper right motor 581 is performed. The operation pattern data is created using data stored in the effect ROM 123 of the effect control board 120.

  In this embodiment, the lift motor 310, the upper left motor 531, the upper right motor 581, the character moving motor 58, the ball left / right moving motor 92, and the ball vertical moving motor 94 are stepping motors, and the number of steps by the effect control microcomputer 121 is Driven by management. Therefore, the production control microcomputer 121 controls how many steps the rotation motor 310, upper left motor 531, upper right motor 581, character movement motor 58, ball left / right movement motor 92, and ball vertical movement motor 94 are driven to rotate by managing the number of steps. I know. That is, the production control microcomputer 121 can grasp the current position of the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k by managing the number of steps. It is like that.

  Further, in this pachinko gaming machine PY1, photosensors for detecting the positions of the central movable body 401, the left movable body 510, and the right movable body 560 are provided in order to enhance safety. That is, although not shown, a photo sensor for detecting the lowered position of the central movable body 401, a photo sensor for detecting the raised position of the central movable body 401, a photo sensor for detecting the closed position of the left movable body 510, and the left movable body A photo sensor for detecting the open position 510, a photo sensor for detecting the closed position of the right movable body 560, and a photo sensor for detecting the open position of the right movable body 560 are provided. In this way, the production control microcomputer 121 can grasp the positions of the central movable body 401, the left movable body 510, and the right movable body 560 not only by managing the number of steps but also by a photo sensor.

  Note that a CPU may be mounted on the sub-drive board 162, and in that case, the CPU may perform lamp lighting control or movable body drive control. Further, in this case, a ROM may be mounted on the sub drive board 162, and data related to the light emission pattern and the operation pattern may be stored in the ROM.

  Further, as shown in FIG. 15, an input unit detection sensor 40a (production button detection sensor), a select button detection sensor 42a, and a deployment release button detection sensor 44a are connected to the production control board 120. The input unit detection sensor 40a detects that the input unit 40k (see FIG. 1) has been pressed. When the input unit 40k is pressed, a detection signal is output from the input unit detection sensor 40a to the effect control board 120. The select button detection sensor 42a detects that the select button 42k (see FIG. 1) has been pressed. When the select button 42k is pressed, a detection signal is output from the select button detection sensor 42a to the effect control board 120.

  The unfolding button detection sensor 44a detects that the unfolding button 44k (see FIG. 1) has been pressed. When the deployment release button 44k is pressed, a detection signal is output from the deployment release button detection sensor 44a to the effect control board 120. Thereby, as described above, the production control microcomputer 121 moves the central movable body 401 that is not in the lowered position to the lowered position, and moves the left movable body 510 and the right movable body 560 that are not in the closed position to the closed position. Is possible.

  14 to 16 are functional block diagrams for explaining the electrical configuration of the pachinko gaming machine PY1 to the last, and not only the substrate shown in FIGS. 14 to 16 is provided. Except for the game control board 100, any of the plurality of boards shown in FIGS. 14 to 16 may be configured as one board, or the one board shown in FIGS. 14 to 16 may be configured as a plurality of boards. good.

  By the way, in this embodiment, the elevating motor 310, the upper left motor 531, the upper right motor 581, the character moving motor 58, the ball left / right moving motor 92, and the ball vertical moving motor 94 have been generally used as production motors. It is not a unipolar stepping motor but a bipolar stepping motor.

  Here, the function of the bipolar stepping motor will be schematically described with reference to FIG. As shown in FIG. 17A, in the bipolar stepping motor, two sets of coils A and B are provided. The coil A is provided with a φ1 terminal and a φ2 terminal. The coil B is provided with a φ3 terminal and a φ4 terminal. When driving this bipolar stepping motor, the directions of the currents flowing through the coil A and the coil B are alternated as shown in (1) → (2) → (3) → (4) of FIG. It is designed to switch.

  That is, first, as shown in (1) of FIG. 17A, a current is passed from the φ1 terminal of the coil A to the φ2 terminal. Next, as shown in (2) of FIG. 17A, a current is passed from the φ3 terminal of the coil B to the φ4 terminal. Subsequently, as shown in (3) of FIG. 17A, a current is passed from the φ2 terminal of the coil A to the φ1 terminal. Finally, as shown in (4) of FIG. 17A, a current is passed from the φ4 terminal of the coil B to the φ3 terminal. Thereafter, by repeating the above (1), (2), (3), and (4), the rotating shaft is rotated so as to be attracted by the generated magnetic force. Thus, the bipolar stepping motor is characterized in that the direction of the current flowing through each terminal is switched.

  On the other hand, the function of a unipolar stepping motor that has been conventionally used as a production motor will be schematically described with reference to FIG. As shown in FIG. 17B, even in a unipolar stepping motor, two sets of coils A and B are provided. The coil A is provided with a φ1 terminal and a φ2 terminal, and a tap TP is provided in the middle of the coil A. The coil B is provided with a φ3 terminal and a φ4 terminal, and a tap TP is provided in the middle of the coil B. A positive power source (DC) is always connected to the tap TP. When driving this unipolar stepping motor, as shown in (1) → (2) → (3) → (4) of FIG. 17 (B), the current flows from the tap TP to each terminal in one direction. It has become.

  That is, first, as shown in (1) of FIG. 17B, a current is passed from the tap TP of the coil A to the φ1 terminal. Next, as shown in (2) of FIG. 17B, a current flows from the tap TP of the coil B to the φ3 terminal. Subsequently, as shown in (3) of FIG. 17B, a current is passed from the tap TP of the coil A to the φ2 terminal. Finally, as shown in (4) of FIG. 17B, a current is passed from the tap TP of the coil B to the φ4 terminal. Thereafter, by repeating the above (1), (2), (3), and (4), the rotating shaft is rotated so as to be attracted by the generated magnetic force. Thus, the unipolar stepping motor is characterized in that the direction of current flowing through each terminal is always constant.

  As described above, in the unipolar stepping motor shown in FIG. 17B, half of the coils A and B in each phase during rotation (any one of (1), (2), (3), and (4)) The current flows only at the (winding). On the other hand, in the bipolar stepping motor shown in FIG. 17A, although the direction of current is switched in the coils A and B in each phase during rotation, the current flows through the entire coil. . That is, the coil always functions. Therefore, when the bipolar stepping motor is used as in the present embodiment, the use efficiency of the coil is higher if the coil has the same number of turns than the conventional unipolar stepping motor. . As a result, the motor can be efficiently rotated, and the output torque during low-speed rotation can be increased.

  In this way, in this embodiment, the bipolar stepping motor 310, the upper left motor 531, the upper right motor 581, the character moving motor 58, the ball left / right moving motor 92, and the ball up / down moving motor 94 are used, so that the unipolar type is used. As compared with the case of using the stepping motor, it is possible to increase the output torque at the time of low speed rotation. However, while the output torque during low-speed rotation is high, there is a demerit that the consumption current (electric power) is larger than that of a unipolar stepping motor.

  Further, in this embodiment, as the excitation method when the bipolar stepping motor moves the movable bodies (the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k), Phase excitation is used. As shown in FIG. 18A, the two-phase excitation is a method in which two phases are simultaneously excited while being shifted by one pulse with respect to the next phase to which a pulse is applied. One example of this two-phase excitation is one-phase excitation. As shown in FIG. 18B, the one-phase excitation is a method of exciting one phase at a time each time a pulse is applied. The two-phase excitation of this embodiment can stabilize the rotation as compared with the one-phase excitation, and is advantageous for high-speed rotation. Furthermore, there is an advantage that the output torque can be increased. However, there is a demerit that the current consumption (power) is about twice that of the single-phase excitation.

4). Next, current limitation to the frame lamp 212 and the panel lamp 54, which is a feature of this embodiment, will be described. First, the current limiting situation will be described. In the power supply board 190 (see FIG. 14 and FIG. 15), power supplies (electric power) of various voltages are created from an AC power supply of 24 V supplied from the outside. Specifically, the power board 190 (power supply means) generates a DC 37V power source from a 24V AC power source using a rectifier circuit, a smoothing circuit, a DC-DC converter, and the like. Furthermore, a DC12V power supply, a DC5V power supply, a DC18V power supply, and a DC24V power supply are generated from a part of the DC37V power supply.

  Among these power sources, for example, a DC 24V power source is a power source for a production motor (elevating motor 310, upper left motor 531, upper right motor 581, character moving motor 58, ball left / right moving motor 92, and ball vertical moving motor 94). Used as. The DC18V power supply is used as a power supply for various LEDs (frame lamp 212, panel lamp 54, contact notification lamp 432). A DC5V power supply is used as a power supply for various integrated circuits (ICs). The DC12V power supply is used as a power supply for the main control unit (game control board 100, payout control board 170), various sensors and solenoids involved in the progress of the game, and used as a power supply for the production motor. In some cases.

  By the way, in recent game machines, since there are many movable bodies and LEDs (driving means), there is a possibility that the upper limit (peak current) of the current that can be supplied by the power supply board may be exceeded, and the tolerance determined by the power supply board May exceed loss. The allowable loss is power consumption that can be allowed so as not to exceed a temperature at which the performance of the power supply board can be maintained. In the pachinko gaming machine PY1 of this embodiment, there are a plurality of relatively large frame movable bodies such as a central movable body 401, a left movable body 510, and a right movable body 560, and there are also a plurality of movable board bodies such as a ball movable body and a ball movable body 56k. . As described above, a bipolar stepping motor is used as the production motor, and two-phase excitation is used as the excitation method. As a result, the power consumption (current) of the pachinko gaming machine PY1 as a whole is large, and there is a risk of exceeding the performance of the power supply board 190.

  Here, in the design and development, in this embodiment, the allowable loss of the power supply board 190 is set to 280 W so as not to exceed the performance of the power supply board 190. In addition, the DC 37V peak current (current value that is instantaneously the largest) that is the origin of various power supplies is set to be 11 A or less. In addition, the peak currents of various power sources are set to be equal to or less than predetermined reference values so that the allowable loss and the DC 37V peak current do not exceed the above-mentioned reference values (280 W, 11 A). Therefore, in this embodiment, the peak current of the power source of the production motor (elevating motor 310, upper left motor 531, upper right motor 581, character moving motor 58, ball left / right moving motor 92, and ball vertical moving motor 94) is less than 4A. It is set to be. However, depending on the situation during the game, even if the peak current of the power supply of the production motor is 4 A or less, the load on the power supply board 190 may become too large. It is desirable that it is less than 3A (3000 mA).

  In view of the above circumstances, in the present embodiment, the following measures are taken in a situation where the peak current of the power source of the production motor is 3000 mA or more. That is, the production control microcomputer 121 can determine the situation where the peak current of the power supply of the production motor is less than 3000 mA and the situation where the peak current of the power supply of the production motor is 3000 mA or more. Specifically, the current limit determination table shown in FIG. Thereby, the production control microcomputer 121 reads the current limit determination table shown in FIG. 19 from the production ROM 123, and the current peak current of the production motor power is 3000 mA or more using the current restriction determination table. It is possible to judge whether or not.

  As a result, if the effect control microcomputer 121 determines that the peak current of the power supply of the effect motor (specific value based on the power supplied by the power supply means) is 3000 mA (predetermined value) or more, the frame lamp 212 and the panel lamp 54 (the LED circuit on the circuit board of the frame lamp 212 and the panel lamp 54) is controlled so that the current (small current) is 25%. In other words, if X current (normal current) is normally supplied to the frame lamp 212 and the panel lamp 54 at that time, if it is determined that the peak current of the power source of the production motor is 3000 mA or more, the frame lamp 212 and the panel lamp 54 are supplied with only 25% of the X current.

  As a result, the current supplied to the frame lamp 212 and the panel lamp 54 (light emitting means) is reduced, and current consumption in the frame lamp 212 and the panel lamp 54 can be suppressed. Therefore, even if the peak current of the power source of the production motor is 3000 mA or more, it is possible to suppress the current consumption of the entire pachinko gaming machine PY1. Therefore, the burden on the power supply board 190 can be reduced, and the allowable loss of the power supply board 190 can be prevented from exceeding 280 W and the peak current of DC37V can be prevented from exceeding 11 A.

  When the current supplied to the frame lamp 212 and the panel lamp 54 is 25% of the normal current (current based on the frame lamp data, current based on the panel lamp data), the frame lamp 212 and the panel lamp 54 are used. Emits light in a darker light emission mode than in normal times. However, the frame lamp 212 and the board lamp 54 are not directing means that are largely involved in the suggestion of winning expectation, and are less noticeable by the player than other directing means. Accordingly, even if the frame lamp 212 and the panel lamp 54 temporarily emit light in a darker light emission mode than in the normal state, the game is less than when the other rendering means are not driven (for example, when the movable body does not move). It is possible to reduce the sense of discomfort given to the person.

  Here, the pachinko gaming machine PY1 is provided with an extremely large number of frame lamps 212 and board lamps 54, and basically continues to emit light while the pachinko gaming machine PY1 is powered on. In addition, when an effect (SP reach or the like) having a high winning expectation level is being executed during the game, the frame lamp 212 and the panel lamp 54 emit light in a particularly bright light emission mode. As described above, the current consumption when a very large number of the frame lamps 212 and the panel lamps 54 emit light in a particularly bright light emission mode by SP reach or the like leads to an increase in the burden on the power supply board 190.

  Therefore, in this embodiment, while the performance with high expectation level (SP reach, etc.) is being executed, the performance motor is driven as usual, but the frame lamp 212 and the panel lamp 54 emit light in a particularly bright light emission mode due to current limitation. I try not to let you. As a result, the current consumption in the frame lamp 212 and the panel lamp 54 can be suppressed only during the execution of an effect (SP reach or the like) with a high expected expectation level that drives many effecting motors. That is, it is possible to effectively suppress the current consumption of the pachinko gaming machine PY1 in accordance with the situation where the burden on the power supply board 190 is increased. Thus, when the current is limited to the frame lamp 212 and the panel lamp 54, the current is controlled to 25% based on the current when the frame lamp 212 and the panel lamp 54 emit light in a particularly bright light emission mode. The frame lamp 212 and the panel lamp 54 do not become very dark.

  On the other hand, if the production control microcomputer 121 determines that the peak current of the power supply of the production motor is less than 3000 mA, the current supplied to the frame lamp 212 and the panel lamp 54 is the normal current (a predetermined normal magnitude). The current is not limited to a current that is 25% of the normal current. Therefore, in this case, the frame lamp 212 and the panel lamp 54 emit light in a normal light emission mode (light emission level, brightness).

  Here, the current limit table shown in FIG. 19 will be described. As shown in FIG. 19, the current limiting table includes various movable bodies (the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k), that is, various motors. Drive patterns 1 to 63 are provided in accordance with the drive status of the elevating motor 310, the upper left motor 531, the upper right motor 581, the character moving motor 58, the ball horizontal moving motor 92, and the ball vertical moving motor 94. And according to each drive pattern 1-63, whether the peak current of the power supply of the production motor is 3000 mA or more or less than 3000 mA is calculated in advance by the design developer, Information on whether or not the peak current of the power supply of the production motor is 3000 mA or more is shown.

  In this way, the production control microcomputer 121 has, for example, the situation of the drive pattern 1 (elevating motor 310, upper left motor 531, upper right motor 581, character moving motor 58, ball left / right moving motor 92, and ball up / down moving motor 94 are all When it is determined that the driving current), the peak current of the power source of the production motor can be determined to be 3000 mA or more from the current limit table shown in FIG. As a result, the current supplied to the frame lamp 212 and the panel lamp 54 is controlled to a low current drive in which the current is 25%.

  The effect control microcomputer 121 is, for example, in a situation where the driving pattern is 2 (although the lifting motor 310 is not driven, the upper left motor 531, the upper right motor 581, the character moving motor 58, the ball left / right moving motor 92, and the ball up / down moving motor) In the case where it is determined that the power source of the production motor is less than 3000 mA, the current limit table shown in FIG. 19 can be used. As a result, the current supplied to the frame lamp 212 and the panel lamp 54 is controlled to the normal current drive in which the current is normal.

  By the way, in this pachinko gaming machine PY1, there is something that is difficult for a design developer to assume as the operation of the movable body. Specifically, there are the following three irregular situations that are difficult for a design developer to assume in this embodiment.

  The first irregular situation is that the unfolding release button 44k (operation means) is pressed to move the central movable body 401 that is not in the lowered position to the lowered position (the drive mode of the second drive means is changed to the return mode). And the left movable body 510 and the right movable body 560 that are not in the closed position are moved to the closed position. In this case, the central movable body 401, the left movable body 510, and the right movable body 560 move (return) not at the timing assumed by the design developer but at the timing based on the player's intention. For this reason, it is difficult for the design developer to predict what value the peak current of the power supply of the production motor will be, as it may result in a situation where a plurality of unintended motors are simultaneously driven.

  The second irregular situation is when the central movable body 401 to be moved is stopped based on detection by the touch sensor 431 (detection means) (the drive mode of the second drive unit is changed to the stop mode). is there. In this case, the central movable body 401 (elevating motor 310) to be moved stops at a timing when the player or the like touches the touch electrode 430 by carelessness or the like, not at the timing assumed by the design developer. Become. In particular, when the moving movable body (central movable body 401) is suddenly stopped, a large load is applied to the motor (elevating motor 310) due to the back electromotive force, and current consumption tends to increase instantaneously. For this reason, it is difficult for the design developer to predict what value the peak current of the power supply of the production motor will be.

  The third irregular situation is when the movable body that is not at the origin position is moved (returned) to the origin position at the start of the special symbol (design) variation display. In general, in a pachinko gaming machine, the effect is returned to the initial state by the time the special symbol variation display is completed so that the player can grasp the result of the lottery of the special symbol for each time without any discomfort. However, there may be rare cases where the movable body has not returned to the origin position by the time the special symbol variation display is terminated due to a motor failure or an instantaneous power failure. Therefore, in this pachinko gaming machine PY1, the movable body (the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k) is at the origin position (at the start of the special symbol variation display). When not in the lowered position, the closed position, the standby position, or the retracted position, the movable body is returned to the origin position. However, returning the movable body that is not at the origin position to the origin position at the start of the special symbol variation display is extremely irregular for the design developer. It is difficult to predict what the peak current of the power supply will be.

  As described above, when the above-mentioned three irregular situations occur, the possibility that the burden on the power supply board 190 becomes too large instantaneously cannot be completely denied. That is, even if the above three irregular situations occur, the worst case is to ensure that the allowable loss of the power supply board 190 exceeds 280 W and the peak current of DC 37 V exceeds 11 A. There was a need to do.

  Therefore, in this embodiment, in order to deal with the above problem, the production control microcomputer 121 copes as follows. That is, the production control microcomputer 121 has the above three irregular situations, and the peak current of the production motor power supply is 3000 mA or more using the current limit determination table shown in FIG. If it judges, it will control so that an electric current may not be supplied to the frame lamp 212 and the board lamp 54 (LED circuit on the circuit board of the frame lamp 212 and the board lamp 54). That is, control is performed so that the frame lamp 212 and the panel lamp 54 do not emit light. As a result, current consumption in the frame lamp 212 and the panel lamp 54 can be eliminated. As a result, even if the peak current of the power source of the production motor is 3000 mA or more and the above three irregular situations occur, it is possible to suppress the current consumption of the pachinko gaming machine PY1 as a whole. Therefore, it is possible to prevent the burden on the power supply board 190 from becoming too large instantaneously, and to reliably prevent the allowable loss of the power supply board 190 from exceeding 280 W and the peak current of DC37V from exceeding 11 A. Is possible.

5). Explanation of jackpot etc. In the pachinko gaming machine PY1 of this embodiment, there are “big hit” and “off” as a result of the jackpot lottery (special symbol lottery). In the case of “hit”, the “hit symbol” is stopped and displayed on the special figure display 81. In the case of “missing”, the “lost symbol” is stopped and displayed on the special figure display 81. When winning the jackpot, a “hit game” is executed in which the big winning opening 14 is opened with an opening pattern corresponding to the type of special symbol (type of jackpot) displayed in a stopped state. The jackpot game is also called a special game.

  In this embodiment, the jackpot game is a multi-round game (unit-open game), an opening before the first round game is started (also referred to as OP), and an ending after the last round game is completed. (Also expressed as ED). Each round game starts with the end of OP or the end of the previous round game, and ends with the start of the next round game or the start of ED. The closing time (interval time) of the big prize opening between round games is included in the open round game before the closing.

  There are several types of jackpots. The types of jackpots are as shown in FIG. As shown in FIG. 20, there are roughly two types in this embodiment. Probable jackpot and normal jackpot. The probability variation jackpot is a jackpot that controls the gaming state after the jackpot game to a high probability state described later. The normal jackpot is a jackpot that controls the gaming state after the jackpot game to a normal probability state (low probability state) described later.

  More specifically, for the probability variation jackpot and the regular jackpot that can be won in the special drawing 1 lottery (the lottery of the first special symbol), the winning prize opening 14 is opened for a maximum of 29.5 seconds per 1R from 1R to 8R. 9R to 16R are jackpots that open the grand prize winning opening 14 for a maximum of 0.1 second per 1R. That is, the total number of rounds per jackpot is 16R, but the actual number of rounds is 8R. The substantial number of rounds is the number of rounds in which game balls can win up to the maximum number of winnings per round (8 in this embodiment). In these jackpots, from 9R to 16R, the opening time of the grand prize winning opening 14 is extremely short, and it is a round in which no winning ball can be expected. In addition, when “probable jackpot” is won by lottery of special figure 1, “special figure 1_probable symbol” is stopped on the first special figure indicator 81a, and when “normal jackpot” is won, “Special figure 1_normal symbol” is stopped and displayed on the first special figure display 81a.

  Further, the probability variation jackpot and the normal jackpot that can be won in the special drawing 2 lottery (the lottery of the second special symbol) are jackpots that open the grand prize winning opening 14 from 1R to 16R for a maximum of 29.5 seconds per 1R. In other words, these jackpots also have a substantial number of rounds of 16R. When “probability change jackpot” is won by lottery of special figure 2, “special figure 2_probability pattern” is stopped and displayed on the second special figure display 81b, and when “normal jackpot” is won, the second “Special figure 2_normal symbol” is stopped and displayed on the special figure display 81b.

  Regardless of which jackpot is won, after the jackpot game is controlled to the electric support control state (high base state) described later. The electric support control state continues until the next jackpot winning when it is controlled in accordance with the high probability state. On the other hand, when the control is performed in accordance with the normal probability state (low probability state), the number of times of electric support (the number of time reductions) is set to 100 times. The electric support number of times is the upper limit execution number of the special symbol variation display in the electric support control state.

  As shown in FIG. 20, in the lottery of special figure 1 and the lottery of special figure 2, the jackpot allocation rate is 65% for probability variation and 35% for normal jackpot. However, if the jackpot is won based on the lottery of Special Figure 1, a jackpot game with a substantial number of rounds will be executed, whereas if the jackpot is won based on the lottery of Special Figure 2, it will be The lottery of FIG. 2 is set to be more advantageous for the player than the lottery of FIG. 1 in that a big hit game with 16 rounds is executed.

  Here, in this pachinko gaming machine PY1, the lottery for determining whether or not the jackpot is won is performed based on the “big hit random number”, and the winning jackpot type lottery is performed based on the “hit type random number”. As shown in FIG. 21A, the jackpot random number takes a value in the range of 0 to 65535. The hit type random number takes a value in the range of 0 to 99. Note that random numbers acquired based on winning at the first start port 11 or the second start port 12 include “reach random number” and “variation pattern random number” in addition to the big hit random number and the hit type random number.

  The reach random number is a random number that determines whether or not a reach is generated in the effect design variation effect indicating the result when the result of the jackpot determination is out of place. Reach is a state in which there is only one effect symbol that is variably displayed among a plurality of effect symbols, and depending on which symbol the effect symbol that is variably displayed is stopped and displayed, It is a state (for example, a state of “7 ↓ 7”) that is a combination of the production symbols shown. It should be noted that the effect symbols that are stopped and displayed in the reach state may be displayed so as to be slightly shaken in the display screen 50a, or may be displayed so as to repeat the enlargement and reduction. This reach random number takes a value in the range of 0-255.

  The variation pattern random number is a random number for determining a variation pattern including a variation time. The fluctuation pattern random number takes a value in the range of 0 to 99. In addition, the random number acquired based on the passage to the gate 13 includes a normal symbol random number (per random number) shown in FIG. The normal symbol random number is a random number for a lottery (ordinary symbol lottery) to determine whether or not to perform an auxiliary game that opens the electric Chu 12D. The normal symbol random number takes a value in the range of 0 to 65535.

6). Description of the gaming state Next, the gaming state of the pachinko gaming machine PY1 of this embodiment will be described. The special map display 81 and the general map display 82 of the pachinko gaming machine PY1 each have a probability variation function and a variation time shortening function. The state in which the probability variation function of the special figure indicator 81 is activated is referred to as “high probability state”, and the state in which it is not activated is referred to as “normal probability state (non-high probability state)”. In the high probability state, the jackpot probability is higher than in the normal probability state. That is, jackpot determination is performed using a jackpot determination table in which the value of the jackpot random number determined to be a jackpot is larger than the jackpot determination table used in the normal probability state (see FIG. 22A). That is, when the probability variation function of the special symbol display 81 is activated, the probability that the display result (that is, the stop symbol) of the special symbol variable display by the special symbol indicator 81 becomes a jackpot symbol, compared to when the special symbol indicator 81 is not activated. Becomes higher.

  In addition, the state where the variable time shortening function of the special figure indicator 81 is operating is referred to as “time-short state”, and the state where it is not operating is referred to as “non-time-short state”. In the short-time state, the variation time of the special symbol (the time from the start of variation display to the time when the display result is derived and displayed) is shorter than in the non-short-time state. That is, the variation pattern is determined using a variation pattern table that is determined so that the variation pattern having a short variation time is selected more than in the non-time-short state (see FIG. 23). That is, when the fluctuation time shortening function of the special symbol display 81 is activated, it is easy to select a short fluctuation time as the fluctuation time of the variable symbol special display as compared to when the special symbol indicator 81 is not activated. As a result, in the short-time state, the special-patch holding pace is accelerated, and an effective winning (a winning that can be stored as a special-pending hold) at the starting port is likely to occur. Therefore, it is possible to aim for a big hit with smooth progress of the game.

  The probability variation function and variation time shortening function of the special figure indicator 81 may be activated at the same time, or only one of them may be activated. The probability changing function and the changing time shortening function of the general-purpose display 82 are operated in synchronization with the changing time reducing function of the special figure display 81. That is, the probability variation function and the variation time shortening function of the general-purpose display device 82 operate in the short time state and do not operate in the non-short time state. Therefore, in the short time state, the winning probability in the normal symbol lottery is higher than in the non-short time state. In other words, a hit determination (ordinary symbol determination) is performed using a normal symbol per-decision table having more normal symbol random numbers (per hit random) determined to be hit than a normal symbol per-decision table used in a non-time-saving state ( (See FIG. 22C). In other words, when the probability variation function of the general-purpose display 82 is activated, the probability that the display result of the variable display of the normal symbol displayed by the general-purpose display 82 is a normal winning symbol is higher than when the probability variation function is not activated. .

  In the short time state, the normal symbol fluctuation time is shorter than in the non-short time state. In this embodiment, the variation time of the normal symbol is 7 seconds in the non-short-time state, but is 1 second in the short-time state (see FIG. 22D). Furthermore, in the time-saving state, the opening time of the electric Chu 12D in the auxiliary game is longer than that in the non-time-saving state (see FIG. 24). That is, the open time extension function of the electric Chu 12D is activated. In addition, in the short time state, the number of times the electric Chu 12D is opened in the auxiliary game is larger than that in the non-short time state (see FIG. 24). That is, the function for increasing the number of times the electric Chu 12D is opened is activated.

  In the situation where the probability changing function and the changing time shortening function of the general-purpose display 82 and the opening time extending function and the opening frequency increasing function of the electric Chu 12D are operating, these functions are not operated. Thus, the electric chute 12D is frequently opened, and the game balls are frequently won at the second starting port 12. As a result, the base, which is the ratio of the number of prize balls to the number of shot balls, increases. Therefore, a state in which these functions are activated is referred to as a “high base state”, and a state in which these functions are not activated is referred to as a “low base state”. In the high base state, it is possible to aim for a big hit without greatly reducing the hand-held game balls. The high base state is a state in which so-called electric support control (control to support winning to the second starting port 12 by the electric Chu 12D) is being executed. Therefore, the high base state is also referred to as an electric support control state or a ball entry easy state. On the other hand, the low base state is also referred to as a non-electric support control state or a non-ball entering easy state.

  In the high base state, not all the functions described above may operate. That is, the operation of one or more of the probability variation function of the general-purpose display 82, the variation time shortening function of the general-purpose display 82, the opening time extending function of the electric Chu 12D, and the opening frequency increasing function of the electric Chu 12D. Therefore, it is only necessary that the electric chew 12D be opened more easily than when the function is not activated. Further, the high base state may be independently controlled without accompanying the time reduction state.

  In the pachinko gaming machine PY1 of this embodiment, the gaming state after the jackpot game by winning the probability variation jackpot is a high probability state, a short time state, and a high base state. This gaming state is particularly referred to as a “highly accurate base state”. The high-accuracy base state is terminated when a special symbol variable display is executed a predetermined number of times (10000 times in this embodiment), or when the jackpot is won and the jackpot game is executed. In other words, in this embodiment, the highly accurate and high base state is substantially continued until the next jackpot winning. It should be noted that the termination condition for the high-accuracy and high-base state may be determined only by winning the jackpot and executing the jackpot game.

  In addition, the gaming state after the jackpot game by winning the normal jackpot is a normal probability state (a non-high probability state, that is, a low probability state), a short time state, and a high base state. This gaming state is particularly referred to as a “low-accuracy base state”. The low-accuracy base state ends when a special symbol variable display is executed a predetermined number of times (100 times in this embodiment), or when the jackpot is won and the jackpot game is executed.

  When the pachinko gaming machine PY1 is played for the first time, the gaming state after power-on is a normal probability state, a non-time-short state, and a low base state. This gaming state is particularly referred to as a “low probability low base state”. The low probability low base state will be referred to as a “normal game state”. A state in which a special game (a jackpot game) is being executed is referred to as a “special game state (a jackpot game state)”. Furthermore, the state controlled to at least one of the high probability state and the high base state is referred to as a “privilege gaming state”.

  In a high base state such as a high-accuracy high-base state or a low-accuracy high-base state, it is possible to advance the game more advantageously if the game ball is advanced to the right game area 6R (see FIG. 5) by hitting right. This is because the electric chew control makes it easier for the electric chew 12D to be opened compared to the low base state, and it is easier to win the second starting port 12 than to win the first starting port 11. . Therefore, the player makes a right turn to win the game ball to the second starting port 12 while passing the game ball to the gate 13 which is a trigger for the normal symbol lottery. As a result, it is possible to obtain a large number of start prizes (win prizes at the start opening) rather than left-handed. In this pachinko gaming machine PY1, a right-handed game is played even during a big hit game.

  On the other hand, in the low base state, it is possible to advance the game more advantageously by making the game ball enter the left game area 6L (see FIG. 5) by left-handed. Since the electric support control is not executed, the electric chew 12D is less likely to be opened than in the high base state, and it is easier to win the first start port 11 than to win the second start port 12. Because it is. Therefore, a left turn is made to win a game ball in the first starting port 11. As a result, it is possible to obtain a larger number of start prizes than right-handed.

7). Control Operation of Pachinko Game Machine Next, the operation of the game control microcomputer 101 will be described based on FIG. 25, and the operation of the effect control microcomputer 121 will be described based on FIGS. First, the operation of the game control microcomputer 101 will be described.

  [Main-side timer interrupt processing] The game control microcomputer 101 repeats the main-side timer interrupt processing shown in FIG. 25 every short time, for example, 4 msec. First, the game control microcomputer 101 determines a jackpot random number used for the jackpot lottery, a hit type random number for determining the jackpot type, a reach random number for determining whether or not to reach the reach state in the effect design variation effect, and a variation pattern. The random number update process is performed to update the fluctuation pattern random number, the normal symbol random number (per random number) used for the normal symbol lottery (S101). Note that at least a part of each random number may be a so-called hardware random number generated using a known random number generation circuit including a counter IC or the like. If all random numbers are hardware random numbers, no software update process is required. The random number generation circuit may be built in the game control microcomputer 101.

  Next, the game control microcomputer 101 performs input processing (S102). In the input process (S102), various sensors (first start port sensor 11a, second start port sensor 12a, gate sensor 13a, large winning port sensor 14a, general winning port sensor 10a (see FIG. 14)) is detected, and payout data for paying out a winning ball corresponding to the type of winning opening is set in a predetermined storage area of the gaming RAM 104. In the input process (S102), a detection signal from the lower plate full switch for detecting the fullness of the lower plate 35 is also fetched and stored in the output buffer of the game RAM 104 as lower plate full data.

  Subsequently, the game control microcomputer 101 executes a start port sensor detection process (S103), a special operation process (S104), and a normal operation process (S105). In the starting port sensor detection process (S103), if there is a winning detection by the first starting port sensor 11a or the second starting port sensor 12a, it is confirmed that there are less than four reserved memories corresponding to the starting port where the winning is detected. As a condition, a random number such as a big hit random number (a big hit random number, a hit type random number, a reach random number, and a variation pattern random number (see FIG. 21A)) is acquired. If there is passage detection by the gate sensor 13a, a normal symbol random number (see FIG. 21B) is acquired on condition that there are less than four ordinary figure holds.

  In the special operation process (S104), a random number such as a jackpot random number obtained in the start port sensor detection process (S103) is used by using a predetermined determination table (see FIGS. 20, 22A, 23B, and 23). judge. And the special symbol display (variation display and stop display) for showing the result of the jackpot lottery is performed. At the start of the special symbol variation display (immediately before the start), a variation start command including variation pattern information is set in a predetermined output buffer of the gaming RAM 104, and at the start of the special symbol stop display (immediately before the start) The variable stop command is set in a predetermined output buffer of the gaming RAM 104. Note that the variation pattern is determined using a special variation pattern determination table shown in FIG. 23 based on determination of various random numbers such as jackpot random numbers. As shown in FIG. 23, when the variation pattern is determined, the variation time during which the special symbol variation display is executed is also determined.

  The SP reach (super reach) shown in the remarks column of FIG. 23 is a reach that has a longer variation time after reach than normal reach. The table allocation ratio is set so that the SP reach is higher in the winning expectation degree (expectation for the big hit win) than in the normal reach. Here, in the SP reach, there are provided types of weak SP reach A, weak SP reach B, and strong SP reach. In order of weak SP reach A ⇒ weak SP reach B ⇒ strong SP reach, the distribution ratios of various fluctuation patterns are set so that the expectation of winning the jackpot increases. When a variation pattern indicating the execution of strong SP reach is selected, the unfolding drive effect (see FIG. 12) by the central upper unit 400 and the opening / closing unit 600 can be executed.

  As a result of the determination of the jackpot random number, if the jackpot is won, a jackpot game (special) that opens the jackpot 14 according to a predetermined opening pattern (opening time and number of times, see FIG. 20) according to the type of jackpot Play). At the start of the jackpot game, an opening command including information on the type of winning jackpot symbol is set in a predetermined storage area of the game RAM 104. The opening command is a command indicating the start of opening. After the big hit game is started, a round designation command is set in a predetermined storage area of the game RAM 104 at the start of the round game, and an ending command is set in a predetermined storage area of the game RAM 104 at the start of the ending. In the special operation process (S104), if no random number such as a big hit random number is stored, a waiting-for-customer command for causing the presentation control microcomputer 121 to execute the waiting-for-customer effect is set.

  In the normal operation process (S105), the normal symbol random number acquired in the start port sensor detection process (S103) is determined using the normal symbol hit determination table (see FIG. 22C). And the normal symbol display (a change display and a stop display) for alerting | reporting the determination result is performed. As a result of the normal symbol random number determination, if the normal winning symbol is won, an auxiliary game that opens the electric chew 12D according to a predetermined opening pattern (opening time and number of times of opening, see FIG. 24) according to the gaming state. Do.

  Next, the game control microcomputer 101 performs an output process (S106) for outputting the command set in each process described above to the effect control board 120 or the like.

  In parallel with the above-described processing in the game control microcomputer 101, the effect control microcomputer 121 performs the processes shown in FIGS. Hereinafter, the operation of the production control microcomputer 121 will be described.

  [Sub-side 1 ms timer interrupt process] The effect control microcomputer 121 repeats the sub-side 1 ms timer interrupt process shown in FIG. The effect control microcomputer 121 executes sub-side 1 ms timer interrupt processing and also executes sub-side 10 ms timer interrupt processing (see FIG. 40) as will be described later. As shown in FIG. 26, in the sub-side 1 ms timer interrupt process, first, an input process is performed (S201). In the input process (S201), switch data (edge data and level data) is created based on detection signals from the input unit detection sensor 40a, the select button detection sensor 42a, and the undeployment button detection sensor 44a (see FIG. 15).

  Subsequently, drive control processing to be described later is performed (S202). The drive control process (S202) controls the driving of various motors (elevating motor 310, upper left motor 531, upper right motor 581, character moving motor 58, ball left / right moving motor 92, ball up / down moving motor 94). This is a process for moving the movable bodies (the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k). Next, a ramp data output process described later is performed (S203). The lamp data output process (S203) is a process of outputting lamp data for causing the frame lamp 212, the panel lamp 54, and the contact notification lamp 432 to emit light. The lamp data is set in the effect RAM 124 for waiting for the customer when the power is turned on, or is set in the effect RAM 124 in accordance with the changing effect pattern. Then, the watchdog timer process (S204) for resetting the watchdog timer is performed, and this process is finished.

  [Driving Control Process] As shown in FIG. 27, in the driving control process (S202), the production control microcomputer 121 performs a central movable body drive control process (S301), a left movable body drive control process (S302), and a right side. A movable body drive control process (S303), a character movable body drive control process (S304), and a ball movable body drive control process (S305) are executed.

  [Central Movable Body Drive Control Process] As shown in FIG. 28, in the central movable body drive control process (S301), the production control microcomputer 121 first moves the central movable body 401 to the production RAM 124 to move the central movable body 401. It is determined whether or not body drive data is set (S401). If it is not set (NO in S401), it is not necessary to perform drive control of the elevating motor 310, and thus this process ends (see FIG. 29). On the other hand, if it is set (YES in S401), it is determined whether or not it is time to move the central movable body 401 based on the central movable body drive data (S402). If it is not time to move (NO in S402), the process proceeds to step S408. On the other hand, if it is the timing to move (YES in S402), the current limit determination table shown in FIG. 19 is referred to (S403).

  Then, based on the current limit determination table, it is determined whether or not the peak current of the power source of the production motor is 3000 mA or more (S404). For example, the production control microcomputer 121 moves the central movable body 401 (drives the lift motor 310), and includes an upper left motor 531, an upper right motor 581, a character movement motor 58, a ball left / right movement motor 92, and a ball up / down movement. If the moving motor 94 is already driven, it is determined that the driving pattern 1 is set. Then, based on the current limit determination table shown in FIG. 19, if the drive pattern is 1, it is determined that the peak current of the power supply of the production motor is 3000 mA or more.

  If it is determined that the peak current of the power supply of the production motor is 3000 mA or more (YES in S404), the first low current drive flag is turned on (S405), and the process proceeds to step S406. The first low current drive flag is a flag indicating that the peak current of the power source of the production motor is 3000 mA or more based on the movement of the central movable body 401 (drive of the lifting motor 310). That is, the first low current drive flag is a flag indicating that the current supplied to the frame lamp 212 and the panel lamp 54 is reduced by the movement of the central movable body 401. Here, in this embodiment, the frame lamp 212 and the panel lamp 54 correspond to “specific drive means” or “first drive means”, and the central movable body 401 and the lifting motor are “other drive means” or “second drive means”. Is equivalent to. In step S406, a delay drive process for slightly delaying the start of driving of the lift motor 310 is executed, and the process proceeds to step S408.

  Here, the delay drive process (S406) is a process for moving the central movable body 401 based on the central movable body drive data after the current limitation on the frame lamp 212 and the panel lamp 54 is started. That is, if the movement of the central movable body 401 (drive of the lifting motor 310) is started before the current limitation on the frame lamp 212 and the panel lamp 54 is started, the peak current of the power supply of the production motor becomes 3000 mA or more. This situation can occur. Therefore, in this embodiment, the start of the drive of the lifting motor 310 is slightly delayed (for example, 100 ms), so that the movement of the central movable body 401 (the lifting motor 310 of the lifting motor 310 is started) before the current limitation on the frame lamp 212 and the panel lamp 54 is started. (Driving) can be prevented from starting.

  On the other hand, if it is determined in step S404 that the peak current of the power supply of the production motor is less than 3000 mA (NO in S404), a drive process for moving the central movable body 401 is executed based on the central movable body drive data. The process proceeds to step S408. That is, if the peak current of the power supply for the production motor is less than 3000 mA, the driving of the lifting motor 310 is immediately started without executing the delay driving process (S406).

  In step S408, it is determined whether or not the central movable body 401 is in the lowered position. If it is in the lowered position (YES in S408), the process proceeds to step S413 shown in FIG. On the other hand, if it is not in the lowered position (NO in S408), it is subsequently determined whether or not the deployment release button detection sensor is ON (S409). If it is not ON (NO in S409), it means that the development cancel button 44k has not been pressed, and the process proceeds to step S413 shown in FIG. On the other hand, if it is ON (YES in S409), the lowering driving process for returning the central movable body 401 not in the lowered position to the lowered position is executed (S410). That is, the lifting motor 310 is driven so that the central movable body 401 returns to the lowered position.

  Subsequently, based on the current limit determination table shown in FIG. 19, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S411). At this time, since the central movable body 401 returns to the lowered position, the drive pattern is determined on the assumption that the central movable body 401 moves (the lifting motor 310 is driven) in the current limit determination table shown in FIG.

  If it is not determined in step S411 that the situation is 3000 mA or more (NO in S411), the process proceeds to step S413 shown in FIG. On the other hand, if it is determined that the situation is 3000 mA or more (YES in S411), the first no-current flag is turned ON (S412), and the process proceeds to step S413 shown in FIG. The first no-current flag is a flag indicating that no current is supplied to the frame lamp 212 and the panel lamp 54 based on the movement of the central movable body 401 (drive of the elevating motor 310). Thus, the first irregular situation (a situation where the unfolding release button 44k is pressed and the central movable body 401 returns to the lowered position) occurs, and the peak current of the power supply of the production motor is 3000 mA or more. In this case, it is possible to control so that no current is supplied to the frame lamp 212 and the panel lamp 54.

  As shown in FIG. 29, in step S413, it is determined whether or not the touch sensor 431 is ON. That is, it is determined whether or not the touch electrode 430 is in contact with a human body. If not ON (NO in S413), the process proceeds to step S418. On the other hand, if it is ON (YES in S413), a stop drive process for preventing the central movable body 401 from moving is executed (S414), and the process proceeds to step S415. That is, control is performed so that the lifting motor 310 is not driven.

  Then, it is determined whether or not the central movable body 401 is moving from the lowered position to the raised position, or moved from the raised position to the lowered position (S415). If central movable body 401 is not moving (NO in S415), the process proceeds to step S418. On the other hand, if the central movable body 401 is moving (YES in S415), based on the current limit determination table shown in FIG. Is determined (S416). At this time, since the central movable body 401 is suddenly stopped from the moving state, a large load is applied to the lifting motor 310. Therefore, in the current limit determination table shown in FIG. 19, the drive pattern is determined on the assumption that the elevating motor 310 is driven.

  If it is not determined in step S416 that the situation is 3000 mA or more (NO in S416), the process proceeds to step S418. On the other hand, if it is determined that the situation is 3000 mA or more (YES in S416), the first no-current flag is turned on (S417), and the process proceeds to step S418. Thus, in the case where the second irregular situation (a situation where the central movable body 401 comes into contact with the touch electrode 430 and stops) and the peak current of the power source of the production motor is 3000 mA or more, It is possible to control so that no current is supplied to the lamp 212 and the panel lamp 54.

  In step S418, it is determined whether or not the central movable body forced return flag is ON. The central movable body forced return flag is a flag indicating that the central movable body 401 is forcibly returned to the lowered position because the central movable body 401 is not in the lowered position at the start of the special symbol variation display. The central movable body forced return flag is turned ON in step S1302 (see FIG. 43) described later. If the central movable body forced return flag is not ON (NO in S418), the process proceeds to step S423.

  On the other hand, if the central movable body forced return flag is ON (YES in S418), a forced return process for returning the central movable body 401 not in the lowered position to the lowered position is executed (S419). That is, the lifting motor 310 is driven so that the central movable body 401 returns to the lowered position. Then, the central movable body forced return flag is turned OFF (S420). Subsequently, based on the current limit determination table shown in FIG. 19, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S421). At this time, since the central movable body 401 returns to the lowered position, the drive pattern is determined on the assumption that the central movable body 401 moves (the lifting motor 310 is driven) in the current limit determination table shown in FIG.

  If it is not determined in step S421 that the situation is 3000 mA or more (NO in S421), the process proceeds to step S423. On the other hand, if it is determined that the situation is 3000 mA or more (YES in S421), the first no-current flag is turned on (S422), and the process proceeds to step S423. Thus, when the third irregular situation (a situation where the central movable body 401 returns to the lowered position at the start of fluctuation) occurs and the peak current of the power supply of the production motor is 3000 mA or more, the frame lamp It is possible to control so that no current is supplied to 212 and the panel lamp 54.

  In step S423, it is determined whether or not the central movable body 401 has returned to the lowered position. If the situation does not return to the lowered position (NO in S423), the process is terminated. On the other hand, if the state returns to the lowered position (YES in S423), the central movable body drive data set in the effect RAM 124 is reset (S424). Subsequently, the first low current drive flag is turned off (S425), the first no-current flag is turned off (S426), and the process is terminated.

  [Left Movable Body Drive Control Process] As shown in FIG. 30, in the left movable body drive control process (S302), the effect control microcomputer 121 first moves the left movable object 510 to the effect RAM 124 to move the left movable object 510. It is determined whether or not body drive data is set (S501). If it is not set (NO in S501), it is not necessary to perform drive control of the upper left motor 531 and the present process is terminated (see FIG. 31). On the other hand, if it is set (YES in S501), it is determined whether or not it is time to move the left movable body 510 based on the left movable body drive data (S502). If it is not time to move (NO in S502), the process proceeds to step S508. On the other hand, if it is the timing to move (YES in S502), the current limit determination table shown in FIG. 19 is referred to (S503).

  Then, based on the current limit determination table, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S504). For example, the production control microcomputer 121 moves the left movable body 510 (drives the upper left motor 531), and the upper right motor 581, the character moving motor 58, the ball left / right moving motor 92, and the ball up / down moving motor 94, Is already driven, it is determined that the driving pattern 2 is present. Then, based on the current limit determination table shown in FIG. 19, if the driving pattern is 2, the peak current of the power supply for the production motor is determined to be less than 3000 mA.

  If it is determined that the peak current of the power supply of the production motor is 3000 mA or more (YES in S504), the second low current drive flag is turned on (S505), and the process proceeds to step S506. The second low current drive flag is a flag indicating that the peak current of the power source of the production motor is 3000 mA or more based on the movement of the left movable body 510 (drive of the upper left motor 531). That is, the second low current drive flag is a flag indicating that the current supplied to the frame lamp 212 and the panel lamp 54 is reduced by the movement of the left movable body 510.

  In step S506, a delay driving process for slightly delaying the start of driving of the upper left motor 531 is executed, and the process proceeds to step S508. This delay drive process (S506) is a process for moving the left movable body 510 based on the left movable body drive data after the current limitation on the frame lamp 212 and the panel lamp 54 is started. In this way, in this embodiment, the start of driving of the upper left motor 531 is slightly delayed (for example, 100 ms), so that the left movable body 510 moves (upper left motor) before the current limitation on the frame lamp 212 and the panel lamp 54 is started. It is possible to avoid that the peak current of the power supply of the production motor becomes 3000 mA or more.

  On the other hand, if it is determined in step S504 that the peak current of the power supply of the production motor is less than 3000 mA (NO in S504), a drive process for moving the left movable body 510 based on the left movable body drive data is executed. Then (S507), the process proceeds to step S508. That is, if the peak current of the power supply of the production motor is less than 3000 mA, the drive of the upper left motor 531 is immediately started without executing the delay drive process (S506).

  In step S508, it is determined whether left movable body 510 is in the closed position. If it is in the closed position (YES in S508), the process proceeds to step S513 shown in FIG. On the other hand, if it is not in the closed position (NO in S508), it is subsequently determined whether or not the deployment release button detection sensor is ON (S509). If it is not ON (NO in S509), it means that the unfolding release button 44k has not been pressed, and the process proceeds to step S513 shown in FIG. On the other hand, if it is ON (YES in S509), a closing drive process for returning the left movable body 510 not in the closed position to the closed position is executed (S510). That is, the upper left motor 531 is driven so that the left movable body 510 returns to the closed position.

  Subsequently, based on the current limit determination table shown in FIG. 19, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S511). At this time, since the left movable body 510 returns to the closed position, the drive pattern is determined on the assumption that the left movable body 510 moves (the upper left motor 531 is driven) in the current limit determination table shown in FIG. .

  If it is not determined in step S511 that the situation is 3000 mA or more (NO in S511), the process proceeds to step S513 shown in FIG. On the other hand, if it is determined that the situation is 3000 mA or more (YES in S511), the second no-current flag is turned on (S512), and the process proceeds to step S513 shown in FIG. The second no-current flag is a flag indicating that no current is supplied to the frame lamp 212 and the panel lamp 54 based on the movement of the left movable body 510 (drive of the upper left motor 531). Thus, the first irregular situation (a situation in which the unfolding release button 44k is pressed and the left movable body 510 returns to the closed position) occurs, and the peak current of the power supply of the production motor is 3000 mA or more. In this case, it is possible to control so that no current is supplied to the frame lamp 212 and the panel lamp 54.

  As shown in FIG. 31, in step S513, it is determined whether or not the left movable body forced return flag is ON. The left movable body forced return flag is a flag indicating that the left movable body 510 is forcibly returned to the closed position because the left movable body 510 is not in the closed position at the start of the special symbol variation display. The left movable body forced return flag is turned ON in step S1304 (see FIG. 43) described later. If the left movable body forced return flag is not ON (NO in S513), the process proceeds to step S518.

  On the other hand, if the left movable body forced return flag is ON (YES in S513), a forced return process for returning the left movable body 510 not in the closed position to the closed position is executed (S514). That is, the upper left motor 531 is driven so that the left movable body 510 returns to the closed position. Then, the left movable body forced return flag is turned OFF (S515). Subsequently, based on the current limit determination table shown in FIG. 19, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S516). At this time, since the left movable body 510 returns to the closed position, the drive pattern is determined on the assumption that the left movable body 510 moves (the upper left motor 531 is driven) in the current limit determination table shown in FIG. .

  If it is not determined in step S516 that the situation is 3000 mA or more (NO in S516), the process proceeds to step S518. On the other hand, if it is determined that the situation is 3000 mA or more (YES in S516), the second no-current flag is turned on (S517), and the process proceeds to step S518. Thus, when the third irregular situation (the situation where the left movable body 510 returns to the closed position at the start of fluctuation) occurs and the peak current of the power supply of the production motor is 3000 mA or more, the frame lamp It is possible to control so that no current is supplied to 212 and the panel lamp 54.

  In step S518, it is determined whether or not the left movable body 510 has returned to the closed position. If the situation does not return to the closed position (NO in S518), the process ends. On the other hand, if the situation returns to the closed position (YES in S518), the left movable body drive data set in the effect RAM 124 is reset (S519). Subsequently, the second low current drive flag is turned off (S520), the second no-current flag is turned off (S521), and this process is finished.

  [Right Movable Body Drive Control Process] As shown in FIG. 32, in the right movable body drive control process (S303), the effect control microcomputer 121 first moves the right movable object 560 to the effect RAM 124 to move the right movable object 560. It is determined whether or not body driving data is set (S601). If it is not set (NO in S601), it is not necessary to perform drive control of the upper right motor 581, and thus this process ends (see FIG. 33). On the other hand, if it is set (YES in S601), it is determined whether or not it is time to move the right movable body 560 based on the right movable body drive data (S602). If it is not time to move (NO in S602), the process proceeds to step S608. On the other hand, if it is the timing to move (YES in S602), the current limit determination table shown in FIG. 19 is referred to (S603).

  Then, based on the current limit determination table, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S604). For example, the production control microcomputer 121 moves the right movable body 560 (drives the upper right motor 581), and the lifting motor 310, the character moving motor 58, the ball left / right moving motor 92, and the ball up / down moving motor 94 are If it is already in a driving state, it is determined that the driving pattern 3 is present. Then, based on the current limit determination table shown in FIG. 19, if the driving pattern is 3, it is determined that the peak current of the power source of the production motor is 3000 mA or more.

  If it is determined that the peak current of the power supply of the production motor is 3000 mA or more (YES in S604), the third low current drive flag is turned on (S605), and the process proceeds to step S606. The third low current drive flag is a flag indicating that the peak current of the power supply of the production motor is 3000 mA or more based on the movement of the right movable body 560 (drive of the upper right motor 581). That is, the third low current drive flag is a flag indicating that the current supplied to the frame lamp 212 and the panel lamp 54 is reduced by the movement of the right movable body 560.

  In step S606, a delay drive process for slightly delaying the start of driving of the upper right motor 581 is executed, and the process proceeds to step S608. This delay drive process (S606) is a process for moving the right movable body 560 based on the right movable body drive data after the current limitation on the frame lamp 212 and the panel lamp 54 is started. In this way, in this embodiment, the start of driving of the upper right motor 581 is slightly delayed (for example, 100 ms), so that the right movable body 560 is moved (upper right motor) before the current limitation on the frame lamp 212 and the panel lamp 54 is started. It is possible to avoid that the peak current of the power source of the production motor becomes 3000 mA or more.

  On the other hand, if it is determined in step S604 that the peak current of the power supply of the production motor is less than 3000 mA (NO in S604), a drive process for moving the right movable body 560 based on the right movable body drive data is executed. Then (S607), the process proceeds to step S608. That is, if the peak current of the power supply of the production motor is less than 3000 mA, the right upper motor 581 is immediately started without executing the delay drive process (S606).

  In step S608, it is determined whether or not the right movable body 560 is in the closed position. If it is in the closed position (YES in S608), the process proceeds to step S613 shown in FIG. On the other hand, if it is not in the closed position (NO in S608), it is subsequently determined whether or not the deployment release button detection sensor is ON (S609). If it is not ON (NO in S609), it means that the unfolding release button 44k has not been pressed, and the process proceeds to step S613 shown in FIG. On the other hand, if it is ON (YES in S609), a closing drive process for returning the right movable body 560 not in the closed position to the closed position is executed (S610). That is, the upper right motor 581 is driven so that the right movable body 560 returns to the closed position.

  Subsequently, based on the current limit determination table shown in FIG. 19, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S611). At this time, since the right movable body 560 returns to the closed position, the drive pattern is determined on the assumption that the right movable body 560 moves (the upper right motor 581 is driven) in the current limit determination table shown in FIG. .

  If it is not determined in step S611 that the situation is 3000 mA or more (NO in S611), the process proceeds to step S613 shown in FIG. On the other hand, if it is determined that the situation is 3000 mA or more (YES in S611), the third no-current flag is turned on (S612), and the process proceeds to step S613 shown in FIG. The third no-current flag is a flag indicating that no current is supplied to the frame lamp 212 and the panel lamp 54 based on the movement of the right movable body 560 (driving the upper right motor 581). Thus, the first irregular situation (a situation in which the unfolding release button 44k is pressed and the right movable body 560 returns to the closed position) occurs, and the peak current of the power supply of the production motor is 3000 mA or more. In this case, it is possible to control so that no current is supplied to the frame lamp 212 and the panel lamp 54.

  As shown in FIG. 33, in step S613, it is determined whether or not the right movable body forced return flag is ON. The left movable body forced return flag is a flag indicating that the right movable body 560 is forcibly returned to the closed position when the right movable body 560 is not in the closed position at the start of the special symbol variation display. The right movable body forced return flag is turned ON in step S1306 (see FIG. 43) described later. If the right movable body forced return flag is not ON (NO in S613), the process proceeds to step S618.

  On the other hand, if the right movable body forced return flag is ON (YES in S613), a forced return process for returning the right movable body 560 not in the closed position to the closed position is executed (S614). That is, the upper right motor 581 is driven so that the right movable body 560 returns to the closed position. Then, the right movable body forced return flag is turned OFF (S615). Subsequently, based on the current limit determination table shown in FIG. 19, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S616). At this time, since the right movable body 560 returns to the closed position, the drive pattern is determined on the assumption that the right movable body 560 moves (the upper right motor 581 is driven) in the current limit determination table shown in FIG. .

  If it is not determined in step S616 that the situation is 3000 mA or more (NO in S616), the process proceeds to step S618. On the other hand, if it is determined that the situation is 3000 mA or more (YES in S616), the third no-current flag is turned on (S617), and the process proceeds to step S618. Thus, when the third irregular situation (the situation where the right movable body 560 returns to the closed position at the start of fluctuation) occurs and the peak current of the power supply of the production motor is 3000 mA or more, the frame lamp It is possible to control so that no current is supplied to 212 and the panel lamp 54.

  In step S618, it is determined whether or not the right movable body 560 has returned to the closed position. If the situation does not return to the closed position (NO in S618), the process ends. On the other hand, if the situation returns to the closed position (YES in S618), the right movable body drive data set in the effect RAM 124 is reset (S619). Subsequently, the third low current drive flag is turned off (S620), the third no-current flag is turned off (S621), and this process is finished.

  [Character movable body drive control process] As shown in FIG. 34, in the character movable body drive control process (S304), the effect control microcomputer 121 first moves the character movable body 55k to the effect RAM 124 to move the character movable body 55k. It is determined whether or not body drive data is set (S701). If it is not set (NO in S701), it is not necessary to perform drive control of the character moving motor 58, so this processing is terminated (see FIG. 35). On the other hand, if it is set (YES in S701), it is determined whether or not it is time to move the character movable body 55k based on the character movable body drive data (S702). If it is not time to move (NO in S702), the process proceeds to step S708 shown in FIG. On the other hand, if it is the timing to move (YES in S702), the current limit determination table shown in FIG. 19 is referred to (S703).

  Then, based on the current limit determination table, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S704). For example, the effect control microcomputer 121 moves the character movable body 55k (drives the character movement motor 58), and includes a lift motor 310, a left upper motor 531, a ball left / right movement motor 92, and a ball vertical movement motor 94. If it is already in the driving state, it is determined that the driving pattern 4 is present. Then, based on the current limit determination table shown in FIG. 19, if the drive pattern is 4, it is determined that the peak current of the power source of the production motor is 3000 mA or more.

  If it is determined that the peak current of the power supply of the production motor is 3000 mA or more (YES in S704), the fourth low current drive flag is turned on (S705), and the process proceeds to step S706. The fourth low current drive flag is a flag indicating that the peak current of the power source of the production motor is 3000 mA or more based on the movement of the character movable body 55k (drive of the character movement motor 58). That is, the fourth low current drive flag is a flag indicating that the current supplied to the frame lamp 212 and the panel lamp 54 is reduced by the movement of the character movable body 55k.

  In step S706, a delay drive process for slightly delaying the start of driving of the character moving motor 58 is executed, and the process proceeds to step S708 shown in FIG. This delay drive process (S706) is a process for moving the character movable body 55k based on the character movable body drive data after the current limitation on the frame lamp 212 and the panel lamp 54 is started. Thus, in this embodiment, the start of driving of the character moving motor 58 is slightly delayed (for example, 100 ms), so that the character movable body 55k is moved (character moving motor) before the current limitation on the frame lamp 212 and the panel lamp 54 is started. It is possible to avoid that the peak current of the power source of the production motor becomes 3000 mA or more.

  On the other hand, if it is determined in step S704 that the peak current of the power supply of the production motor is less than 3000 mA (NO in S704), a drive process for moving the character movable body 55k based on the character movable body drive data is executed. The process proceeds to step S708 shown in FIG. That is, if the peak current of the power supply of the production motor is less than 3000 mA, the drive of the character moving motor 58 is immediately started without executing the delay drive process (S706).

  As shown in FIG. 35, in step S708, it is determined whether or not the character movable body forced return flag is ON. The character movable body forced return flag is a flag indicating that the character movable body 55k is forcibly returned to the standby position when the character movable body 55k is not in the standby position at the start of the special symbol variation display. The character movable body forced return flag is turned on in step S1308 (see FIG. 43) described later. If the character movable body forced return flag is not ON (NO in S708), the process proceeds to step S713.

  On the other hand, if the character movable body forced return flag is ON (YES in S708), a forced return process for returning the character movable body 55k that is not in the standby position to the standby position is executed (S709). That is, the character moving motor 58 is driven so that the character movable body 55k returns to the standby position. Then, the character movable body forced return flag is turned OFF (S710). Subsequently, based on the current limit determination table shown in FIG. 19, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S711). At this time, since the character movable body 55k returns to the standby position, the driving pattern is determined on the assumption that the character movable body 55k moves (the character moving motor 58 is driven) in the current limit determination table shown in FIG. .

  If it is not determined in step S711 that the situation is 3000 mA or more (NO in S711), the process proceeds to step S713. On the other hand, if it is determined that the situation is 3000 mA or more (YES in S711), the fourth no-current flag is turned ON (S712), and the process proceeds to step S713. The fourth no-current flag is a flag indicating that no current is supplied to the frame lamp 212 and the panel lamp 54 based on the movement of the character movable body 55k (the driving of the character moving motor 58). Thus, when the third irregular situation (the situation where the character movable body 55k returns to the standby position at the start of the fluctuation) occurs and the peak current of the power supply of the production motor is 3000 mA or more, the frame lamp It is possible to control so that no current is supplied to 212 and the panel lamp 54.

  In step S713, it is determined whether or not the character movable body 55k has returned to the standby position. If the situation has not returned to the standby position (NO in S713), the process is terminated. On the other hand, if the situation returns to the standby position (YES in S713), the character movable body drive data set in the effect RAM 124 is reset (S714). Subsequently, the fourth low current drive flag is turned off (S715), the fourth no-current flag is turned off (S716), and this process is finished.

  [Ball Movable Body Drive Control Process] As shown in FIG. 36, in the ball movable body drive control process (S305), the effect control microcomputer 121 first moves the ball movable body 56k to the effect RAM 124 to move the ball movable body 56k. It is determined whether or not body drive data is set (S801). If it is not set (NO in S801), it is not necessary to perform drive control on either the ball left / right moving motor 92 or the ball up / down moving motor 94, and thus this processing ends (see FIG. 37). On the other hand, if it is set (YES in S801), it is determined whether it is time to move the ball movable body 56k based on the ball movable body drive data (S802). If it is not time to move (NO in S802), the process proceeds to step S808 shown in FIG. On the other hand, if it is the timing to move (YES in S802), the current limit determination table shown in FIG. 19 is referred to (S803).

  Then, based on the current limit determination table, it is determined whether or not the peak current of the power supply for the production motor is 3000 mA or more (S804). For example, the production control microcomputer 121 moves the ball movable body 56k (drives both the ball left / right moving motor 92 and the ball up / down moving motor 94), and includes a lift motor 310, an upper left motor 531 and an upper right motor 581. Are already driven, it is determined that the driving pattern 5 is present. Then, based on the current limit determination table shown in FIG. 19, if the drive pattern is 5, it is determined that the peak current of the power source of the production motor is 3000 mA or more.

  If it is determined that the peak current of the power supply of the production motor is 3000 mA or more (YES in S804), the fifth low current drive flag is turned on (S805), and the process proceeds to step S806. The fifth low current drive flag indicates that the peak current of the power supply for the production motor is 3000 mA or more based on the movement of the ball movable body 56k (driving at least one of the ball horizontal movement motor 92 or the ball vertical movement motor 94). It is a flag which shows. That is, the fifth low current drive flag is a flag indicating that the current supplied to the frame lamp 212 and the panel lamp 54 is reduced by the movement of the ball movable body 56k.

  In step S806, a delay drive process for slightly delaying the start of driving of the ball horizontal movement motor 92 and the ball vertical movement motor 94 is executed, and the process proceeds to step S808 shown in FIG. This delay drive process (S806) is a process for moving the ball movable body 56k based on the ball movable body drive data after the current limitation on the frame lamp 212 and the panel lamp 54 is started. In this way, in this embodiment, the start of driving of the ball left / right moving motor 92 and the ball up / down moving motor 94 is slightly delayed (for example, 100 ms), so that the ball movable body is started before the current limitation on the frame lamp 212 and the panel lamp 54 is started. It is possible to avoid the 56k movement (driving the ball left / right movement motor 92 and the ball vertical movement motor 94) being started, and the peak current of the power supply of the production motor to be 3000 mA or more.

  On the other hand, if it is determined in step S804 that the peak current of the power supply of the production motor is less than 3000 mA (NO in S804), a drive process for moving the ball movable body 56k is executed based on the ball movable body drive data. Then (S807), the process proceeds to step S808 shown in FIG. That is, if the peak current of the power source of the production motor is less than 3000 mA, both the ball left / right movement motor 92 and the ball vertical movement motor 94, or the ball left / right movement motor 92 or Immediately start driving one of the ball vertical movement motors 94.

  As shown in FIG. 37, in step S808, it is determined whether or not the ball movable body forced return flag is ON. The ball movable body forced return flag is a flag indicating that the ball movable body 56k is forcibly returned to the retracted position because the ball movable body 56k is not in the retracted position at the start of the special symbol variation display. The ball movable body forced return flag is turned ON in step S1310 (see FIG. 43) described later. If the ball movable body forced return flag is not ON (NO in S808), the process proceeds to step S813.

  On the other hand, if the ball movable body forced return flag is ON (YES in S808), a forced return process for returning the ball movable body 56k that is not in the retracted position to the retracted position is executed (S809). That is, at least one of the ball left / right movement motor 92 and the ball vertical movement motor 94 is driven so that the ball movable body 56k returns to the retracted position. Then, the ball movable body forced return flag is turned OFF (S810). Subsequently, based on the current limit determination table shown in FIG. 19, it is determined whether or not the peak current of the power supply of the production motor is 3000 mA or more (S811). At this time, since the ball movable body 56k returns to the retracted position, in the current limit determination table shown in FIG. 19, the ball horizontal movement motor 92 and the ball vertical movement motor 94 are changed according to the direction in which the ball movable body 56k is moved. The drive pattern is determined on the assumption that both are driven or one of the ball horizontal movement motor 92 and the ball vertical movement motor 94 is driven.

  If it is not determined in step S811 that the situation is 3000 mA or more (NO in S811), the process proceeds to step S813. On the other hand, if it is determined that the situation is 3000 mA or more (YES in S811), the fifth no-current flag is turned on (S812), and the process proceeds to step S813. The fifth no-current flag indicates that no current is supplied to the frame lamp 212 and the panel lamp 54 based on the movement of the ball movable body 56k (at least one drive of the ball horizontal movement motor 92 or the ball vertical movement motor 94). It is a flag to show. Thus, when the third irregular situation (the situation where the ball movable body 56k returns to the retracted position at the start of the fluctuation) occurs and the peak current of the power source of the production motor is 3000 mA or more, the frame lamp It is possible to control so that no current is supplied to 212 and the panel lamp 54.

  In step S813, it is determined whether or not the ball movable body 56k has returned to the retracted position. If it is not in the state of returning to the retreat position (NO in S813), this process is finished. On the other hand, if the situation returns to the retracted position (YES in S813), the ball movable body drive data set in the effect RAM 124 is reset (S814). Subsequently, the fifth low current drive flag is turned off (S815), the fifth no-current flag is turned off (S816), and the process is terminated.

  [Ramp Data Output Process] As shown in FIG. 38, in the lamp data output process (S203), the effect control microcomputer 121 sets the frame lamp data based on the fact that the frame lamp data is set in the effect RAM 124. It is determined whether or not it is the timing to output to the sub drive board 162. The frame lamp data is data for causing the frame lamp 212 to emit light. If the determination result of step S901 is NO, the process proceeds to step S907. On the other hand, if the decision result in the step S901 is YES, it is subsequently decided whether or not all non-current flags are OFF (S902). That is, it is determined whether or not all of the first no-current flag, the second no-current flag, the third no-current flag, the fourth no-current flag, and the fifth no-current flag are OFF. All the no-current flags are not OFF (NO in S902), that is, any one of the first no-current flag, the second no-current flag, the third no-current flag, the fourth no-current flag, and the fifth no-current flag. If it is ON, the process proceeds to step S906.

  In step S906, a frame lamp no-current process in which no current is supplied to the frame lamp 212 (LED circuit on the LED substrate) is executed (S906), and the process proceeds to step S907. Specifically, in the frame lamp no-current process (S906), the effect control microcomputer 121 does not output the frame lamp data to the sub drive board 162 even though the frame lamp data is set in the effect RAM 124. Then, a drive stop signal is output to the sub drive board 162. As a result, the sub drive board 162 performs control so that no current is supplied to the LED circuit of the LED board on which the frame lamp 212 (LED) is mounted. Thus, when the first to third irregular situations occur and the peak current of the power supply of the production motor is 3000 mA or more, consumption by the frame lamp 212 by the frame lamp no-current process (S906). The current can be eliminated, and the burden on the power supply board 190 can be greatly reduced.

  If all the no-current flags are OFF in step S902 (YES in S902), it is subsequently determined whether all the low-current drive flags are OFF (S903). That is, it is determined whether or not all of the first low current drive flag, the second low current drive flag, the third low current drive flag, the fourth low current drive flag, and the fifth low current drive flag are OFF. The low current drive flags are not all OFF (NO in S903), that is, the first low current drive flag, the second low current drive flag, the third low current drive flag, the fourth low current drive flag, and the fifth low current drive flag. If any one of them is ON, the process proceeds to step S905.

  In step S905, low current frame lamp data output processing is performed to make the current supplied to the frame lamp 212 a current of 25% (S905), and the process proceeds to step S907. Specifically, in the low current frame lamp data output process (S905), low current frame lamp data is generated based on the frame lamp data set in the effect RAM 124. The low-current frame lamp data generated at this time is such that the current supplied to the frame lamp 212 is 25% of the current (normal current) based on the frame lamp data set in the effect RAM 124. Is. The effect control microcomputer 121 outputs the low current frame lamp data generated in this way to the sub drive board 162. As a result, the sub drive board 162 controls the current supplied to the LED circuit of the LED board on which the frame lamp 212 (LED) is mounted based on the low current frame lamp data to be 25%. . Thus, although the first to third irregular situations have not occurred, the frame lamp is output by the low current frame lamp data output process (S905) in the situation where the peak current of the power source of the production motor is 3000 mA or more. The current consumption by 212 can be reduced, and the burden on the power supply board 190 can be reduced.

  If all the low current drive flags are OFF in step S903 (YES in S903), frame lamp data output processing is executed (S904), and the process proceeds to step S907. Specifically, in the frame lamp data output process (S904), the effect control microcomputer 121 outputs the frame lamp data set in the effect RAM 124 to the sub-drive board 162 as usual. As a result, the sub drive board 162 can supply current to the LED circuit of the LED board on which the frame lamp 212 (LED) is mounted based on the frame lamp data, so that the frame lamp 212 can emit light as usual. is there.

  In step S907, the effect control microcomputer 121 determines whether it is time to output the panel lamp data to the sub drive board 162 based on the fact that the panel lamp data is set in the effect RAM 124. The panel lamp data is data for causing the panel lamp 54 to emit light. If the determination result of step S907 is NO, the process proceeds to step S913 shown in FIG. On the other hand, if the decision result in the step S907 is YES, it is subsequently decided whether or not all the no-current flags are OFF (S908). None of the no-current flags are OFF (NO in S908), that is, any one of the first no-current flag, the second no-current flag, the third no-current flag, the fourth no-current flag, and the fifth no-current flag. If it is ON, the process proceeds to step S912.

  In step S912, a panel lamp no-current process in which no current is supplied to the panel lamp 54 (LED circuit of the LED substrate) is executed (S912), and the process proceeds to step S913 shown in FIG. Specifically, in the panel lamp no-current process (S912), the effect control microcomputer 121 does not output the panel lamp data to the sub drive board 162 even though the panel lamp data is set in the effect RAM 124. Then, a drive stop signal is output to the sub drive board 162. As a result, the sub drive board 162 performs control so that no current is supplied to the LED circuit of the LED board on which the panel lamp 54 (LED) is mounted. Thus, in the situation where the above first to third irregularities occur and the peak current of the power supply of the production motor is 3000 mA or more, the consumption by the panel lamp 54 by the panel lamp no-current process (S912). The current can be eliminated, and the burden on the power supply board 190 can be greatly reduced.

  If all the non-current flags are OFF in step S907 (YES in S908), it is subsequently determined whether or not all the low current drive flags are OFF (S909). The low current drive flags are not all OFF (NO in S909), that is, the first low current drive flag, the second low current drive flag, the third low current drive flag, the fourth low current drive flag, and the fifth low current drive flag. If any one of them is ON, the process proceeds to step S911.

  In step S911, a low-current panel lamp data output process is performed to set the current supplied to the panel lamp 54 to a current of 25% (S911), and the process proceeds to step S913 shown in FIG. Specifically, in the low-current panel lamp data output process (S911), low-current panel lamp data is generated based on the panel lamp data set in the effect RAM 124. The low-current panel lamp data generated at this time is such that the current supplied to the panel lamp 54 is 25% of the current (normal current) based on the panel lamp data set in the effect RAM 124. Is. The effect control microcomputer 121 outputs the low-current panel lamp data generated in this way to the sub drive board 162. Thereby, the sub drive board 162 is controlled so that the current supplied to the LED circuit of the LED board on which the board lamp 54 (LED) is mounted is 25% based on the board lamp data for low current. . Thus, in the situation where the above first to third irregularities have not occurred but the peak current of the power supply of the production motor is 3000 mA or more, the panel lamp is output by the low current panel lamp data output process (S911). 54 can reduce current consumption, and the load on the power supply board 190 can be reduced.

  If all the low current drive flags are OFF in step S909 (YES in S909), the panel lamp data output process is executed (S910), and the process proceeds to step S913 shown in FIG. Specifically, in the panel lamp data output process (S910), the effect control microcomputer 121 outputs the panel lamp data set in the effect RAM 124 to the sub drive board 162 as usual. As a result, the sub drive board 162 can supply current to the LED circuit of the LED board on which the board lamp 54 (LED) is mounted based on the board lamp data, so that the board lamp 54 can emit light as usual. is there.

  As shown in FIG. 39, in step S913, it is determined whether or not the touch sensor 431 is ON. That is, it is determined whether or not the human body is in contact with the touch electrode 430. If the touch sensor 431 is not ON (NO in S913), this process is terminated. On the other hand, if the touch sensor is ON (YES in S914), the output process of the contact notification lamp data is executed (S914), and this process is finished. Specifically, in the contact notification lamp data output process (S914), the effect control microcomputer 121 reads the contact notification lamp data from the effect ROM 123 and outputs it to the sub-drive board 162. Thereby, the sub drive substrate 162 can cause the contact notification lamp 432 to emit light in a specific light emission mode based on the contact notification lamp data.

  In this way, the contact notification lamp 432 emits light in a specific light emission mode, so that it is possible to make the player or the like more aware of being in contact with the touch electrode 430. Here, as long as the human body is in contact with the touch electrode 430, the contact notification lamp 432 always emits light in a specific light emission mode, and does not emit light in a light emission mode darker than the specific light emission mode, or does not turn off. . In other words, unlike the case of the frame lamp 212 and the panel lamp 54, the contact notification lamp 432 is not limited in current even if the peak current of the power supply of the production motor is 3000 mA or more.

  This is because the contact notification lamp 432 has a very small number of LEDs compared to the frame lamp 212 and the panel lamp 54, and even if the current limit is applied to the contact notification lamp 432, the contact notification lamp 432 is not connected to the power supply board 190. This is because the burden reduction is small. As described above, in this embodiment, even if the peak current of the power supply of the production motor is 3000 mA or more, current is not limited for all the lamps, and the number of LEDs among the pachinko gaming machines PY1 is large. The current is limited only to the (frame lamp 212 and panel lamp 54).

  By the way, in this embodiment, when the first irregular situation occurs (the unfolding release button 44k is pressed, the central movable body 401, the left movable body 510, and the right movable body 560 have their respective origin positions (lowering positions). When the peak current of the power of the production motor is 3000 mA or more, no current is supplied to the frame lamp 212 and the panel lamp 54, and the frame lamp 212 and the panel lamp 54 emit light. Disappear. However, the state in which the frame lamp 212 and the panel lamp 54 do not emit light does not continue for a long time. That is, if the central movable body 401, the left movable body 510, and the right movable body 560 return to their respective origin positions (downward position, closed position), the first no-current flag, the second no-current flag, and the third no-current flag. Are turned off (see steps S426, S521, S621), and the first low current drive flag, the second low current drive flag, and the third low current drive flag are turned off (steps S425, S520, S620). reference). As a result, the current limitation on the frame lamp 212 and the panel lamp 54 is released (YES is determined in steps S902, S903, S908, and S909), and the frame lamp 212 and the panel lamp 54 can be caused to emit light as usual. (Steps S904 and S910 can be executed). Thus, even if the first irregular situation occurs, as soon as the central movable body 401, the left movable body 510, and the right movable body 560 return to the origin positions, the light emission modes of the frame lamp 212 and the panel lamp 54 are changed. It is possible to return to normal. As a result, it is possible to prevent the player from feeling as uncomfortable as possible because the frame lamp 212 and the board lamp 54 become dark.

  In addition, when the second irregular situation occurs (when the central movable body 401 stops in contact with the touch electrode 430) and the peak current of the power source of the production motor is 3000 mA or more, the frame lamp 212 Further, no current is supplied to the panel lamp 54, and the frame lamp 212 and the panel lamp 54 do not emit light. However, the state in which the frame lamp 212 and the panel lamp 54 do not emit light does not continue for a long time. That is, when the stopped central movable body 401 returns to the origin position (lowering position), the first no-current flag is turned off (see step S426) and the first low-current drive flag is turned off. (See step S425). As a result, the current limitation on the frame lamp 212 and the panel lamp 54 is released (YES is determined in steps S902, S903, S908, and S909), and the frame lamp 212 and the panel lamp 54 can be caused to emit light as usual. (Steps S904 and S910 can be executed). Thus, even if the second irregular situation occurs, the light emission mode of the frame lamp 212 and the panel lamp 54 can be returned to the normal state as soon as the central movable body 401 returns to the origin position (lowering position). It is. As a result, it is possible to prevent the player from feeling as uncomfortable as possible because the frame lamp 212 and the board lamp 54 become dark.

  Further, when the third irregular situation occurs (at the start of fluctuation, the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k have their respective origin positions (lowering positions). , Closed position, standby position, retraction position), if the peak current of the power supply of the production motor is 3000 mA or more, no current is supplied to the frame lamp 212 and the panel lamp 54, and the frame lamp 212 and The panel lamp 54 does not emit light. However, the state in which the frame lamp 212 and the panel lamp 54 do not emit light does not continue for a long time. That is, if the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k return to their respective origin positions (downward position, closed position, standby position, retreat position), The no-current flag is turned off (see steps S426, S521, S621, S716, and S816), and each low-current drive flag is turned off (see steps S425, S520, S620, S715, and S815). As a result, the current limitation on the frame lamp 212 and the panel lamp 54 is released (YES is determined in steps S902, S903, S908, and S909), and the frame lamp 212 and the panel lamp 54 can be caused to emit light as usual. (Steps S904 and S910 can be executed). Thus, even if the third irregular situation occurs, as soon as the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k return to the origin position, the frame lamp It is possible to return the light emission mode of 212 and the panel lamp 54 as usual. As a result, it is possible to prevent the player from feeling as uncomfortable as possible because the frame lamp 212 and the board lamp 54 become dark.

  [Sub-side 10 ms timer interruption process] The production control microcomputer 121 repeats the sub-side 10 ms timer interruption process shown in FIG. 40 every 10 msec. As shown in FIG. 40, in the sub-side 10 ms timer interrupt process, first, a received command analysis process to be described later is performed (S1001). Next, switch state acquisition processing is performed in which the switch data created in the sub-side 1 ms timer interrupt processing is stored in the effect RAM 124 as switch data for 10 ms timer interrupt processing (S1002). Subsequently, a switch process for setting the display contents of the display screen 50a of the image display device 50 based on the switch data stored in the switch state acquisition process is performed (S1003).

  Subsequently, the effect control microcomputer 121 performs voice control processing (S1004). In the voice control process (S1004), creation of voice data (data for outputting voice from the speaker 610), output of voice data to the voice control board 161, time management of voice production, and the like are performed. As a result, sound suitable for the effect to be executed is output from the speaker 610. The speaker 610 is provided on the lower rear side of the upper decorative unit 200 (elevating unit 300). Thereafter, other processes such as creating lamp data for waiting for customers and updating various random numbers for determining the effect are executed (S1005), and this process ends.

  [Reception Command Analysis Processing] As shown in FIG. 41, in the reception command analysis processing (S1001), first, the effect control microcomputer 121 determines whether or not a variation start command is received from the game control board 100 (S1101). If it has been received, a variation effect start process described later is performed (S1102).

  Subsequently, the effect control microcomputer 121 determines whether or not a variation stop command has been received from the game control board 100 (S1103), and if received, performs a variation effect end process (S1104). In the variation effect end process (S1104), the variation stop command is analyzed, and a variation effect end command for ending the variation effect is set in the output buffer of the effect RAM 124 based on the analysis result.

  Subsequently, the effect control microcomputer 121 determines whether or not an opening command indicating the start of execution of the jackpot game opening is received from the game control board 100 (S1105), and if received, performs opening effect selection processing (S1105). S1106). In the opening effect selection process (S1106), the opening command is analyzed, and the pattern (contents) of the opening effect to be executed during the opening of the jackpot game is selected based on the analysis result. Then, an opening effect start command for starting the opening effect with the selected opening effect pattern is set in the output buffer of the effect RAM 124.

  Subsequently, the effect control microcomputer 121 determines whether or not a round designation command indicating the start of execution of the jackpot game round game has been received from the game control board 100 (S1107), and if received, round effect selection processing is performed. Perform (S1108). In the round effect selection process (S1108), the round designation command is analyzed, and the pattern (contents) of the round effect to be executed during the round game of the jackpot game is selected based on the analysis result. Then, a round effect start command for starting the round effect with the selected round effect pattern is set in the output buffer of the effect RAM 124.

  Subsequently, the effect control microcomputer 121 determines whether or not an ending command indicating start of execution of the jackpot game ending has been received from the game control board 100 (S1109), and if received, performs an ending effect selection process (S1109). S1110). In the ending effect selection process (S1110), the ending command is analyzed, and the ending effect pattern (content) to be executed during the jackpot game ending is selected based on the analysis result. Then, an ending effect start command for starting the ending effect with the selected ending effect pattern is set in the output buffer of the effect RAM 124.

  Subsequently, the effect control microcomputer 121 performs a process based on a received command other than the above-described command (a process for executing a customer waiting effect, etc.) as the other process (S1111). Then, the received command analysis process (S1001) ends.

  [Variation Effect Start Process] As shown in FIG. 42, in the change effect start process (S1102), the effect control microcomputer 121 first analyzes a change start command (S1201). The fluctuation start command includes information on fluctuation patterns (see FIG. 23) and information on special figure stop symbol data based on jackpot determination. Next, the effect control microcomputer 121 executes a change start forced return determination process to be described later (S1202). The change start forced return determination process (S1202) is performed when each of the movable bodies (the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k) is displayed at the start of the variation display of the special symbol. Is a process for determining whether or not to return to each origin position (lowering position, closing position, standby position, retracted position).

  Subsequently, the effect control microcomputer 121 selects an effect symbol EZ that is finally stopped and displayed in the variation effect (S1203). Then, based on the analysis result of the change start command, the change effect pattern that is the content of the change effect is selected (S1204). Once the variation production pattern is determined, the variation production time, the variation display mode of the production symbol, the presence / absence of the reach production, the contents of the reach production, the presence / absence of the SW production (production button production), the contents of the SW production, the production deployment configuration, The details of the contents of the fluctuating effect, such as the type of background, are determined. The various variation effect patterns include a variation effect pattern for executing the movable body opening effect.

  Subsequently, the effect control microcomputer 121 selects a notice effect (S1205). Thereby, the contents of the notice effects such as so-called step-up notice effects and chance-up notice effects are determined. Next, a drive data setting process for setting drive data according to the selected variation effect pattern is executed (S1206). When a variation effect pattern for executing an effect (SP reach or the like) with a high expectation of winning is selected by this drive data setting process (S1206), the above-mentioned central movable body drive data, left movable body drive data, right side The movable body drive data, the character movable body drive data, and the ball movable body drive data can be set in the effect RAM 124. When a variation effect pattern indicating execution of strong SP reach is selected, the center movable body drive data, the left movable body drive data, and the right movable body drive data are set in the effect RAM 124 to execute the unfolding drive effect. To be able to be.

  Then, a lamp data setting process for setting lamp data according to the selected variation effect pattern is executed (S1207). By this lamp data setting process (S1207), frame lamp data and panel lamp data different from the waiting lamp data can be set in the effect RAM 124. In particular, when a variation effect pattern that performs an effect with high expectation of winning (such as SP reach) is selected, the frame lamp data and the panel lamp for causing the frame lamp 212 and the panel lamp 54 to emit light in a particularly bright light emission mode. The data is set in the effect RAM 124.

  Thereafter, the effect control microcomputer 121 sets a change effect start command for starting the change effect in the selected effect symbol, the change effect pattern, and the notice effect in the output buffer of the effect RAM 124 (S1208). The effect start process (S1102) ends. When the variable effect start command set in step S1208 is transmitted to the image control board 140, the image CPU 141 of the image control board 140 reads a predetermined effect image from the image ROM 142 and displays it on the image display device 50. Variation effect is performed on the screen 50a.

  [Variation start forced return determination process] As shown in FIG. 43, in the fluctuation start forced return determination process (S1202), the effect control microcomputer 121 determines whether or not the central movable body 401 is in the lowered position. (S1301). If it is in the lowered position (YES in S1301), the process proceeds to step S1303. On the other hand, if it is not in the lowered position (NO in S1301), the central movable body forced return flag is set to ON (S1302), and the process proceeds to step S1303. As a result, if the peak current of the power supply of the production motor is 3000 mA or more (YES in S421), the first no-current flag is turned on (S422) so that no current is supplied to the frame lamp 212 and the panel lamp 54. It is possible to

  In step S1303, it is determined whether left movable body 510 is in the closed position. If it is in the closed position (YES in S1303), the process proceeds to step S1305. On the other hand, if not in the closed position (NO in S1303), the left movable body forced return flag is set to ON (S1304), and the process proceeds to step S1305. As a result, if the peak current of the power supply of the production motor is 3000 mA or more (YES in S516), the second no-current flag is turned on (S517) so that no current is supplied to the frame lamp 212 and the panel lamp 54. It is possible to

  In step S1305, it is determined whether or not the right movable body 560 is in the closed position. If it is in the closed position (YES in S1305), the process proceeds to step S1307. On the other hand, if not in the closed position (NO in S1305), the right movable body forced return flag is set to ON (S1306), and the process proceeds to step S1307. As a result, if the peak current of the power supply of the production motor is 3000 mA or more (YES in S616), the third no-current flag is turned on (S617) so that no current is supplied to the frame lamp 212 and the panel lamp 54. It is possible to

  In step S1307, it is determined whether or not the character movable body 55k is in the standby position. If it is in the standby position (YES in S1307), the process proceeds to step S1309. On the other hand, if not in the standby position (NO in S1307), the character movable body forced return flag is set to ON (S1308), and the process proceeds to step S1309. As a result, if the peak current of the power supply of the production motor is 3000 mA or more (YES in S711), the fourth no-current flag is turned on (S712) so that no current is supplied to the frame lamp 212 and the panel lamp 54. It is possible to

  In step S1309, it is determined whether or not the ball movable body 56k is in the retracted position. If it is in the retracted position (YES in S1309), this process is finished. On the other hand, if it is not in the retracted position (NO in S1309), the ball movable body forced return flag is set to ON (S1310), and this process is terminated. As a result, if the peak current of the power supply of the production motor is 3000 mA or more (YES in S811), the fifth no-current flag is turned on (S812) so that no current is supplied to the frame lamp 212 and the panel lamp 54. It is possible to

8). Effects of the Present Embodiment As described in detail above, according to the pachinko gaming machine PY1, the frame lamp 212 can emit light in a normal light emission mode by being supplied with a normal current based on the frame lamp data. Is possible. The panel lamp 54 can emit light in a normal light emission mode by being supplied with a normal current based on the panel lamp data. On the other hand, the frame lamp 212 is supplied with a small current that is 25% of the normal current described above based on the low current frame lamp data, so that the light emission mode is darker than the normal light emission mode. It is possible to emit light. The panel lamp 54 also emits light in a darker light emission mode than the normal light emission mode by being supplied with a small current that is 25% of the above-described normal current based on the low-current panel lamp data. It is possible. In this way, by switching the normal current supply or the small current supply to the frame lamp 212 and the panel lamp 54, the current consumption of the entire pachinko gaming machine PY1 can be suppressed.

  Further, according to this pachinko gaming machine PY1, if the peak current (specific value based on the power supplied from the power supply means) of the power supply for the production motor is less than 3000 mA, the normal current described above is applied to the frame lamp 212 and the panel lamp 54. Is supplied, and the frame lamp 212 and the panel lamp 54 can emit light in a normal light emission mode. On the other hand, if the peak current of the power supply of the production motor is 3000 mA or more, the small current described above is supplied to the frame lamp 212 and the panel lamp 54, and light emission is performed while suppressing current consumption in the frame lamp 212 and the panel lamp 54. It is possible to make it. In this way, the supply current to the frame lamp 212 and the panel lamp 54 is switched in software (by the control by the effect control microcomputer 121) in accordance with the state of the power supplied by the power supply board 190 (the power of the effect motor). It is possible to prevent the power supply board 190 from being overloaded.

  Further, according to this pachinko gaming machine PY1, the peak current of the power supply of the production motor is 3000 mA or more, and for example, when the driving mode of the central movable body 401 being driven is changed (regardless of the central movable body drive data). When the central movable body 401 that is not in the lowered position is returned to the lowered position, or the moving central movable body is returned to the lowered position), no current is supplied to the frame lamp 212 and the panel lamp 54, and light is emitted. No longer. Thus, by completely eliminating the current consumption in the frame lamp 212 and the panel lamp 54, it is possible to prevent the power supply board 190 from being overloaded while ensuring the movement (return) of the central movable body 401.

  Further, according to the pachinko gaming machine PY1, the frame lamp 212 and the panel lamp 54 can emit light as usual by being supplied with the normal current described above. On the other hand, the frame lamp 212 and the panel lamp 54 are based on the driving mode (see FIG. 19) of each movable body (the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k). Thus, light is emitted when a small current that is 25% of the normal current is supplied, or no light is emitted when no current is supplied. Thus, by switching the current supplied to the frame lamp 212 and the panel lamp 54 according to the driving mode of each movable body, it is possible to suppress the current consumption of the entire pachinko gaming machine PY1.

  Further, according to the pachinko gaming machine PY1, for example, the driving mode of the central movable body 401 can be changed based on the operation by the player, even though the central movable body 401 is being driven based on the central movable body drive data. . Specifically, when the unfolding release button 44k is pressed when the central movable body 401 is not in the lowered position, the central movable body 401 returns to the lowered position. Alternatively, if the touch electrode 430 is touched while the central movable body 401 is moving, the central movable body 401 stops. Such a change in the driving mode of the central movable body 401 can be irregular for the design developer, and thus there is a possibility that the current consumption becomes too large contrary to prediction. Therefore, when the driving mode of the central movable body 401 is changed based on the operation by the player, it is possible not to supply current to the frame lamp 212 and the panel lamp 54. As a result, even if the above-mentioned irregular situation occurs for the design developer, it is possible to suppress the current consumption of the entire pachinko gaming machine PY1.

  Further, according to this pachinko gaming machine PY1, the movable bodies (the central movable body 401, the left movable body 510, the right movable body 560, the character movable body 55k, and the ball movable body 56k) are located at the origin position (at the start of the special symbol variation display). When it is not in the lowered position, closed position, standby position, or retracted position, the movable body can be forcibly returned to the origin position. Since the return of the movable body in this case can be irregular for the design developer, the current consumption may become too large unexpectedly. Therefore, in this case, it is possible not to supply current to the frame lamp 212 and the panel lamp 54. As a result, even if the above-mentioned irregular situation occurs for the design developer, it is possible to suppress the current consumption of the entire pachinko gaming machine PY1.

  Further, according to this pachinko gaming machine PY1, when the movable body that is not at the origin position is returned to the origin position as described above, if no current is supplied to the frame lamp 212 and the panel lamp 54, the movable body is moved to the origin position. A normal current is supplied to the frame lamp 212 and the panel lamp 54 immediately after returning to. After the irregular situation is completed in this way, the frame lamp 212 and the panel lamp 54 can emit light as usual. Therefore, since the frame lamp 212 and the board lamp 54 do not emit light for a long time, it is possible to reduce a sense of discomfort given to the player.

9. Modified Examples Hereinafter, modified examples will be described. In the description of the modification, the same reference numerals are assigned to the same configurations as those of the pachinko gaming machine PY1 of the above embodiment, and the description thereof is omitted. Of course, you may comprise combining the structure which concerns on a modification suitably. Further, technical features in the above-described embodiments and the following modifications can be appropriately deleted unless they are described as essential in the present specification.

  In the above embodiment, when the peak current of the power supply of the production motor is 3000 mA or more, the current supplied to the frame lamp 212 and the panel lamp 54 is the normal current (current based on the frame lamp data, current based on the panel lamp data). ) Was controlled to a small current of 25%. However, the magnitude of the small current described above can be changed as appropriate, and may be a small current that exceeds 25% of the normal current or a small current that is less than 25% of the normal current. However, from the viewpoint of suppressing current consumption in the pachinko gaming machine PY1, it is preferable to control the current so as to be 50% or less of the normal current.

  In the above embodiment, the current supplied to the frame lamp 212 and the panel lamp 54 is set to a normal current or a small current based on whether or not the peak current of the power source of the production motor is 3000 mA (specific value) or more, or Control was performed so that no current was supplied to the frame lamp 212 and the panel lamp 54. However, the current supplied to the frame lamp 212 and the panel lamp 54 is set to a normal current or a small current based on whether or not the peak current of the power source of the production motor is a value other than 3000 mA, for example, 3500 mA or 2500 mA, or Control may be performed so that no current is supplied to the frame lamp 212 and the panel lamp 54.

  In the above embodiment, the drive means (specific drive means, first drive means) to be supplied with the normal current, or supplied with a small current smaller than the normal current, or no longer supplied with the current is the frame lamp 212. And a panel lamp 54. However, the above-described driving means may be all the light emitting means including the contact notification lamp 432, or may be either the frame lamp 212 or the panel lamp 54, and further, a part of the frame lamp 212 or the panel lamp 54. May be part of The driving means described above is not limited to the light emitting means. For example, the board driving means provided in the game board 1 such as the character movable body 55k and the character moving motor 58, the central movable body 401, and the lifting motor. 310, a driving means for a frame provided in the gaming machine frame 2, a driving means operable by a player such as an effect button (input unit 40k), a sound generating means such as a speaker 610, and an image display device 50 backlights and other driving means such as various solenoids and sensors (electronic devices) may be used. When the driving means (specific driving means, first driving means) to which a small current is supplied is a movable body, the torque generated in the movable body due to the small current is reduced. Therefore, it is preferable to slow down the moving speed of the movable body or limit the range of moving the movable body so that the movable body moves even with a small torque.

  In the above embodiment, when a small current smaller than the normal current (25% of the normal current) is supplied to the frame lamp 212 and the panel lamp 54, the entire frame lamp 212 and the panel lamp 54 are darker than the normal mode. It was made to emit light. However, a normal current is supplied to 25% of the entire frame lamp 212 and panel lamp 54 to emit light in the same light emission mode as the normal mode. On the other hand, 75% of the entire frame lamp 212 and panel lamp 54 may be turned off without supplying current.

  Further, in the above embodiment, whether or not to supply a normal current or a small current to the frame lamp 212 and the panel lamp 54 is a specific value based on the peak current of the production motor power supply (DC24V power supply). ). However, whether or not to supply a normal current or a small current may be based on the peak current of a DC 37V power source, which is the origin of various power sources, or the peak current of other power sources, such as DC 12V, which is the power source of various LEDs. Moreover, it is not limited to the peak current, and may be based on the power value (current × voltage value) or the allowable loss (W) of the power supply substrate 190. As described above, whether or not to supply the normal current or the small current can be appropriately changed as long as it is based on a value related to the power supplied to the power supply board 190, that is, a value indicating the burden on the power supply board 190.

  In the above embodiment, whether or not a normal current or a small current is supplied to the frame lamp 212 and the panel lamp 54 is determined based on a specific value based on the power supplied from the power supply board 190 (power supply means) (specifically, the performance motor). It was based on the peak current of the power supply. However, the current supplied to the frame lamp 212 and the panel lamp 54 may be switched to a normal current or a small current regardless of the specific value based on the power supplied from the power supply board 190. For example, while a frame opening detection sensor for detecting opening of the gaming machine frame 2 is detecting, or while a sensor for fraud detection such as a magnetic sensor or a vibration sensor is detecting, or a specific time zone (for example, The current supplied to the frame lamp 212 and the panel lamp 54 is switched from a normal current to a small current while a specific operation is being performed on the effect button (input unit 40k). May be. Further, when any of the first to third irregular situations occurs (when the driving mode of the second driving means is changed), the current supplied to the frame lamp 212 and the panel lamp 54 is changed from the normal current. It may be possible to switch to a small current.

  Further, in the above embodiment, when the current is not supplied to the frame lamp 212 and the panel lamp 54, the driving modes of the central movable body 401 (other driving means), the left movable body 510, and the right movable body 560 being driven are It was subject to change. Specifically, when the unfolding release button 44k is pressed and the central movable body 401, the left movable body 510, and the right movable body 560 return to the origin position (the lowered position, the closed position), or the touch electrode 430 is touched. The condition is that the central movable body 401 stops. However, when the unfolding release button 44k is pressed and the central movable body 401, the left movable body 510, and the right movable body 560 return to the origin position (the lowered position, the closed position), or the center movable body is in contact with the touch electrode 430. Only one of the cases where the body 401 stops may be used as a condition. In addition, the driving condition of the central movable body 401 (other driving means), the left movable body 510, and the right movable body 560 being driven is not changed, and other conditions may be used. For example, detection by a frame opening detection sensor that detects the opening of the gaming machine frame 2 or detection by a fraud detection sensor such as a magnetic sensor or a vibration sensor, or in a specific time zone (for example, in the morning) There may be a condition that a certain operation is performed on the effect button (input unit 40k).

  Further, in the above embodiment, when the peak current of the power source of the production motor is 3000 mA or more and the first to third irregular situations occur (the unfolding release button 44k is pressed down to move the movable body to the original position. When the movable body stops when it touches the touch electrode 430, or when the movable body returns to the origin position at the start of the special symbol variation display), current is supplied to the frame lamp 212 and the panel lamp 54. Controlled not to be. However, control is performed so that no current is supplied to the frame lamp 212 and the panel lamp 54 only when the first to third irregular situations occur, regardless of the peak current of the power supply of the production motor. May be.

  Further, in the above embodiment, the effect control microcomputer 121 applies to the frame lamp 212 and the panel lamp 54 depending on whether or not the peak current of the power supply of the effect motor and the first to third irregular situations are occurring. On the other hand, a case where a normal current is supplied, a case where a small current is supplied, and a case where no current is supplied are switched. However, the effect control microcomputer 121 may be switched only when the normal current is supplied to the frame lamp 212 and the panel lamp 54 and when the small current is supplied. Alternatively, the switching may be performed only when the normal current is supplied to the frame lamp 212 and the panel lamp 54 and when the current is not supplied. In addition, for example, the production control microcomputer 121 applies to the frame lamp 212 and the panel lamp 54 depending on whether or not the peak current of the power supply of the production motor or the first to third irregular situations occur. A case where a normal current is supplied, a case where a small current that is 25% of the normal current is supplied, and a case where a minimum current (for example, 10% of the normal current) smaller than the above-described small current is supplied. You may make it switch.

  Further, in the above embodiment, the effect control microcomputer 121 (effect control means) controls to switch the current supplied to the frame lamp 212 and the panel lamp 54 (specific drive means, first drive means) as drive means. did. However, control means other than the effect control microcomputer 121, for example, a CPU mounted on the sub drive board 162 or a CPU mounted on the audio control board 161 is driven based on the current limit table as shown in FIG. The current supplied to the means may be controlled to be switched. Note that the current limit table shown in FIG. 19 is merely a table shown as an example, and the contents can be changed as appropriate.

  In the above embodiment, a bipolar stepping motor (shown in the figure) is used as a production motor (elevating motor 310, upper left motor 531, upper right motor 581, character moving motor 58, ball left / right moving motor 92, and ball vertical moving motor 94). 17 (A)). However, a unipolar stepping motor (see FIG. 17B) or a DC motor may be used as the production motor. In addition, although two-phase excitation (see FIG. 18A) is used as an excitation method for the production motor, one-phase excitation (see FIG. 18B) is used, or for the next phase to which a pulse is applied. By alternately shifting one pulse and two pulses, it is possible to use 1-2 phase excitation that alternately creates a state in which only one phase is excited and a state in which two phases are simultaneously excited.

  Further, in the above-described form, the central movable body 401 (second driving means), the left movable body 510, and the right movable body 560 are moved to their respective origin positions (lowering position, Closed position). However, the board movable body such as the character movable body 55k and the ball movable body may be returned to the respective origin positions (standby position, retreat position) based on operations on other operation means. Further, when an operating means such as an effect button (input unit 40k) moves, the operating means may return to the origin position. In these modifications, the current to the first drive means (the frame lamp 212 and the panel lamp) may be limited when the panel movable body and the operation means are returned to the origin position.

  Moreover, in the said form, based on the detection by the touch sensor 431 (detection means), the moving central movable body 401 (2nd drive means) was stopped. However, the movable board body such as the character movable body 55k and the ball movable body may be stopped based on detection by other sensors. Further, when an operating means such as an effect button (input unit 40k) moves, the operating means may be stopped. In these modified examples, when the panel movable body and the operation means are stopped, the current to the first driving means (the frame lamp 212 and the panel lamp) is preferably limited.

  In the above embodiment, four random numbers such as jackpot random numbers are acquired as random numbers (determination information) acquired based on winning to the first starting port 11 or the second starting port 12, but one random number May be determined based on the random number to determine whether or not it is a big hit, the type of win, the presence or absence of reach, and the type of variation pattern. That is, it is possible to arbitrarily set the number of random numbers acquired based on the start winning and what is determined in each random number.

  In the above embodiment, the game machine is determined to shift to the high probability state based on the type of the winning jackpot symbol. However, a so-called V chance machine (a game that controls to a high probability state based on the passage of a specific area). Machine). Although only the big prize device 14D is provided as the big prize device, two big prize devices may be provided.

  Further, in the above embodiment, the pachinko gaming machine PY1 does not execute the small hit game (the special game where the total opening time of the big winning opening is short as a predetermined time (for example, 1.8 seconds) or less), but the small hit game is executed. It is good as a pachinko machine to get. The state in which the small hit game is being executed is referred to as a small hit game state.

  In the above embodiment, the game machine is configured as a game machine (so-called probability variable loop type game machine), which is controlled to the high probability state until the next jackpot game is started. May be configured as a gaming machine with a number of cuts. Moreover, in the said form, it comprised so that the fluctuation | variation of special figure 2 might be performed with priority over the fluctuation | variation of special figure 1. FIG. On the other hand, you may comprise so that the fluctuation | variation of special figure 2 and the fluctuation | variation of special figure 1 may be performed according to the winning order to a start opening. In this case, a storage area that can be stored by adding the first special figure hold and the second special figure hold is provided in the game RAM 104, and the determination information is stored in the storage area in accordance with the winning order. It can be configured to digest from Further, it may be configured such that the fluctuation of the special figure 1 can be executed even during the fluctuation of the special figure 2, and the fluctuation of the special figure 2 can be executed even during the fluctuation of the special figure 1. That is, you may comprise as a game machine which performs what is called simultaneous fluctuation. Moreover, you may comprise as what is called 1 type 2 type | mold mixing machine or a honey-type game machine. That is, the present invention can be suitably applied to gaming machines having various game characteristics regardless of the game characteristics of the gaming machine.

  Moreover, in the said form, it was comprised as a pachinko game machine controlled to a jackpot game state (special game state) on the condition that the special symbol which shows that was won and it was stopped and displayed. On the other hand, it may be configured as a slot machine (cylinder gaming machine, pachislot gaming machine). In this case, in the case of a so-called normal machine that increases the medals by winning a big bonus or a regular bonus, a state in which a bonus such as a big bonus or a regular bonus is being executed corresponds to a special gaming state. Also, if it is a so-called ART machine or AT machine that increases the number of medals during a special game period such as ART (assist replay time) or AT (assist time) that can be frequently won for small roles, the state during ART or AT Corresponds to the special gaming state. In addition, in the normal machine, the control conditions for the special gaming state are determined by winning a big bonus or regular bonus, and on the activated pay line, each combination of symbols that triggers the transition to the big bonus or regular bonus. It is derived and displayed as a reel display result. In addition, the control conditions for the special gaming state on ART machines and AT machines are determined by, for example, winning the ART or AT activation timing by winning the ART or AT execution lottery and then digesting the prescribed number of games. is there.

  In this specification, “establishment of predetermined control conditions” means that, in the above-described form, a win is won in the lottery of the first special symbol or the lottery of the second special symbol, and the jackpot symbol indicating the win is stopped and displayed. It is.

10. Inventions described in the above-described embodiments In the above-described embodiments, the inventions of the following means are shown. In the description of the means described below, the corresponding configuration names and expressions in the above-described embodiment, and reference numerals used in the drawings are added in parentheses for reference. However, the component of each invention is not limited to this supplementary note.

<Means A>
The invention according to means A1
In a gaming machine (pachinko gaming machine PY1) that controls to a special gaming state (big hit gaming state) advantageous to the player based on establishment of a predetermined control condition,
Production control means (production control microcomputer 121) capable of controlling production,
Specific driving means (frame lamp 212, panel lamp 54) that can be driven,
The production control means includes
By supplying a predetermined normal current (current based on frame lamp data, current based on panel lamp data) to the specific driving means, the specific driving means can be driven,
By supplying a small current (25% of the normal current, a current based on the frame lamp data for low current, a current based on the panel lamp data for low current) smaller than the normal current to the specific driving means, A gaming machine characterized in that the specific driving means can be driven.

  According to the gaming machine having this configuration, the specific driving means can be driven as usual by being supplied with a normal current. The specific driving means can be driven by supplying a small current smaller than the normal current. Thus, the current consumption can be suppressed by switching the supply of the normal current or the supply of the small current to the specific drive means.

The invention according to means A2
In the gaming machine described in means A1,
Power supply means (power supply board 190) capable of supplying power,
The production control means includes
When it is determined that the specific value (the peak current of the power supply of the production motor) based on the power supplied from the power supply means is less than a predetermined value (3000 mA) (YES in steps S903 and S909), the specific drive means By supplying the normal current, it is possible to drive the specific drive means,
When determining that the specific value based on the power supplied by the power supply means is equal to or greater than the predetermined value (3000 mA) (NO in steps S903 and S909), by supplying the small current to the specific drive means, A gaming machine characterized in that the specific driving means can be driven.

  According to the gaming machine having this configuration, if the specific value based on the power supplied from the power supply means is less than the predetermined value, the normal current is supplied to the specific drive means, and the specific drive means can be driven normally. It is. On the other hand, if the specific value based on the power supplied from the power supply means is greater than or equal to a predetermined value, a small current is supplied to the specific drive means, and it is possible to drive while suppressing current consumption in the specific drive means. In this way, the supply current to the specific drive means can be switched in software (by control by the effect control means) in accordance with the state of the power supply of the power supply means, so that the power supply means can be overloaded. It is possible to prevent.

The invention according to means A3 is
In the gaming machine described in means A2,
Provided with other driving means (central movable body 401 and lifting motor 310) that can be driven,
The production control means includes
When it is determined that the specific value based on the power supplied by the power supply means is equal to or greater than the predetermined value, and the drive mode of the other drive means is changed during the drive of the other drive means (the deployment release button 44k is When the central movable body 401 is returned to the lowered position by being pressed, and when the central movable body 401 comes into contact with the touch electrode 430 and stops, the specific driving means does not supply current to the specific driving. It is a gaming machine characterized in that it is possible not to drive the means (execute steps S412, S417).

  According to the gaming machine having this configuration, when the specific value based on the power supplied by the power supply means is equal to or greater than the predetermined value and the drive mode of the other drive means being driven is changed, the current is supplied to the specific drive means. Does not drive without being supplied. Thus, by completely eliminating the current consumption in the specific drive means, it is possible to prevent the power supply means from being overloaded while ensuring the drive of the other drive means.

The invention according to means A4 is
In the gaming machine according to any one of means A1 to means A3,
The specific drive means is a light-emitting means capable of emitting light (frame lamp 212, board lamp 54).

  According to the gaming machine having this configuration, the light emission mode of the light emitting means may be difficult to stand out by supplying a small current smaller than the normal current to the light emitting means. However, since most players are not paying much attention to the light emission mode of the light emission means, even if the light emission mode of the light emission means becomes inconspicuous, it is possible to reduce the uncomfortable feeling given to the player.

  By the way, in the invention according to A1 to A4 described above, with respect to the gaming machine described in Japanese Patent Application Laid-Open No. 2003-290453, the effect control unit supplies a specific normal current to the specific drive unit, thereby providing the specific drive unit. The specific drive means can be driven by supplying a small current smaller than the normal current to the specific drive means. Thereby, it is possible to solve the problem of providing a gaming machine capable of suppressing current consumption (to provide operational effects).

<Means B>
The invention according to means B1 is
In a gaming machine (pachinko gaming machine PY1) that controls to a special gaming state (big hit gaming state) advantageous to the player based on establishment of a predetermined control condition,
Production control means (production control microcomputer 121) capable of controlling production,
First drive means (frame lamp 212, panel lamp 54) that can be driven;
Drivable second drive means (central movable body 401 and lifting motor 310),
The production control means includes
The first driving means can be driven by supplying a predetermined normal current (current based on frame lamp data, current based on panel lamp data) to the first driving means,
Based on the driving mode of the second driving means (current limit determination table shown in FIG. 19), the first driving means has a small current smaller than the normal current (25% of normal current, low current frame). The first driving means is driven by supplying a current based on lamp data, a current based on panel lamp data for low current), or by not supplying current to the first driving means. The gaming machine is characterized in that it cannot be driven.

  According to the gaming machine having this configuration, the first driving means can be driven normally by being supplied with the normal current. On the other hand, the first driving means is driven by supplying a small current smaller than the normal current based on the driving mode of the second driving means, or is not driven completely by not supplying the current. In this way, it is possible to suppress current consumption by switching the current supplied to the first drive means in accordance with the drive mode of the second drive means.

The invention according to means B2
In the gaming machine described in means B1,
The production control means includes
While the second driving means is being driven, the driving mode of the second driving means is changed based on the action by the player (depressing operation on the unfolding release button 44k, touching the touch electrode 430) (centrally movable not in the lowered position) The body 401 can be returned to the lowered position, and the moving central movable body 401 in contact with the touch electrode 430 can be stopped)
When the driving mode of the second driving unit is changed, the first driving unit is driven by supplying a small current smaller than the normal current to the first driving unit, or the first driving unit The gaming machine is characterized in that the first driving means can be prevented from being driven (steps S412, S417 are executed) by not supplying current.

  According to the gaming machine having this configuration, the driving mode of the second driving means can be changed based on the operation by the player, even while the second driving means is being driven. However, since the change in the driving mode of the second driving unit can be irregular for the design developer, the current consumption may become excessively large against prediction. Therefore, when the driving mode of the second driving unit is changed based on the operation by the player, a small current is supplied to the first driving unit or no current is supplied. As a result, current consumption can be suppressed.

The invention according to means B3 is
In the gaming machine described in means B2,
Provided with detection means (touch sensor 431) capable of detecting contact or approach by the player,
The production control means includes
When the drive mode of the second drive unit is changed to the stop mode based on the detection by the detection unit (detection by the touch sensor 431) (when the moving central movable body 401 stops), the first drive The first drive unit is driven by supplying a small current smaller than the normal current to the unit, or the first drive unit is not driven by supplying no current to the first drive unit (step S417 is executed). It is a gaming machine characterized by being capable of

  According to the gaming machine having this configuration, when the detection unit detects contact or approach by the player, the driving mode of the second driving unit becomes the stop mode, and safety can be improved. However, since the driving of the second driving means is suddenly stopped, there is a possibility that the current consumption becomes excessively large as an irregular situation. Therefore, in this case, it is possible to suppress current consumption by supplying a small current or no current to the first driving means.

The invention according to means B4 is
In the gaming machine described in means B2,
Provided with operation means (expansion release button 44k) that can be operated by the player,
The second driving means is movable to a predetermined origin position (down position) or operation position (up position) (see FIGS. 3 and 9).
The production control means includes
When the driving mode of the second driving unit is changed to a returning mode in which the second driving unit returns to the origin position (execution of step S410) based on an operation on the operating unit, the first driving is performed. The first driving means is driven by supplying a small current smaller than the normal current to the means, or the first driving means is not driven by supplying no current to the first driving means (step S412 is executed). It is a gaming machine characterized by being capable of

  According to the gaming machine having this configuration, when the player operates the operation means, the drive mode of the second drive means is returned to the origin position, and the second drive means is not disturbed. Is possible. However, since the second drive means is forcibly returned to the origin position instead of the original drive pattern for the second drive means, there is a possibility that the current consumption becomes excessively large as an irregular situation. Therefore, in this case, it is possible to suppress current consumption by supplying a small current or no current to the first driving means.

The invention according to means B5 is
In the gaming machine described in means B4,
The production control means includes
When the driving mode of the second driving unit is changed to a return mode in which the second driving unit returns to the origin position, the second driving unit moves to the origin position (determined as YES in step S423). Then, after the first no-current flag is turned off in step S426, the first driving unit is driven by supplying the normal current to the first driving unit (steps S904 and S910 are executed). It is a gaming machine characterized by being possible.

  According to the gaming machine having this configuration, after the second driving means that is not at the origin position is moved to the origin position, the suppression of the current to the first driving means is released and the normal current is supplied to the first driving means. To do. Thus, after the irregular situation is finished, the first driving means can be driven as usual.

The invention according to means B6 is
In the gaming machine described in means B1,
The second driving means is movable to a predetermined origin position (lowering position shown in FIG. 3) or operating position (upward position shown in FIG. 9).
A symbol display means (special symbol display device 81) for stopping and displaying a symbol (special symbol) in a variable manner based on establishment of a predetermined start condition;
The production control means includes
When the second drive means that is not at the origin position is moved to the origin position when the symbol variation display is started (step S419 is executed), the first drive means is set to be more than the normal current. It is possible to drive the first driving unit by supplying a small small current, or not to drive the first driving unit by supplying no current to the first driving unit (execution of step S422). It is a gaming machine characterized by this.

  According to the gaming machine having this configuration, when the symbol variation display is started, if the second drive means is not at the origin position, the second drive means is forcibly moved to the origin position. However, in this case, since the second driving means is moved as an irregular situation, the current consumption may be excessively increased. Therefore, in this case, it is possible to suppress current consumption by supplying a small current or no current to the first driving means.

The invention according to means B7 is
In the gaming machine described in means B6,
When the second drive means that is not at the origin position is moved to the origin position when the symbol variation display is started, the second drive means is moved to the origin position (YES in step S423). And after the first no-current flag is turned off in step S426), the first drive unit is driven by supplying the normal current to the first drive unit (steps S904 and S910 are executed). It is a gaming machine characterized by being capable of.

  According to the gaming machine having this configuration, after the second drive means that is not at the origin position is moved to the origin position when the symbol variation display is started, the restriction on the supply current to the first drive means is released. Thus, a normal current is supplied to the first driving means. Thus, after the irregular situation is finished, the first driving means can be driven as usual.

The invention according to means B8 is
In the gaming machine according to any one of means B1 to means 7,
The gaming machine is characterized in that the first driving means is a light emitting means capable of emitting light (frame lamp 212, board lamp 54).

  According to the gaming machine having this configuration, there is a case where the light emission mode of the light emitting means becomes inconspicuous by supplying a small current or no current to the light emitting means. However, since most players are not paying much attention to the light emission mode of the light emission means, even if the light emission mode of the light emission means becomes inconspicuous, it is possible to reduce the uncomfortable feeling given to the player.

  By the way, in the invention according to B1 to B8 described above, with respect to the gaming machine described in Japanese Patent Application Laid-Open No. 2003-290453, the effect control means supplies the first driving means by supplying a predetermined normal current. The first driving means can be driven by supplying a small current smaller than the normal current to the first driving means based on the driving mode of the second driving means, or the first driving. It is different in that it is possible not to drive the first drive means by not supplying current to the means. Thereby, it is possible to solve the problem of providing a gaming machine capable of suppressing current consumption (to provide operational effects).

PY1 ... Pachinko machine 44a ... Deployment release button detection sensor 44k ... Deployment release button 54 ... Panel lamp 55k ... Character movable body 56k ... Ball movable body 58 ... Character movement motor 81 ... Special-purpose indicator 92 ... Ball left / right movement motor 94 ... Ball vertical movement motor 121 ... Production control microcomputer 212 ... Frame lamp 310 ... Lifting motor 401 ... Central movable body 430 ... Touch electrode 431 ... Touch sensor 510 ... Left movable body 531 ... Upper left motor 560 ... Right movable body 581 ... Upper right part motor

Claims (1)

In a gaming machine that controls to a special gaming state advantageous to a player based on establishment of a predetermined control condition,
Production control means capable of controlling production;
Drivable first driving means;
Second driving means movable to a predetermined origin position or operation position,
The production control means includes
The first driving means can be driven by supplying a predetermined normal current to the first driving means,
When the second drive means moves to the origin position, the first drive means is driven by supplying a small current smaller than the normal current to the first drive means, or the first drive means A gaming machine, characterized in that the first driving means can be prevented from being driven by supplying no current.

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