JP5696732B2 - Game machine - Google Patents

Description

The present invention relates to a gaming machine.

In a pachinko machine, when a ball that has been driven into the game area enters the symbol operating port, a lottery is performed at the timing of the entry. Further, in a spinning-type game machine using a slot machine or a game ball, when a start lever is operated, a lottery is performed at the operation timing. A result of the lottery, for example, comes to the person have enough, and is ready payout of prize balls and coins. The control for determining the lottery and those or are performed by the main controller, the main controller is liable to be subject to fraud.

Specific fraud, for example, the main control unit, or replaced by illegal that those have enough occurs frequently, or connect the invalid substrate (e.g., "hanging board") to the main controller, an equivalent or there is illegal to those to be generated. Also, in the case of pachinko machines, for example, by fraudulently bent nails which are driven on the game board, the sphere is also misconduct to facilitate ball entrance to winning hole and patterns actuation port.
In the case of a pachinko machine, for example, the inner frame can be opened and closed with respect to the outer frame . A glass frame is provided on the front surface of the inner frame, and the glass frame can be opened and closed with respect to the inner frame. Therefore, when a cheating person performs cheating on the game board surface or the main control device, the inner frame or the glass frame must be opened, but when the inner frame or the glass frame is opened, opening is detected by the sensor grasp, for example, or is notified to the hall computer which manages the game hall, by broadcast knowledge by the fact that the inner frame or glass frame is opened like a lamp lighting and audio output, the fraud can do.

JP 2001-198332 A

However, for example, midnight, etc. after closing of the game arcade, fraudster may enter, if the intruder was fraud by opening the inner frame or glass frame or the like, the power of the pachinko machine is sectional in the time Since the pachinko machine is stopped, it is difficult to detect the opening of the inner frame or the glass frame and it is very difficult to grasp the opening.

  The present invention has been made in order to solve the above-described problems and the like, and allows the opening to be grasped when the door is opened while the power of the gaming machine is turned off. It aims to provide a gaming machine that can.

In order to achieve this object, a gaming machine according to claim 1 is directed to a main body, a door body that can be opened and closed with respect to the main body , main arithmetic means for executing arithmetic processing relating to game control, and the main arithmetic means . are those in which a power supply means for supplying driving power, the driving power of the door opening detection means for detecting the opening of the pre Kitobiratai, the opening detection of the door body according to the door opening detection means from said power supply means Holding means that can be held even when not supplied, and when the door opening detection means detects the opening of the door body when drive power from the power supply means is not supplied, the holding means and supplies power for a predetermined period of the main operating unit falling up, the open detection of the door body and a rise-up means for retaining said holding means, said main operation unit, the main processing unit and another member Electrically connected to a specific device Ri, repeating the process to repeatedly execute the plurality of arithmetic processing at a predetermined execution interval, when launched by the startup means, based on the opening detection of the door body is held in said holding means, Output means for outputting a pulse with a length shorter than the execution interval of the repetitive processing to the specific device, the output means, the holding means and the main arithmetic means are started up in the rising means, Based on the fact that the opening detection of the door body is held by the holding means after the holding means holds the opening detection of the door body and before the execution of the repetitive processing is started. The pulse is output once to the specific device.

According to the gaming machine of the first aspect, there is an effect that it is possible to grasp the opening of the door performed when the power of the gaming machine is turned off.

It is a front view of a pachinko machine. It is a front view of the game board of a pachinko machine. It is a rear view of a pachinko machine. It is a perspective view of the pachinko machine in the state where an inner frame, a front frame, and a lower plate unit were opened. It is the figure which showed the structure of the switch. It is a block diagram which shows the electric constitution of a pachinko machine. It is the circuit diagram which showed the electrical structure of the frame open | release detection circuit. State of inner frame, state of front frame, voltage of TRG terminal of timer, voltage of OUT terminal of timer, voltage of capacitor CD4, voltage of power supply output terminal of frame open detection circuit, reset signal output terminal of frame open detection circuit It is the timing chart which showed the relationship between the voltage and the voltage of the electric power interruption signal output terminal of a frame open | release detection circuit. (A) is the figure which showed typically the area division setting and effective line setting of the display screen, (b) is the figure which illustrated the actual display screen. It is a figure which shows the outline | summary of various counters. 3 is a flowchart showing start-up processing executed by an MPU 201 in the main control device 110. It is a flowchart which shows the main process performed by MPU in a main controller. It is a flowchart which shows the fluctuation | variation process performed in a main process. It is the flowchart which showed the change start process performed in a change process. It is a flowchart which shows a timer interruption process. It is a flowchart which shows the start winning process performed in a timer interruption process. It is a flowchart which shows a NMI interruption process. It is the flowchart which showed the starting process performed by MPU in an audio lamp control apparatus. It is the flowchart which showed the main process performed by MPU of an audio lamp control apparatus. It is the flowchart which showed the door opening alerting | reporting process performed by MPU of an audio | voice lamp control apparatus. It is the flowchart which showed the starting process performed by MPU in the main control apparatus of the pachinko machine of 2nd Embodiment. It is a flowchart which shows the timer interruption process performed with MPU in the main control apparatus of the pachinko machine of 2nd Embodiment. It is a flowchart which shows the main process performed with MPU in the main control apparatus of the pachinko machine of 2nd Embodiment. It is the flowchart which showed the starting process performed with MPU in the main control apparatus of the pachinko machine of 3rd Embodiment. It is the flowchart which showed the main process performed with MPU in the main control apparatus of the pachinko machine of 3rd Embodiment. It is the flowchart which showed the starting process performed with MPU in the main control apparatus of the pachinko machine of 4th Embodiment. It is the flowchart which showed the main process performed with MPU in the main control apparatus of the pachinko machine of 4th Embodiment.

  Hereinafter, an embodiment of a pachinko gaming machine (hereinafter simply referred to as “pachinko machine”) will be described with reference to the drawings. 1 is a front view of the pachinko machine 10, FIG. 2 is a front view of the game board 13 of the pachinko machine 10, and FIG. 3 is a rear view of the pachinko machine 10.

  As shown in FIG. 1, the pachinko machine 10 includes an outer frame 11 having an outer shell formed of a wooden frame combined in a substantially rectangular shape, and an outer frame 11 having substantially the same outer shape as the outer frame 11. And an inner frame 12 supported to be openable and closable. In order to support the inner frame 12, metal hinges 18 are attached to the outer frame 11 at two upper and lower portions on the left side when viewed from the front (see FIG. 1), and the side on which the hinge 18 is provided is used as an opening / closing axis. The frame 12 is supported so as to be openable and closable to the front front side.

  A game board 13 (see FIG. 2) having a large number of nails, winning holes 63, 64, and the like is detachably mounted on the inner frame 12 from the back side. A ball ball game is performed when the ball flows down the front surface of the game board 13. The inner frame 12 has a ball launch unit 112a (see FIG. 5) that launches a ball to the front area of the game board 13 and a launch that guides the ball launched from the ball launch unit 112a to the front area of the game board 13. A rail (not shown) or the like is attached.

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

  The front frame 14 is assembled with decorative resin parts, electrical parts, and the like, and a window part 14c that is formed in an approximately elliptical shape is provided at a substantially central part thereof. A glass unit 16 having two plate glasses is disposed on the back side of the front frame 14, and the front surface of the game board 13 can be seen on the front side of the pachinko machine 10 through the glass unit 16. On the front frame 14, an upper plate 17 that stores balls is formed in a substantially box shape that protrudes forward and the upper surface is opened, and prize balls and rental balls are discharged to the upper plate 17. The bottom surface of the upper plate 17 is formed to be inclined downward to the right when viewed from the front (see FIG. 1), and the sphere thrown into the upper plate 17 is guided to the ball launch unit 112a by the inclination. A frame button 22 is provided on the upper surface of the upper plate 17. This frame button 22 is operated by the player, for example, when changing the effect pattern of the variable display displayed on the third symbol display device 81 or changing the effect content at the reach effect.

  In addition, the front frame 14 is provided with light emitting means such as various lamps around the periphery (for example, a corner portion). These light-emitting means play a role of enhancing the effect of the game during the game by changing or controlling the light-emitting mode by turning on or flashing according to the change in the gaming state at the time of big hit or predetermined reach. On the peripheral edge of the window portion 14c, there are provided electric decoration portions 29 to 33 incorporating light emitting means such as LEDs. In the pachinko machine 10, these lighting parts 29 to 33 function as effect lamps such as jackpot lamps, and the lighting parts 29 to 33 are turned on by lighting or blinking of the built-in LEDs at the time of jackpot or reach effects. Alternatively, it blinks to notify that the jackpot is being hit or that the reach is one step before the jackpot.

  Further, in the upper left part of the front frame 14 as viewed from the front (see FIG. 1), there is provided a display lamp 34 which has built-in light emitting means such as LEDs and can display the payout of a prize ball and when an error occurs. In addition, a small window 35 is formed by attaching a transparent resin from the back side so that the back side of the front frame 14 can be visually recognized, on the lower side of the right illumination part 32, and a sticking space K1 on the front side of the game board 13 (FIG. 2) is visible from the front surface of the pachinko machine 10. In addition, in the pachinko machine 10, a plated member 36 made of ABS resin that is chrome-plated is attached to an area around the electric decoration parts 29 to 33 in order to bring out more gorgeousness.

  A ball rental operation unit 40 is disposed below the window 14c. The ball lending operation unit 40 is provided with a frequency display unit 41, a ball lending button 42, and a return button 43. When the ball lending operation unit 40 is operated in a state where a bill or a card is inserted into a card unit (ball lending unit) (not shown) arranged on the side of the pachinko machine 10, Loans are made. Specifically, the frequency display unit 41 is an area in which the remaining amount information such as a card is displayed, and the built-in LED is lit to display the remaining amount as the remaining amount information. The ball lending button 42 is operated to obtain a lending ball based on information recorded on a card or the like (recording medium), and the lending ball is supplied to the upper plate 17 as long as there is a remaining amount on the card or the like. Is done. The return button 43 is operated when requesting the return of a card or the like inserted into the card unit. In addition, in a pachinko machine in which a ball is lent directly to the upper plate 17 from a ball lending device or the like without using a card unit, a so-called cash machine does not require the ball lending operation unit 40. In this case, the ball lending operation unit 40 It is also possible to add a decorative seal or the like to the installation portion of the parts so that the component configuration is common. A pachinko machine using a card unit and a cash machine can be shared.

  In the lower plate unit 15 located on the lower side of the upper plate 17, a lower plate 50 for storing a ball that could not be stored in the upper plate 17 is formed in a substantially box shape having an open upper surface. Yes. On the right side of the lower plate 50, an operation handle 51 that is operated by a player to drive a ball into the front surface of the game board 13 is disposed, and the operation of the ball launching unit 112a is permitted inside the operation handle 51. Touch sensor 51a, a push button-type stop switch 51b for stopping the launch of the ball during the pressing operation, and a variable resistor for detecting the amount of rotation of the operating handle 51 by a change in electric resistance (Not shown). When the operation handle 51 is rotated clockwise by the player, the touch sensor is turned on and the resistance value of the variable resistor changes corresponding to the operation amount, and according to the rotation operation amount of the operation handle 51. A ball is fired with a strength corresponding to the resistance value of the variable resistor that changes, and the ball is driven into the front surface of the game board 13 with a jump amount corresponding to the player's operation. Further, when the operation handle 51 is not operated by the player, the touch sensor 51a and the stop switch 51b are off.

  In the lower part of the front of the lower plate 50, a ball removal lever 52 is provided for operating when the balls stored in the lower plate 50 are discharged downward. The ball removal lever 52 is always urged in the right direction. By sliding the ball release lever 52 in the left direction against the urge, the bottom opening formed in the bottom surface of the lower plate 50 is opened. A ball naturally falls from the bottom opening and is discharged. The operation of the ball removal lever 52 is normally performed in a state where a box (generally referred to as “a thousand box”) for receiving the balls discharged from the lower plate 50 is placed below the lower plate 50. As described above, the operation handle 51 is disposed on the right side of the lower plate 50, and the ashtray 53 is attached on the left side of the lower plate 50.

  As shown in FIG. 2, the game board 13 includes a wooden base plate 60 cut into a substantially square shape when viewed from the front, a large number of ball nails, windmills and rails 61 and 62, a general winning opening 63, The ball entrance 64, the variable winning device 65, the variable display device unit 80, and the like are assembled, and the peripheral edge thereof is attached to the back side of the inner frame 12. The general winning port 63, the first winning port 64, the variable winning device 65, and the variable display device unit 80 are arranged in a through hole formed in the base plate 60 by router processing, and the wood screw is provided from the front side of the game board 13. It is fixed by etc. Further, the front center portion of the game board 13 can be viewed from the front side of the inner frame 13 through the window portion 14c (see FIG. 1) of the front frame 14. Below, the structure of the game board 13 is demonstrated.

  An outer rail 62 formed by bending a strip-shaped metal plate into a substantially arc shape is planted on the front surface of the game board 13, and the strip-shaped metal plate is located on the inner side of the outer rail 62 in the same manner as the outer rail 62. The arc-shaped inner rail 61 formed by the above is planted. The inner rail 61 and the outer rail 62 surround the outer periphery of the front surface of the game board 13, and the game board 13 and the glass unit 16 (see FIG. 1) surround the front and rear. A game area in which a game is played is formed by the behavior of. The game area is a front surface of the game board 13 and is a substantially circular area formed by dividing the two rails 61 and 62 and the arc member 70 (a winning hole or the like is provided, Area).

  The two rails 61 and 62 are provided to guide the ball fired from the ball launching unit 112a to the upper part of the game board 13. A return ball preventing member 68 is attached to the front end portion of the inner rail 61 (upper left portion in FIG. 2) to prevent the ball once guided to the upper portion of the game board 13 from returning to the ball guide path again. Is done. A return rubber 69 is attached to the tip of the outer rail 62 (upper right part in FIG. 2) at a position corresponding to the maximum flying portion of the sphere, and the ball launched at a predetermined momentum or more hits the return rubber 69 and gains momentum. Is bounced back to the center while being attenuated. A resin arc member 70 formed by providing an arc connecting the rails on the inner surface side between the lower right end of the inner rail 61 and the upper right end of the outer rail 62 is a base. The plate 60 is driven and fixed.

  A first symbol display device 37 provided with a plurality of LEDs 37a, which are light emitting means, and a 7-segment display 37b is disposed in the upper right portion of the game area when viewed from the front (upper right portion in FIG. 2). The first symbol display device 37 displays information corresponding to each control performed by the main control device 110, and mainly displays the gaming state of the pachinko machine 10. The plurality of LEDs 37a indicate whether the pachinko machine 10 is in the process of being probabilistically changing, operating in a short time, or in a normal state, indicating whether the pachinko machine 10 is changing or not by a lighting state, and the symbols corresponding to the probable big hit. Whether the symbol is a symbol corresponding to a normal jackpot or an out-of-game symbol is indicated by a lighting state, or the number of reserved balls is indicated by a lighting state. The 7-segment display device 37b displays the number of rounds that are a big hit and an error display. In addition, LED37a is comprised so that the light emission color (for example, red, green, blue) of each LED may differ, The various game states of the pachinko machine 10 can be suggested with few LEDs by the combination of the light emission color. .

  In addition, the above-mentioned pachinko machine 10 being probable is a game state in which the jackpot probability is increased and it is easy to shift to the special game state. Further, during the probability change in the present embodiment, the game is in a state where the hit probability of the second symbol is increased and the ball easily enters the first entrance 64. In addition, the time when the pachinko machine 10 is short-running is a game state in which it is easy for a ball to easily enter the first entrance 64 by increasing only the hit probability of the second symbol without changing the jackpot probability. In addition, when the pachinko machine 10 is in a normal state, it is a game state in which neither the probability change nor the time is short (the state where neither the big hit probability nor the second symbol hit probability is increased). It should be noted that, depending on the gaming state of the pachinko machine 10, the time for opening the electric accessory (not shown) associated with the first entrance 64 and the number of times the electric accessory is released per hit are changed. It is good as a thing.

  The game area is provided with a plurality of general winning openings 63 through which 5 to 15 balls are paid out as winning balls when the balls win. In addition, a variable display device unit 80 is disposed in the central portion of the game area. The variable display device unit 80 includes a third symbol display device 81 configured with a liquid crystal display (hereinafter simply referred to as “display device”) that displays the third symbol in a variable manner with a winning at the first entrance 64 as a trigger. And a second symbol display device 82 composed of a light emitting diode (hereinafter abbreviated as “LED”) for variably displaying the second symbol with the passage of the ball at the second entrance 67 as a trigger. .

  The display content of the third symbol display device 81 is controlled by a display control device 114, which will be described later, and for example, three symbol sequences of left, middle and right are displayed. Each symbol row is composed of a plurality of symbols, and these symbols are vertically scrolled for each symbol row so that the third symbol is variably displayed on the display screen of the third symbol display device 81. Further, in the present embodiment, the third symbol display device 81 is constituted by a large liquid crystal display of 8 inch size, and the variable display device unit 80 surrounds the outer periphery of the third symbol display device 81 so as to surround the center frame. 86 is arranged. In the third symbol display device 81 of the present embodiment, the display of the gaming state accompanying the control of the main control device 110 is performed by the first symbol display device 37, whereas the display of the first symbol display device 37 is performed. The decorative display according to is performed. Instead of the display device, for example, the third symbol display device 81 may be configured using a reel or the like.

  In addition, when the ball enters the first entrance 64 until the stop symbol (any one of the probable jackpot symbol, the normal jackpot symbol, or the off symbol) is displayed on the first symbol display device 37. The number of entered balls is held up to 4 times, and the number of held times is indicated by the first symbol display device 37 and the number of lights of the holding lamp 85. Four hold lamps 85 are provided corresponding to the maximum number of holds, and are arranged symmetrically above the third symbol display device 81. In the present embodiment, the winning at the first entrance 64 is configured to be held up to 4 times, but the maximum holding number is not limited to 4 times, but 3 times or less. Alternatively, the number may be set to 5 times or more (for example, 8 times). In addition, the hold lamp 85 is deleted, and the number of times the variable display is held based on the winning at the first entrance 64 is numerically held in a part of the third symbol display device 81, or the area divided into four is held. You may make it display in a different aspect (for example, a color and a lighting pattern) by the frequency | count. In addition, since the number of times of holding is indicated by the first symbol display device 37, the holding lamp 85 may not perform lighting display.

  The second symbol display device 82 includes a second symbol display unit 83 and a holding lamp 84, and each time the ball passes through the second entrance 67, the display unit 83 displays a display symbol (second symbol). The “○” symbol and the “×” symbol are alternately lit and displayed in a variable manner. When the fluctuation display stops at a predetermined symbol (in this embodiment, the symbol “O”) The 1 entrance 64 is configured to be activated (opened) for a predetermined time. The number of passes through the second entrance 67 of the sphere is suspended up to a maximum of 4 times, and the number of suspensions is displayed by the above-described first symbol display device 37 and is also lit on the hold lamp 84. The second symbol variation display is performed by switching on and off of a plurality of lamps in the display unit 83 as in the present embodiment, as well as the first symbol display device 37 and the third symbol display device. A part of 81 may be used. Similarly, the hold lamp 84 may be turned on by a part of the third symbol display device 81. In addition, the passage of the second entrance 67 is not limited to 4 times as in the case of the 1st entrance 64, and is not limited to 4 times, or 3 times or less (for example, (8 times). In addition, since the number of times of holding is indicated by the first symbol display device 37, the holding lamp 84 may not perform lighting display.

  Below the variable display device unit 80, a first entrance 64 into which a sphere can enter is disposed. When a ball enters the first entrance 64, a first entrance switch (not shown) provided on the back side of the game board 13 is turned on, and the first entrance switch is turned on. The main controller 110 performs a lottery lottery, and a display corresponding to the lottery result is indicated by the LED 37 a of the first symbol display device 37. The first entrance 64 is also one of the entrances through which 5 balls are paid out as prize balls when a ball enters.

  A variable winning device 65 is disposed below the first ball opening 64, and a horizontally-long rectangular specific winning port (large opening) 65a is provided at a substantially central portion thereof. In the pachinko machine 10, when the lottery in the main control device 110 is a big hit, after a predetermined time (fluctuation time) has elapsed, the LED 37a of the first symbol display device 37 is turned on so as to become a big hit stop symbol, The stop symbol corresponding to the jackpot is displayed on the third symbol display device 81 to indicate the occurrence of the jackpot. Thereafter, the gaming state transitions to a special gaming state (big hit) where the ball is easy to win. In this special gaming state, the special winning opening 65a that is normally closed is opened for a predetermined time (for example, until 30 seconds have elapsed or ten balls have been won).

  The specific winning opening 65a is closed when a predetermined time elapses, and after the closing, the specific winning opening 65a is opened again for a predetermined time. The opening / closing operation of the specific winning opening 65a can be repeated up to 16 times (16 rounds), for example. The state in which the opening / closing operation is performed is a form of a special gaming state advantageous to the player, and the player is given out a larger amount of prize balls than usual in order to give a gaming value (game value). Is done.

  Specifically, the variable winning device 65 is a horizontally long rectangular opening / closing plate covering the specific winning opening 65a, and a large opening opening solenoid (not shown) for driving to open / close forward with the lower side of the opening / closing plate as an axis. And. The special winning opening 65a is normally closed so that the ball cannot win or is difficult to win. In the case of a big hit, the large opening opening solenoid is driven to tilt the opening / closing plate to the lower front side to temporarily form an open state in which the ball is likely to win the specific winning opening 65a. It operates to repeat the state and the state alternately.

  Note that the special gaming state is not limited to the above-described form. When the game area is provided with a large opening that is opened and closed separately from the specific winning opening 65a, and the LED 37a corresponding to the jackpot is turned on in the first symbol display device 37, the specific winning opening 65a is opened for a predetermined time, and the specific winning opening A special gaming state is defined as a game state in which a large opening provided separately from the specific winning port 65a is opened for a predetermined time and a predetermined number of times when the ball 65 is opened into the specific winning port 65a. You may make it form.

  Adhesive spaces K1, K2 for adhering certificate papers, identification labels, etc. are provided at the left and right corners on the lower side of the game board 13, and the certificate paper, etc., adhered to the adhesive space K1, is a front frame 14. It can be visually recognized through the small window 35 (see FIG. 1).

  Further, the game board 13 is provided with an out port 66. A ball that has not entered any of the winning openings 63, 64, 65a is guided through an out port 66 to a ball discharge path (not shown). A number of nails are planted on the game board 13 in order to appropriately disperse and adjust the falling direction of the ball, and various members (instruments) such as a windmill are arranged.

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

  The back pack unit 94 includes a back pack 92 and a dispensing unit 93 that form a protective cover. In addition, each control board is used for MPU as a one-chip microcomputer that controls each control, a port for communicating with various devices, a random number generator used for various lotteries, time counting and synchronization. A clock pulse generation circuit or the like is mounted as necessary.

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

  Further, the substrate box 100 (main control device 110) and the substrate box 102 (dispensing control device 111 and launch control device 112) connect the box base and the box cover so that they cannot be opened by a sealing unit (not shown) (caulking structure). Consolidated). In addition, a seal (not shown) is attached to the connecting portion between the box base and the box cover so as to cover the box base and the box cover. This seal seal is made of a brittle material. If the seal is to be peeled off in order to open the substrate boxes 100, 102, or if the substrate boxes 100, 102 are forcibly opened, the box base side and the box cover are removed. Cut to the side. Therefore, it is possible to know whether or not the substrate boxes 100 and 102 have been opened by checking the sealing unit or the sealing seal.

  The payout unit 93 includes a tank 130 that is located at the top of the back pack unit 94 and opens upward, a tank rail 131 that is connected to the lower side of the tank 130 and is gently inclined toward the downstream side, and downstream of the tank rail 131. A case rail 132 that is vertically connected to the side, and a payout device 133 that is provided at the most downstream portion of the case rail 132 and that pays out a ball by a predetermined electrical configuration of the payout motor 216 (see FIG. 5). ing. The tank 130 is successively replenished with balls supplied from the island equipment of the game hall, and a required number of balls are paid out by the payout device 133 as appropriate. A vibrator 134 for applying vibration to the tank rail 131 is attached to the tank rail 131.

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

  Next, the internal configuration of the pachinko machine 10 will be described with reference to FIG. FIG. 4 is a perspective view of the pachinko machine 10 in a state where the inner frame 12, the front frame 14, and the lower dish unit 15 are opened.

  The pachinko machine 10 is provided with an outer frame 11 that forms an outer shell thereof, and an inner frame 12 is supported to the outer frame 11 so as to be opened and closed. In the game hall, the outer peripheral surface of the outer frame 11 is fixed to an installation location called an island of the game hall. Since the inner frame 12, the front frame 14, and the lower dish unit 15 are configured to be openable to the front side with respect to the outer frame 11, the inner frame 12, the front frame 14, and the lower dish unit 15 are not touched from the front side of the pachinko machine 10. Inspection and adjustment are performed with the inner frame 12 and the like open to the front side with respect to the outer frame 11.

  In order to support the inner frame 12, metal upper hinges (not shown) and lower hinges (not shown) are attached to the outer frame 11 at two upper and lower positions on the left side when viewed from the front. The inner frame 12 is supported so as to be openable and closable with the side on which the upper and lower hinges are provided as an opening / closing axis.

  The inner frame 12 is mainly composed of an ABS resin inner frame base 55 formed in a rectangular shape, and a substantially circular central window 55 a is formed at the center of the inner frame base 55. An attachment portion for the game board 13 is provided on the back side of the inner frame base 55, and the game board 13 is detachably attached.

  The lower side of the central window 55a of the inner frame base 55 is formed in a concave shape with the front side open, and a flat mounting surface 52b is formed on the back side. On the mounting surface 52b, a launch unit 140 for launching a ball to the front surface of the game board 13, a passage forming member 54 that forms a passage for discharging the ball to the upper plate 17 and the lower plate 50, and the like are attached.

  A switch SW1 for detecting opening and closing of the inner frame 12 is provided between the outer frame 11 and the inner frame 12, and between the inner frame 12 and the front frame 14, the opening of the front frame 14 and A switch SW2 for detecting closing is provided.

  Here, the structure of the switch SW1 and the switch SW2 will be described with reference to FIG. Since the switch SW1 and the switch SW2 have the same structure, the structure of the switch SW1 will be described, and the description of the switch SW2 will be omitted.

  FIG. 5 is a cross-sectional view of the switch SW1. FIG. 5A is a cross-sectional view showing a state (cut-off state) of the switch SW1 in a state where the inner frame 12 is closed. FIG. 5B is a cross-sectional view showing a state (conductive state) of the switch SW1 in a state where the inner frame 12 is opened.

  As shown in FIG. 5A, the switch SW1 disposed on the surface of the outer frame 11 facing the inner frame 12 includes a movable shaft SW1a that contacts the inner frame 12 in a closed state, and the movable shaft. A conductor plate SW1-1a made of metal which is a conductive member disposed on SW1a, and a pair of terminal plates SW1-1b made of metal disposed at a position facing the conductor plate SW1-1a, The pair of terminal plates SW1-1b are arranged on a surface opposite to the surface facing the pair of terminal plates SW1-1b on the conductor plate SW1-1a and the support plate SW1-1c disposed in the housing SW1b. And a pair of springs SW1c that generate a biasing force in the direction toward the pair of terminal plates SW1-1b with respect to the conductor plate SW1-1a.

  As shown in FIG. 5A, in a state where the inner frame 12 is closed, the movable shaft SW1a abuts on the inner frame 12, and the movable shaft SW1a is pushed into the housing SW1b. Accordingly, the contact between the conductor plate SW1-1a and the pair of terminal plates SW1-1b is prevented. Therefore, in a state where the inner frame 12 is closed, the switch SW1 is in a state where conduction is cut off.

  On the other hand, as shown in FIG. 5B, in the state where the inner frame 12 is opened, the contact between the movable shaft SW1a and the inner frame 12 is released, so that the conductor is applied by the biasing force of the pair of springs SW1c. The board SW1-1a and the pair of terminal boards SW1-1b are in contact with each other. Therefore, in a state where the inner frame 12 is opened, the switch SW1 is in a conductive state.

  As described above, the switch SW1 is in a cut-off state when the inner frame 12 is closed, and is in a conductive state when the inner frame 12 is opened. Note that the structure of the switch SW1 is not limited to the shape shown in FIG. 5. When the inner frame 12 is closed, the switch SW1 is in a cut-off state, while in the state where the inner frame 12 is opened, Any structure may be used as long as the switch SW1 is in a conductive state. The same applies to the structure of the switch SW2.

  Next, the electrical configuration of the pachinko machine 10 will be described with reference to FIG. FIG. 6 is a block diagram showing an electrical configuration of the pachinko machine 10.

  The power supply device 115 includes a power supply unit 251 for supplying power to each unit of the pachinko machine 10, a power failure monitoring circuit 252 for monitoring power interruption due to a power failure, and a RAM deletion switch 122 (see FIG. 3). It has an erasing switch circuit 253 and a reset circuit 254 that outputs a reset signal SG3a for enabling the arithmetic processing of the MPU 201. The power supply unit 251 is a device that supplies a necessary operating voltage to each of the control devices 110 to 114 through a power supply path (not shown). As its outline, the power supply unit 251 takes in the voltage of AC 24 volts supplied from the outside, and drives various switches such as various switches 208, solenoids such as the solenoid 209, motors, etc. A 5 volt voltage for logic, a backup voltage for RAM backup, and the like are generated, and the 12 volt voltage, the 5 volt voltage, and the backup voltage are supplied to the control devices 110 to 114 as necessary voltages. The power supply unit 251 outputs a drive voltage Va of 5 volts to the input terminal I13 of the multiplexer MP1.

  When a power failure occurs due to a power failure or the like when the power of the pachinko machine 10 is turned on, the power failure monitoring circuit 252 is connected to the input terminal I11 of the multiplexer MP1 and the NMI terminal of the MPU 211 of the dispensing control device 111 when the power is interrupted. This is a circuit for outputting a power failure signal SG1a which is a positive pulse signal. The power failure monitoring circuit 252 monitors the DC stable voltage of 24 volts, which is the maximum voltage output from the power supply unit 251, and determines that a power failure (power interruption, power interruption) occurs when this voltage falls below 22 volts. Then, the power failure signal SG1a is output to the multiplexer MP1 and the payout control device 111. By the output of the power failure signal SG1a, the main controller 110 and the payout controller 111 recognize the occurrence of the power failure and execute the NMI interrupt process. Note that the power supply unit 251 outputs a voltage of 5 volts, which is a drive voltage of the control system, for a time sufficient to execute the NMI interrupt processing even after the DC stable voltage of 24 volts becomes less than 22 volts. Is maintained at a normal value. Therefore, main controller 110 and payout controller 111 can normally execute and complete the NMI interrupt process (see FIG. 17).

  The RAM erase switch circuit 253 is a circuit for outputting a RAM erase signal SG2 for clearing backup data to the main controller 110 when the RAM erase switch 122 is pressed. When the RAM erase signal SG2 is input when the pachinko machine 10 is turned on, the main control device 110 and the payout control device 111 clear the respective backup data and the payout control device 111 for clearing the backup data. A payout initialization command is transmitted to the payout control device 111.

  The reset circuit 254 is a circuit that outputs a reset signal SG3a that puts the MPU 201 into a state in which arithmetic processing can be executed. The reset circuit 254 outputs a voltage of 5 volts output from the power supply unit 251 as the reset signal SG3a. When the reset signal SG3a is input to the MPU 201 via the multiplexer MP2, the MPU 201 is in a state in which arithmetic processing can be executed. On the other hand, when the output of the reset signal SG3a is stopped, the MPU 201 is in a state where the arithmetic processing cannot be executed. Although not shown, the reset signal SG3a output from the reset circuit 254 is also input to the MPU 211 of the payout control device 111, the MPU 221 of the sound lamp control device 113, and the MPU 231 of the display control device 114.

  In the pachinko machine 10, the power failure monitoring circuit 252, the RAM erasing switch circuit 253, and the reset circuit 254 are provided in the power supply device 115. However, the power failure monitoring circuit 252, the RAM erasing switch circuit 253, or the like is not limited thereto. Any of the reset circuits 254 may be provided in the main controller 110. Further, a combination of any two of the power failure monitoring circuit 252, the RAM erasing switch circuit 253, and the reset circuit 254 may be provided in the main controller 110. Further, three circuits of the power failure monitoring circuit 252, the RAM erasing switch circuit 253, and the reset circuit 254 may be provided in the main controller 110. When the RAM erase switch circuit 253 is provided in the main controller 110, the RAM erase switch 112 is also provided in the main controller 110.

  The main controller 110 is equipped with an MPU 201 as a one-chip microcomputer that is an arithmetic unit. The MPU 201 includes a ROM 202 that stores various control programs executed by the MPU 201 and fixed value data, and a memory that temporarily stores various data when the control program stored in the ROM 202 is executed. A certain RAM 203 and various other circuits such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit are incorporated. Various commands are transmitted from the main control device 110 to the sub control device by the data transmission / reception circuit in order to instruct the sub control device such as the payout control device 111 and the sound lamp control device 113 to operate. Such a command is transmitted from the main controller 110 to the sub controller only in one direction.

  The MPU 201 has either a power supply terminal to which the driving voltage Va or the driving voltage Vb that enables the MPU 201 to be input is input, and either the reset signal SG3a or the reset signal SG3b that enables the MPU 201 to execute arithmetic processing. And a NMI terminal (non-maskable interrupt terminal) to which either the power failure signal SG1a or the power failure signal SG1b is input.

  The lower limit value of the voltage at which the MPU 201 can operate is about 4.0 volts. Therefore, if the driving voltage Va or the driving voltage Vb supplied to the power supply terminal of the MPU 201 exceeds about 4.0 volts, the MPU 201 enters a startable state (operable state), while the power supply terminal of the MPU 201 When the drive voltage Va or the drive voltage Vb supplied to the voltage is about 4.0 volts or less, the MPU 201 becomes inoperable. In addition, the lower limit value of the voltage at which the MPU 201 can execute the calculation is about 4.3 volts. Therefore, if the voltage (reset signal SG3a or reset signal SG3b) supplied to the reset terminal of the MPU 201 exceeds about 4.3 volts, the MPU 201 is ready to perform arithmetic processing, while the MPU 201 has a reset terminal. If the supplied voltage (reset signal SG3a or reset signal SG3b) is about 4.3 volts or less, the MPU 201 becomes incapable of performing arithmetic processing. Also, the power failure signal SG1a output from the power failure monitoring circuit 252 or the power failure signal SG1b output from the frame opening detection circuit 260 is input to the NMI terminal of the MPU 201, and the power failure signal SG1a or power failure signal is output. When any of SG1b is input to the MPU 201, an NMI interrupt process (see FIG. 17) as a power failure process is immediately executed.

  An input / output port 205 is connected to the MPU 201 of the main control device 110 via a bus line 204 composed of an address bus and a data bus. The input / output port 205 includes a payout control device 111, a sound lamp control device 113, a first symbol display device 37, a second symbol display device 82, various switches 208 including a switch group and a sensor group (not shown), and a specific prize. A solenoid 209 comprising a large opening solenoid for opening and closing the front side with the lower side of the opening and closing plate of the opening 65a as an axis, a solenoid for driving an electric accessory, and the like is connected.

  In addition, a hall computer 262 that continues to operate for 24 hours is connected to the input / output port 205. When the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on when the power of the pachinko machine 10 is turned off, the frame opening detection circuit 260 described later temporarily starts the MPU 201. The MPU 201 that has temporarily started up outputs a pulse signal having a pulse width of about 1 msec to the hall computer 262 via the input / output port 205. The pulse signal output via the input / output port 205 is stored in the hall computer 262. Therefore, by analyzing the pulse signal stored in the hall computer 262, it is possible to detect the opening of the inner frame 12 or the front frame 14 performed while the power of the pachinko machine 10 is turned off. Furthermore, the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened can be specified.

  The main controller 110 is provided with a frame opening detection circuit 260 that detects opening of the inner frame 12 when the switch SW1 is turned on and detects opening of the front frame 14 when the switch SW2 is turned on. The frame opening detection circuit 260 is connected to a switch SW1 for detecting the opening of the inner frame 12 and a switch SW2 for detecting the opening of the front frame 14. The switch SW1 and the switch SW2 are connected to the frame opening detection circuit 260 via an input / output unit (not shown) that is different from the input / output port 205 (latch circuit, etc.) for inputting and outputting signals. Has been done. Although details will be described with reference to FIG. 7, the frame opening detection circuit 260 is provided with a power supply capacitor CD1, so that when the pachinko machine 10 is powered off, the inner frame 12 or the front surface Even if the frame 14 is opened, the frame open detection circuit 260 can detect the opening and temporarily start the MPU 201. In addition, when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is on, the frame opening detection circuit 260 naturally operates. Here, when the power of the pachinko machine 10 is on, the MPU 201 has already started up, and it is not necessary to start up the MPU 201 by the frame opening detection circuit 260. At this time, the inner frame 12 or the front frame 14 has been opened. In this case, the frame opening detection circuit 260 outputs only the reset signal SG3b to the input / output port 205 without starting up the MPU 201 by the operations of the multiplexers MP1 to MP3.

  Further, the frame open detection circuit 260 receives an input of the multiplexer MP1 when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on when the power of the pachinko machine 10 is turned off. The terminal I21 is provided with a power interruption signal output terminal for outputting the power failure signal SG1b for about 4.4 seconds from when the switch SW1 or the switch SW2 is turned on. The power interruption signal output terminal of the frame opening detection circuit 260 is connected to the input terminal I21 of the multiplexer MP1 in which the output terminal O1 is connected to the NMI terminal of the MPU 201. The input terminal I11 of the multiplexer MP1 is connected to the power failure monitoring circuit 252, and the control terminal S1 of the multiplexer MP1 is connected to the power supply unit 251. Therefore, when the power of the pachinko machine 10 is on, a voltage of 5 volts for logic is input from the power supply unit 251 to the control terminal S1 of the multiplexer MP1. On the other hand, when the power of the pachinko machine 10 is off, the power supply unit 251 does not operate, so no voltage is input to the control terminal S1 of the multiplexer MP1 (the voltage of the control terminal S1 of the multiplexer MP1 is zero volts). Become).

  Here, regarding the relationship between the power outage signal SG1a output from the power outage monitoring circuit 252 and the power outage signal SG1b output from the power outage signal output terminal of the frame opening detection circuit 260, the power of the pachinko machine 10 is turned on. A description will be given separately when the power of the pachinko machine 10 is turned off.

  When the power of the pachinko machine 10 is on, a voltage of 5 volts is input from the power supply unit 251 to the control terminal S1 of the multiplexer MP1. When a voltage of 5 volts is input to the control terminal S1, the multiplexer MP1 conducts the input terminal I11 of the multiplexer MP1 and the output terminal O1 of the multiplexer MP1 (the input terminal I21 of the multiplexer MP1 and the output terminal of the multiplexer MP1). When the power of the pachinko machine 10 is on, the power failure signal SG1a output from the power failure monitoring circuit 252 can be input to the NMI terminal of the MPU 201 (frame open detection). Even if the power failure signal SG1b is output from the power interruption signal output terminal of the circuit 260, it is not input to the NMI terminal of the MPU 201). On the other hand, when the power of the pachinko machine 10 is turned off, a voltage of zero volts is input from the power supply unit 251 to the control terminal S1 of the multiplexer MP1. When a voltage of zero volts is input to the control terminal S1, the multiplexer MP1 conducts the input terminal I21 of the multiplexer MP1 and the output terminal O1 of the multiplexer MP1 (the input terminal I11 of the multiplexer MP1 and the output terminal O1 of the multiplexer MP1). When the power of the pachinko machine 10 is off, the power failure signal SG1b output from the power interruption signal output terminal of the frame open detection circuit 260 can be input to the NMI terminal of the MPU 201. It becomes. As described above, the multiplexer MP1 outputs a signal to be output to the NMI terminal of the MPU 201 according to the voltage input from the power supply unit 251 to the control terminal S1, that is, according to the on / off state of the power supply of the pachinko machine 10. Switch to one of the signals SG1b.

  Further, the frame open detection circuit 260 receives an input of the multiplexer MP2 when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on when the power of the pachinko machine 10 is turned off. The terminal I22 and the input / output port 205 are provided with a reset signal output terminal for outputting the reset signal SG3b for about 9.4 seconds from when the switch SW1 or the switch SW2 is turned on. The reset signal output terminal of the frame opening detection circuit 260 is connected to the input terminal I22 and the input / output port 205 of the multiplexer MP2 in which the output terminal O2 is connected to the reset terminal of the MPU 201. The input terminal I12 of the multiplexer MP2 is connected to the reset circuit 254, and the control terminal S2 of the multiplexer MP2 is connected to the power supply unit 251. Therefore, when the power of the pachinko machine 10 is on, a voltage of 5 volts for logic is input from the power supply unit 251 to the control terminal S2 of the multiplexer MP2. On the other hand, when the power of the pachinko machine 10 is off, the power supply unit 251 does not operate, so no voltage is input to the control terminal S2 of the multiplexer MP2 (the voltage of the control terminal S2 of the multiplexer MP2 is zero volts). Become).

  Here, regarding the relationship between the reset signal SG3a output from the reset circuit 254 and the reset signal SG3b output from the reset signal output terminal of the frame opening detection circuit 260, the case where the power of the pachinko machine 10 is turned on and the pachinko machine A description will be given separately for the case where the power supply 10 is turned off.

  When the power of the pachinko machine 10 is turned on, a voltage of 5 volts is input from the power supply unit 251 to the control terminal S2 of the multiplexer MP2. When a voltage of 5 volts is input to the control terminal S2, the multiplexer MP2 conducts between the input terminal I12 of the multiplexer MP2 and the output terminal O2 of the multiplexer MP2 (the input terminal I22 of the multiplexer MP2 and the output terminal of the multiplexer MP2). Therefore, when the power of the pachinko machine 10 is turned on, the reset signal SG3a output from the reset circuit 254 can be input to the reset terminal of the MPU 201 (frame open detection circuit). Even if the reset signal SG3b is output from the reset signal output terminal 260, it is not input to the reset terminal of the MPU 201). On the other hand, when the power of the pachinko machine 10 is turned off, a voltage of zero volts is input from the power supply unit 251 to the control terminal S2 of the multiplexer MP2. When a voltage of zero volt is input to the control terminal S2, the multiplexer MP2 conducts between the input terminal I22 of the multiplexer MP2 and the output terminal O2 of the multiplexer MP1 (the input terminal I12 of the multiplexer MP2 and the output terminal O2 of the multiplexer MP1). When the power of the pachinko machine 10 is turned off, the reset signal SG3b output from the reset signal output terminal of the frame opening detection circuit 260 can be input to the reset terminal of the MPU 201. Become. As described above, the multiplexer MP2 outputs a signal to be output to the reset terminal of the MPU 201 according to the voltage input from the power supply unit 251 to the control terminal S, that is, according to the on / off state of the power supply of the pachinko machine 10, or the reset signal SG3a. Switch to one of the signals SG3b.

  Note that the reset signal output terminal of the frame opening detection circuit 260 is also connected to the input / output port 205 as described above. Therefore, when the inner frame 12 or the front frame 14 is opened, the reset signal SG3b is sent from the reset signal output terminal of the frame open detection circuit 260 to the input / output port 205 regardless of whether the power of the pachinko machine 10 is turned on. Is output. The MPU 201 can detect the opening of the inner frame 12 or the front frame 14 by the reset signal SG3b output to the input / output port 205.

  The frame opening detection circuit 260 has an input terminal I13 of the multiplexer MP3 when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on when the power of the pachinko machine 10 is turned off. A power output terminal is provided for supplying a drive voltage Vb having a maximum value of about 5 volts for about 9.9 seconds after the switch SW1 or SW2 is turned on. The power supply output terminal of the frame opening detection circuit 260 is connected to the input terminal I23 of the multiplexer MP3 in which the output terminal O3 is connected to the power supply terminal of the MPU 201. The input terminal I13 of the multiplexer MP3 is connected to the power supply unit 251, and the control terminal S3 of the multiplexer MP3 is also connected to the power supply unit 251. Therefore, when the power of the pachinko machine 10 is on, a voltage of 5 volts for logic is input from the power supply unit 251 to the control terminal S3 of the multiplexer MP3. On the other hand, when the power of the pachinko machine 10 is off, the power supply unit 251 does not operate, so no voltage is input to the control terminal S3 of the multiplexer MP3 (the voltage of the control terminal S3 of the multiplexer MP3 is zero volts). Become).

  Here, regarding the relationship between the drive voltage Va output from the power supply unit 251 and the drive voltage Vb having a maximum value of about 5 volts output from the power supply output terminal of the frame opening detection circuit 260, the power of the pachinko machine 10 is turned on. A case where the power supply of the pachinko machine 10 is turned off will be described separately.

  When the power of the pachinko machine 10 is turned on, a voltage of 5 volts is input from the power supply unit 251 to the control terminal S3 of the multiplexer MP3. When a voltage of 5 volts is input to the control terminal S3, the multiplexer MP3 conducts between the input terminal I13 of the multiplexer MP3 and the output terminal O3 of the multiplexer MP3 (the input terminal I23 of the multiplexer MP3 and the output terminal of the multiplexer MP3). Therefore, when the power of the pachinko machine 10 is turned on, the drive voltage Va output from the power supply unit 251 can be input to the power supply terminal of the MPU 201 (frame open detection circuit). Even if the drive voltage Vb is output from the power supply output terminal 260, it is not input to the power supply terminal of the MPU 201). On the other hand, when the power of the pachinko machine 10 is turned off, a voltage of zero volts is input from the power supply unit 251 to the control terminal S3 of the multiplexer MP3. When a voltage of zero volts is input to the control terminal S3, the multiplexer MP3 conducts between the input terminal I23 of the multiplexer MP3 and the output terminal O3 of the multiplexer MP3 (the input terminal I13 of the multiplexer MP3 and the output terminal O3 of the multiplexer MP3). Therefore, when the power of the pachinko machine 10 is turned off, the drive voltage Vb output from the power output terminal of the frame opening detection circuit 260 can be input to the power terminal of the MPU 201. . As described above, the multiplexer MP3 outputs the voltage output from the power supply unit 251 to the power supply terminal of the MPU 201 according to the voltage input from the power supply unit 251 to the control terminal S, that is, according to the on / off state of the power supply of the pachinko machine 10. The drive voltage Va is switched to either the output drive voltage Va or the drive voltage Vb output from the power supply output terminal of the frame opening detection circuit 260.

  The output terminal O3 of the multiplexer MP3 is also connected to the input / output port 205, although not shown. Therefore, when the power of the pachinko machine 10 is turned off, when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on, the power is output from the power output terminal of the frame open detection circuit 260. The driving voltage Vb is also supplied to the input / output port 205.

  As described above, when the power of the pachinko machine 10 is turned on, various signals (power failure signal SG1a and reset signal SG3a) from each circuit (power supply unit 251, power failure monitoring circuit 252 and reset circuit 254) of the power supply device 115. The driving voltage Va is output to each terminal (NMI terminal, reset terminal, and power supply terminal) of the MPU 201 via the multiplexers MP1 to MP3. When the power of the pachinko machine 10 is turned on, when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on, only the reset signal SG3b is input from the frame open detection circuit 260. The data is output to the output port 205. On the other hand, when the power of the pachinko machine 10 is turned off, when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on, the frame open detection circuit 260 outputs various signals (power failure signal SG1b). The reset signal SG3b) and the drive voltage Vb are output to each terminal (NMI terminal, reset terminal, and power supply terminal) of the MPU 201 for a certain period via the multiplexers MP1 to MP3. Therefore, even when the power of the pachinko machine 10 is turned off, the frame opening detection circuit 260 temporarily turns the MPU 201 (this embodiment) when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on. In about 9.9 seconds) you can start up.

  As described above, the output terminal O3 of the multiplexer MP3 is also connected to the input / output port 205, although not shown. Therefore, when the power of the pachinko machine 10 is turned off, when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on, the power output terminal of the frame open detection circuit 260 is connected to the input / output port 205. Drive voltage Vb is also output. Therefore, even when the power of the pachinko machine 10 is turned off, the frame opening detection circuit 260 causes the input / output port 205 to be turned on when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on. It can be started temporarily (in this embodiment, about 9.9 seconds).

  The RAM 203 stores the contents of the internal registers of the MPU 201, the return address of the control program executed by the MPU 201, and the work area (work area for storing various flags and counters, I / O values, etc. Area). Further, the RAM 203 has an off-in-frame release flag 203a and an on-in-frame release flag 203b. Note that the RAM 203 is configured so that the backup voltage is supplied from the power supply device 115 and the data can be retained (backed up) even after the power of the pachinko machine 10 is shut off, and all data stored in the RAM 203 is backed up. .

  When the power is shut down due to the occurrence of a power failure or the like, the stack pointer and the value of each register when the power is shut off (including when the power failure occurs, the same applies hereinafter) are stored in RAM 203. On the other hand, at the time of power-on (including power-on due to power failure cancellation, the same applies hereinafter), the state of the pachinko machine 10 is restored to the state before power-off based on information stored in the RAM 203. Writing to the RAM 203 is executed when the power is shut off by the main process (see FIG. 12), and restoration of each value written in the RAM 203 is executed in a startup process (see FIG. 11) when the power is turned on.

  When the power of the pachinko machine 10 is turned off, the off-in-frame release flag 203a opens the inner frame 12 or the front frame 14, the switch SW1 or the switch SW2 conducts, and the MPU 201 is turned on by the frame release detection circuit 260. This is a flag that is turned on when it is temporarily activated (the process of S112 of the activation process of the main controller 110 described later). By turning on the off-in-frame release flag 203a, the MPU 201 can detect that the inner frame 12 or the front frame 14 has been opened when the power of the pachinko machine 10 is turned off. When the off-in-frame opening detection flag 203a is on and the power of the pachinko machine 10 is turned on, the MPU 201 performs notification using the audio output device 226 and the lamp display device 227. As a result, the pachinko machine 10 can notify an unspecified number of persons (such as shop assistants and players) that the inner frame 12 or the front frame 14 has been opened while the pachinko machine 10 is powered off. On the other hand, the off-in-frame release flag 203a is turned off when the RAM deletion switch 122 is operated to clear the used RAM area in the process of S116 of the startup process of the main controller 110 (see FIG. 11). . Therefore, once the off-in-frame release flag 203a is turned on, the off-in-frame release flag 203a cannot be turned off unless the RAM erase switch 122 is operated to clear the used RAM area in the process of S116. Therefore, when the power of the pachinko machine 10 is turned on, the pachinko machine 10 does not reliably confirm that the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off. It is possible to notify a specific number of people.

  The on-frame open flag 203b is a reset signal for the frame open detection circuit 260 when the power of the pachinko machine 10 is turned on, the inner frame 12 or the front frame 14 is opened, the switch SW1 or the switch SW2 is turned on. This flag is turned on when the reset signal SG3b is output from the output terminal to the input / output port 205 (processing in S219 of the main processing). When the opened inner frame 12 or the opened front frame 14 is closed, the on-in-frame opening flag 203b is turned off in the process of S220 of the main process. When the on-in-frame release flag 203b is turned on, the MPU 201 can detect that the inner frame 12 or the front frame 14 has been opened when the power of the pachinko machine 10 is turned on. Note that, when the pachinko machine 10 is powered on, the MPU 201 performs a notification using the audio output device 226 and the lamp display device 227 when the on-in-frame opening detection flag 203b is turned on. Thereby, the pachinko machine 10 can notify an unspecified number of persons that the inner frame 12 or the front frame 14 has been opened while the pachinko machine 10 is powered on.

  The payout control device 111 drives the payout motor 216 to perform payout control of prize balls and rental balls. The MPU 211, which is an arithmetic unit, includes a ROM 212 that stores a control program executed by the MPU 211, fixed value data, and the like, and a RAM 213 that is used as a work memory or the like.

  The RAM 213 of the payout control device 111, like the RAM 203 of the main control device 110, has a stack area for storing the contents of the internal registers of the MPU 211, the return address of the control program executed by the MPU 211, and various flags and counters. And a work area (work area) in which values such as I / O are stored. The RAM 213 is configured to be able to retain (backup) data by being supplied with a backup voltage from the power supply device 115 even after the power of the pachinko machine 10 is cut off, and all data stored in the RAM 213 is backed up. The NMI terminal of the MPU 211 is configured to receive a power failure signal SG1a from the power failure monitoring circuit 252 when the power is shut down due to the occurrence of a power failure or the like, and when the power failure signal SG1a is input to the MPU 211, The NMI interrupt process (see FIG. 17) as a process is immediately executed.

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

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

  The voice lamp control device 113 is a voice output in a voice output device (such as a speaker not shown) 226, an output of lighting and extinguishing in a lamp display device (such as the illumination units 29 to 33 and the display lamp 34), and the display control device 114. The setting of the display mode of the 3rd symbol display apparatus 81 performed etc. is controlled. The MPU 221 that is an arithmetic unit includes a ROM 222 that stores a control program executed by the MPU 221, fixed value data, and the like, and a RAM 223 that is used as a work memory or the like.

  An input / output port 225 is connected to the MPU 221 of the sound lamp control device 113 via a bus line 224 including an address bus and a data bus. The main control device 110, the display control device 114, the audio output device 226, the lamp display device 227, and the like are connected to the input / output port 225, respectively.

  The display control device 114 controls the change display of the third symbol on the third symbol display device (LCD) 81. The display control device 114 includes an MPU 231, a ROM (program ROM) 232, a work RAM 233, a video RAM 234, a character ROM 235, an image controller 236, an input port 237, an output port 238, and bus lines 239 and 240. have. The input side of the input port 237 is connected to the output side of the sound lamp control device 113, and the output side of the input port 237 is connected to the MPU 231, ROM 232, work RAM 233, and image controller 236. A video RAM 234 and a character ROM 235 are connected to the image controller 236, and an output port 238 is connected via a bus line 240. A third symbol display device 81 is connected to the output side of the output port 238. Even if the pachinko machine 10 is a different model with different winning probability for winning the jackpot and the number of prize balls to be paid out in one jackpot, there is a model having the same specifications as the symbols displayed on the third symbol display device 81. Therefore, the display control device 114 is made into a common part to reduce the cost.

  The MPU 231 of the display control device 114 controls the display content of the third symbol display device 81 based on the symbol display command input from the sound lamp control device 113. The ROM 232 is a memory for storing various control programs executed by the MPU 231 and fixed value data. The work RAM 233 is a memory for temporarily storing work data and flags used when the MPU 231 executes various programs. The character ROM 235 is a memory that stores data for effects such as symbols (background symbols and third symbols) displayed on the third symbol display device 81. The video RAM 234 is a memory for storing effect data displayed on the third symbol display device 81, and the display content of the third symbol display device 81 is changed by rewriting the contents of the video RAM 234.

  The image controller 236 adjusts the timing of the MPU 231, the video RAM 234, and the output port 238 to intervene in reading and writing data, and reads display data stored in the video RAM 234 at a predetermined timing to read the third symbol display device 81. Is displayed.

  Next, the frame opening detection circuit 260 will be described with reference to FIG. FIG. 7 is a circuit diagram showing an electrical configuration of the frame opening detection circuit 260. A frame opening detection circuit 260 that detects the opening of the inner frame 12 or the opening of the front frame 14 includes a DC power supply DC1 that supplies a DC voltage of 12 volts, diodes D1 to D5, capacitors CD1 to CD4, and resistors R1 to R5. Timer IC1 (LMC555 manufactured by National Semiconductor), transistor TR1, FET1 to FET3, reset IC2 (BD4843 manufactured by ROHM Co., Ltd.), and NOTIC3 which is a logic negation circuit. doing.

  In order to detect the opening of the inner frame 12 when the switch SW1 is turned on and to detect the opening of the front frame 14 when the switch SW2 is turned on, the frame opening detection circuit 260 has the above components shown in FIG. Connected according to circuit diagram. Since the switch SW1 and the switch SW2 are connected in parallel and connected to the frame opening detection circuit 260, the frame opening detection circuit 260 is connected to the inner frame 12 or the front frame if either switch is turned on. 14 can be detected.

  The DC power source DC <b> 1 is a power source that supplies a DC voltage of 12 volts to the frame opening detection circuit 260. Power (power) to the DC power supply DC1 is supplied from a power supply unit 251 provided in the power supply device 115 through a power supply path (not shown). This DC power supply DC1 is connected to the anode terminal of the diode D1. One end of a 1F (farad) capacitor CD1 is connected to the cathode terminal of the diode D1. The other end of the capacitor CD1 is grounded. One end of the capacitor CD1 is connected to one end of the switch SW1, one end of the switch SW2, the VDD terminal of the timer IC1, and the RES terminal of the timer IC1.

  Capacitor CD1 exhibits the function of a rechargeable battery that supplies DC voltage to frame open detection circuit 260 when power supply to pachinko machine 10 is interrupted and DC voltage of 12 volts is not supplied from DC power supply DC1. It is a part.

  This is because the capacitor CD1 is applied to the capacitance 1F (farad) of the capacitor CD1 and the capacitor CD1 when power is supplied to the pachinko machine 10 and a DC voltage of 12 volts is supplied from the DC power source DC1. The charge obtained by the product of the DC voltage (about 11.3 volts obtained by subtracting about 0.7 volts from the diode D1 from 12 volts supplied from the DC power supply DC1) is stored.

  On the other hand, the capacitor CD1 is stored in the capacitor CD1, for example, when the business hours of the amusement hall are over and the power supply to the pachinko machine 10 is cut off and no DC voltage of 12 volts is supplied from the DC power supply DC1. The electric power based on the generated electric charge is supplied to the open frame detection circuit 260.

  Therefore, the frame opening detection circuit 260 operates naturally when power is supplied to the pachinko machine 10 and a DC voltage of 12 volts is supplied from the DC power supply DC1, and further, for example, a game hall business Even when the power supply to the pachinko machine 10 is interrupted and the DC voltage of 12 volts is not supplied from the DC power supply DC1, the inner frame is operated by the power supplied by the capacitor CD1. The opening of 12 and the opening of the front frame 14 can be detected. In the present embodiment, the capacitor CD1 is used as a component for supplying power to the open frame detection circuit 260 when a DC voltage of 12 volts is not supplied from the DC power supply DC1. However, the present invention is not limited to this, and the capacitor CD1 may be a secondary battery (rechargeable battery) with a larger amount of stored electricity or a primary battery that does not require charging.

  Further, the cathode terminal of the diode D1 is connected to one end of the capacitor CD1, and the diode D1 serves to prevent the backflow of current. Therefore, when power is supplied from the capacitor CD1 to the open frame detection circuit 260. However, the voltage generated with the electric power is not applied to the DC power source DC1, and the DC power source DC1 is not damaged.

  The timer IC1 is a C-MOS timer, and the inner frame 12 is opened or the front frame 14 is opened by connecting a 200 kΩ resistor R1, a 100 kΩ R2, a 22 μF capacitor CD2, and a 0.1 μF capacitor CD3. And functions as a circuit for making the transistor TR1 conductive for about 4.4 seconds. When the transistor TR1 is turned on, the drive voltage Vb having a maximum value of about 5 volts is started to be output from the power supply output terminal, the reset signal SG3b is started to be output from the reset signal output terminal, and the power failure is output from the power interruption signal output terminal. Output of the signal SG1b is started.

  The timer IC1, for example, is supplied with power by the capacitor CD1 when the business hours of the amusement hall are over and the power supply to the pachinko machine 10 is cut off and no DC voltage of 12 volts is supplied from the DC power supply DC1. The case where power is supplied to the pachinko machine 10 and the case where a DC voltage of 12 volts is supplied from the DC power source DC1 is also used. Therefore, of course, the timer IC 1 can operate at a DC voltage of 12 volts or less supplied to the frame opening detection circuit 260 when power is supplied to the pachinko machine 10. Furthermore, since the timer IC1 is a timer composed of a C-MOS semiconductor, power consumption during operation can be suppressed and operation can be performed for a long time.

  The VDD terminal of the timer IC1 is a terminal for inputting a DC voltage supplied to the timer IC1, and is connected to one end of the switch SW1, one end of the switch SW2, one end of the capacitor CD1, and the RES terminal of the timer IC1. The RES terminal of the timer IC 1 is a terminal for operating a reset function for forcibly stopping the voltage output from the OUT terminal (zero volts) when a pulse signal is input to the RES terminal. However, since this frame open detection circuit 260 does not use this reset function, the RES terminal of the timer IC 1 is connected to the VDD terminal of the timer IC 1 so that the reset function is not activated. Since the VDD terminal of timer IC1 and the RES terminal of timer IC1 are connected to one end of capacitor CD1 as described above, a DC voltage of about 11.3 volts is applied to the VDD terminal and RES terminal of timer IC1. Applied.

  When the switch SW1 and the switch SW2 are cut off (when the inner frame 12 and the front frame 14 are closed), the TRG terminal of the timer IC1 reduces the voltage output from the OUT terminal of the timer IC1. When one of the switches SW1 and SW2, or both of the switches SW1 and SW2 is in a conductive state, one of the inner frame 12 and the front frame 14, or When both the inner frame 12 and the front frame 14 are open), the voltage output from the OUT terminal of the timer IC 1 is set from about 10.6 volts to zero volts about 4.4 seconds after the conduction. It is a terminal to do. The TRG terminal of the timer IC1 is connected to the other end of the resistor R2.

  The resistor R2 connected to the TRG terminal of the timer IC1 is connected to the timer R1 when the inner frame 12 or the front frame 14 is in an open state and the switch SW1 or the switch SW2 is in a conductive state (see FIG. 5B). This is a resistor for applying a DC voltage (about 11.3 volts) to the TRG terminal of IC1. Note that the input impedance of the TRG terminal of the timer IC1 is sufficiently large with respect to the resistance value (100 kΩ) of the resistor R2, so that a voltage drop due to the resistor R2 hardly occurs. Therefore, when the switch SW1 or the switch SW2 becomes conductive, a voltage of about 11.3 volts supplied from one end of the capacitor CD1 is applied to the TRG terminal of the timer IC1.

  With the above connection, when the switch SW1 and the switch SW2 are in the cut-off state (when the inner frame 12 and the front frame 14 are in the closed state), no voltage is supplied to the resistor R2, so that the voltage is applied to the TRG terminal of the timer IC1. The voltage will be zero volts. At this time, the voltage output from the OUT terminal of the timer IC 1 is about 10.6 volts.

  On the other hand, when either the switch SW1 or the switch SW2 or both the switch SW1 and the switch SW2 are in a conductive state (either the inner frame 12 or the front frame 14 or both the inner frame 12 and the front frame 14 are Since the voltage is supplied to the resistor R2 (when in the open state), the voltage applied to the TRG terminal of the timer IC1 is about 11.3 volts, the same as the voltage applied to one end of the capacitor CD1. At this time, the voltage output from the OUT terminal of the timer IC1 is about 10.6 for about 4.4 seconds after either the switch SW1 or the switch SW2 or both the switch SW1 and the switch SW2 are turned on. It becomes a bolt, and then it becomes zero volts.

  In this way, the voltage output from the OUT terminal of the timer IC 1 can be set to about 10.6 volts or zero volts by the voltage applied to the TRG terminal of the timer IC 1. When the switch SW1 or the switch SW2 is turned on (the inner frame 12 or the front frame 14 is opened) and the voltage applied to the TRG terminal of the timer IC 1 changes from zero volts to about 11.3 volts, as described above, The voltage of about 10.6 volts output from the OUT terminal of the timer IC1 falls to zero volts after about 4.4 seconds from the rise of the voltage. As will be described in detail later, the transistor is determined by the time difference (about 4.4 seconds) between the rise of the voltage applied to the TRG terminal of the timer IC1 and the fall of the voltage output from the OUT terminal of the timer IC1. TR1 conducts for about 4.4 seconds.

  When the switch SW1 and the switch SW2 are cut off (the inner frame 12 and the front frame 14 are closed) and the voltage applied to the TRG terminal of the timer IC1 becomes zero volts, the OUT terminal of the timer IC1 has a voltage of about 10.6 volts. When the switch SW1 or the switch SW2 is turned on (the inner frame 12 or the front frame 14 is opened) and the voltage applied to the TRG terminal of the timer IC1 rises to about 11.3 volts, about This is a terminal for setting the output voltage of about 10.6 volts to zero volts with a delay of 4.4 seconds. This OUT terminal is connected to the gate terminal G of FET1 and the gate terminal G of FET2.

  The FET 1 is an N-MOS switching element that switches between conduction and interruption according to the voltage output from the OUT terminal of the timer IC 1. The drain terminal D of the FET 1 is connected to the other end of the 100 kΩ resistor R 3 and the base terminal b of the transistor TR 1. Connected. The emitter terminal e of the transistor TR1 is connected to one end of the resistor R3, one end of the resistor R2, and the input terminal of the NOTIC3. The collector terminal c of the transistor TR1 is connected to one end of the capacitor CD4, one end of the resistor R4, the anode terminal of the diode D3, and the anode terminal of the diode D4. The source terminal S of the FET 1 is connected to the cathode terminal of the Zener diode D2. The anode terminal of the Zener diode D2 is grounded.

  When the voltage output from the OUT terminal of the timer IC 1 is about 10.6 volts, the FET 1 (when the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have passed since the opening) When the inner frame 12 and the front frame 14 are closed), the drain terminal D and the source terminal S of the FET 1 are brought into conduction. On the other hand, when the voltage output from the OUT terminal of the timer IC 1 is zero volts (when the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have elapsed since the opening), the FET 1 The drain terminal D and the source terminal S are turned off.

  Here, three scenes of the operation of the FET1 and the operation of the transistor TR1 will be described in time series. First, the operation of the FET 1 and the operation of the transistor TR1 until about 4.4 seconds after the inner frame 12 or the front frame 14 is opened will be described. When the inner frame 12 or the front frame 14 is opened, the switch SW1 or the switch SW2 is in a conductive state. Therefore, until about 4.4 seconds elapse after the inner frame 12 or the front frame 14 is opened (switch The current supplied from the DC power source DC1 or the capacitor CD1 is supplied via the resistor R3 to the drain terminal D and the source terminal S of the FET 1 until about 4.4 seconds elapse after the SW1 or the switch SW2 is turned on. And flows into the cathode terminal of the Zener diode D2. Here, the limiting voltage of the Zener diode D2 is about 5.7 volts. When the drain terminal D and the source terminal S of the FET 1 are in a conductive state, the impedance between the drain terminal D and the source terminal S of the FET 1 is about several Ω. Therefore, the voltage at the base terminal b of the transistor TR1 is about 5.7 volts, which is substantially the same voltage as the limit voltage of the Zener diode D2. When a voltage is generated in the resistor R3, a bias voltage is applied to the base terminal b of the transistor TR1 and the emitter terminal e of the transistor. Therefore, the terminal between the emitter terminal e and the collector terminal c of the transistor TR1 is also conductive, and the current supplied from the DC power source DC1 or the capacitor CD1 flows from the emitter terminal e of the transistor TR1 to the collector terminal c. Here, when the base terminal b and the collector terminal c of the transistor TR1 are in a conductive state, the impedance between the base terminal b and the collector terminal c of the transistor TR1 is about several Ω. Therefore, until about 4.4 seconds have passed since the inner frame 12 or the front frame 14 was opened, the voltage at the collector terminal c of the transistor TR1 is about 5.7 which is substantially the same voltage as the limit voltage of the Zener diode D2. It becomes a bolt. By this operation, a voltage of about 5.7 volts is applied to the capacitor CD4 until about 4.4 seconds elapse after the inner frame 12 or the front frame 14 is opened, and the capacitor CD4 is charged, and the power supply A drive voltage Vb having a maximum value of about 5 volts (a voltage obtained by subtracting a voltage drop of 0.7 volts of the diode D3 from about 5.7 volts applied to the capacitor CD4) is started to be output from the output terminal, and from the reset signal output terminal The reset signal SG3b starts to be output, and the power failure signal SG1b starts to be output from the power interruption signal output terminal.

  Next, the operation of the FET 1 and the operation of the transistor TR1 when the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have elapsed from the opening will be described. When the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have passed since the opening, the drain terminal D and the source terminal S of the FET 1 are cut off. Therefore, even if the switch SW1 or the switch SW2 is in a conductive state, the current supplied from the DC power source DC1 or the capacitor CD1 does not flow into the resistor R3, and the voltage generated in the resistor R3 becomes zero. Therefore, the conduction between the emitter terminal e and the collector terminal c of the transistor TR1 is cut off. Accordingly, when the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have elapsed since the opening, the voltage at the collector terminal c of the transistor TR1 becomes zero volts. By this operation, the inner frame 12 or the front frame 14 is opened, and when about 4.4 seconds have elapsed since the opening, the voltage applied to the capacitor CD4 becomes zero volts, and the electric power stored in the capacitor CD4 is in a discharged state. .

  Finally, the operation of the FET1 and the operation of the transistor TR1 when the inner frame 12 and the front frame 14 are closed will be described. When the inner frame 12 and the front frame 14 are closed, the voltage output from the OUT terminal of the timer IC 1 becomes approximately 10.6 volts, and the drain terminal D and the source terminal S of the FET 1 are conducted, but the switch SW1 and the switch SW2 is in a cut-off state. Therefore, when the inner frame 12 and the front frame 14 are closed, the drain terminal D and the source terminal S of the FET 1 become conductive, but no current is supplied from the DC power source DC1 or the capacitor CD1, and the transistor TR1 The voltage between the base terminal b and the emitter terminal e is zero volts. Thereby, the conduction between the emitter terminal e and the collector terminal c of the transistor TR1 is cut off. Therefore, when the inner frame 12 and the front frame 14 are closed, no voltage is applied to the collector terminal c of the transistor TR1, and the voltage at the collector terminal c of the transistor TR1 is zero volts. With this operation, even when the inner frame 12 and the front frame 14 are closed, the voltage applied to the capacitor CD4 becomes zero volts, and the electric power stored in the capacitor CD4 is discharged.

  Returning to the description of FIG. Capacitor CD4 charges the electric power supplied via transistor TR1, and discharges the charged electric power, and has a capacitance value 1F for supplying electric power to the power supply output terminal and reset IC 2 excluding the power interruption signal output terminal ( Farad) capacitor. One end of the capacitor CD4 is connected to the collector terminal c of the transistor TR1, one end of the resistor R4, the anode terminal of the diode D3, and the anode terminal of the diode D4. On the other hand, the other end of the capacitor CD4 is grounded.

  By this connection, the capacitor CD4 is connected to the drain terminal D and the source terminal S of the FET 1 and the emitter terminal of the transistor TR1 until about 4.4 seconds have elapsed after the inner frame 12 or the front frame 14 is opened. e and the collector terminal c are conducted), so that electric power supplied from the DC power source DC1 or the capacitor CD1 via the transistor TR1 is stored. In the capacitor CD4, when the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have elapsed from the opening, the drain terminal D and the source terminal S of the FET 1 are cut off, and the emitter terminal of the transistor TR1 e and the collector terminal c are cut off), the stored power is discharged to supply power to the power output terminal and the reset IC 2. When the drain terminal D and the source terminal S of the FET 1 are in the cut-off state, naturally, the conduction between the drain terminal D and the source terminal S of the FET 2 is also cut off. It does not flow into the resistor R5. Therefore, the voltage accompanying the power discharged from the capacitor CD4 is not output to the power interruption signal output terminal. Therefore, the capacitor CD4 does not supply power to the power interruption signal output terminal, but supplies power to the power supply output terminal and the reset IC 2.

  The discharge time until the electric power stored in the capacitor CD4 becomes zero is the input impedance of the input terminal I23 of the multiplexer MP3 connected to the power supply output terminal and the power supply terminal of the MPU 201 connected to the output terminal O3 of the multiplexer MP3. Input impedance, input impedance of input terminal IN of reset IC2, input impedance of input terminal I22 of multiplexer MP2 connected to the output terminal of reset signal, and input impedance of reset terminal of MPU201 connected to output terminal O2 of multiplexer MP2. Etc. are determined. In the present embodiment, when the capacitor CD4 is fully charged, the discharge time until the fully charged power becomes zero is set to about 20 seconds. However, when the capacitor CD4 is fully charged, the discharge time until the fully charged power becomes zero is shorter than about 20 seconds or longer than about 20 seconds by adjusting the above impedance. May be set.

  The discharge of the electric power stored in the capacitor CD4 also occurs when the inner frame 12 or the front frame 14 is opened, about 4.4 seconds have passed since the opening, and the inner frame 12 and the front frame 14 are further closed. continue. When the inner frame 12 and the front frame 14 are closed, the voltage output from the OUT terminal of the timer IC 1 is about 10.6 volts, and the drain terminal D and the source terminal S of the FET 1 are conducted. The switches SW1 and SW2 are in the cut-off state. Therefore, when the inner frame 12 and the front frame 14 are closed, the drain terminal D and the source terminal S of the FET 1 are conducted, but no current is supplied from the DC power source DC1 or the capacitor CD1, and the base of the transistor TR1. The voltage between the terminal b and the emitter terminal e is zero volts. Accordingly, since the emitter terminal e and the collector terminal c of the transistor TR1 are cut off, the inner frame 12 or the front frame 14 is opened, and the capacitor CD4 is stored in the same manner as when about 4.4 seconds have elapsed since the opening. The discharged power is discharged to supply power to the power output terminal and the reset IC 2. Here, when the inner frame 12 and the front frame 14 are closed, the drain terminal D and the source terminal S of the FET 2 are in a conductive state as in the FET 1, and the power failure signal SG1b is output from the power interruption signal output terminal. In this case, since the drain terminal D and the source terminal S of the FET 3 described later are in a conductive state, the power failure signal SG1b is not output from the power interruption signal output terminal. This description will be described in detail later.

  In addition, when the electric power stored in the capacitor CD4 becomes zero, the discharge is naturally terminated (stopped). As a result, the power supplied from the capacitor CD4 to the power supply output terminal and the reset IC 2 is also stopped.

  The FET 2 is an N-MOS switching element that switches between conduction and cutoff according to the voltage output from the OUT terminal of the timer IC 1, as with the FET 1. The drain terminal D of the FET 2 is connected to the other end of the 100 kΩ resistor R 4. The One end of the resistor R4 is connected to one end of the capacitor CD4, the collector terminal c of the transistor TR1, the anode terminal of the diode D3, and the anode terminal of the diode D4. The source terminal S of the FET 2 is connected to the anode terminal of the backflow preventing diode D5 and one end of the 100 MΩ resistor R5. The other end of this resistor R5 is grounded. The cathode terminal of the diode D5 is connected to the power interruption signal output terminal.

  When the voltage output from the OUT terminal of the timer IC 1 is about 10.6 volts, the FET 2 (when the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have elapsed since its opening) When the inner frame 12 and the front frame 14 are closed), the drain terminal D and the source terminal S of the FET 2 are brought into conduction. On the other hand, when the voltage output from the OUT terminal of the timer IC1 is zero volts (when the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have elapsed since the opening), the FET2 The drain terminal D and the source terminal S are turned off.

  NOTIC3 is a logic negation circuit that applies a voltage to the gate terminal G of the FET3. The NOTIC3 has input terminals connected to the other end of the switch SW1, the other end of the switch SW2, one end of the resistor R1, one end of the resistor R2, and one end of the resistor R3. Further, the power supply terminal of the NOTIC 3 is connected to one end of the capacitor CD1, although not shown. Therefore, when the inner frame 12 or the front frame 14 is opened, the switch SW1 or the switch SW2 is turned on, and a voltage of about 11.3 volts is applied to the input terminal of the NOTIC3, zero volts is applied from the output terminal of the NOTIC3. Is output. On the other hand, when the inner frame 12 and the front frame 14 are closed, the switch SW1 and the switch SW2 are cut off, and zero volt is applied to the input terminal of the NOTIC3, a voltage of about 11.3 volts is applied from the output terminal of the NOTIC3. Is output.

  The FET 3 is an N-MOS switching element that controls the power failure signal SG1b output from the power interruption signal output terminal. The gate terminal G of the FET 3 is connected to the output terminal of the NOTIC 3. The drain terminal D of the FET 3 is connected to the anode terminal of the diode D5, and the source terminal S of the FET 3 is grounded. Therefore, when zero volt is output from the output terminal of NOTIC3, that is, when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on, the drain terminal D and the source terminal S of the FET3. Is interrupted. Therefore, when the inner frame 12 or the front frame 14 is opened, the power failure signal SG1b can be output from the power interruption signal output terminal. On the other hand, when a voltage of about 11.3 volts is output from the output terminal of the NOTIC 3, that is, when the inner frame 12 and the front frame 14 are closed and the switch SW1 and the switch SW2 are cut off, the drain of the FET 3 The terminals D and the source terminal S are electrically connected. Therefore, when the inner frame 12 or the front frame 14 is closed, the power failure signal SG1b cannot be output from the power interruption signal output terminal.

  Here, the operation of FET2 and FET3 will be described in time series in the same manner as in FET1. First, the operation of the FET2 and FET3 from when the inner frame 12 or the front frame 14 is opened until about 4.4 seconds have elapsed will be described. When the inner frame 12 or the front frame 14 is opened, the switch SW1 or the switch SW2 is in a conductive state. Therefore, until about 4.4 seconds elapse after the inner frame 12 or the front frame 14 is opened (switch The current supplied from the DC power source DC1 or the capacitor CD1 is supplied from the drain terminal D of the FET 2 and the source of the FET 2 through the resistor R4 until the SW1 or the switch SW2 is turned on (approximately 4.4 seconds). It passes between the terminals S and flows into the resistor R5. At this time, as described above, since the voltage of the collector terminal c of the transistor TR1 is about 5.7 volts, the voltage applied to one end of the resistor R4 is also about 5.7 volts. Here, when the drain terminal D and the source terminal S of the FET 2 are in a conductive state, the impedance between the drain terminal D and the source terminal S of the FET 2 is about several Ω. On the other hand, since the inner frame 12 or the front frame 14 is open, the conduction between the drain terminal D and the source terminal S of the FET 3 is interrupted. Therefore, the voltage of about 5.7 volts applied to one end of the resistor R4 is divided by the resistor R4 and the resistor R5. The resistance ratio between the resistors R4 and R5 is 1: 1000. Therefore, until about 4.4 seconds have passed after the inner frame 12 or the front frame 14 is opened, the voltage applied to the resistor R5 is about 5.7 volts, which is substantially the same voltage as the limit voltage of the Zener diode D2. It becomes. By this operation, the power failure signal SG1b is output from the power interruption signal output terminal until about 4.4 seconds have elapsed after the inner frame 12 or the front frame 14 is opened. At this time, the power failure signal SG1b output from the power interruption signal output terminal is about 5.0 volts obtained by subtracting about 0.7 volts from the diode D5 from about 5.7 volts applied to the resistor R5. It becomes.

  Further, until approximately 4.4 seconds have elapsed since the inner frame 12 or the front frame 14 was opened (until approximately 4.4 seconds have elapsed since the switch SW1 or the switch SW2 is turned on), the DC power source DC1 Alternatively, the voltage supplied from the capacitor CD1 is applied to the power supply signal output terminal via the diode D3 and also applied to the input terminal IN of the reset IC via the diode D4. Therefore, the drive voltage is output from the power signal output terminal, and the reset signal SG3b is also output from the reset signal output terminal.

  Next, the operation of the FET 2 and FET 3 when the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have elapsed since the opening is described. When the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have elapsed since the opening, the drain terminal D and the source terminal S of the FET 2 are cut off. At this time, as described above, since the conduction between the drain terminal D and the source terminal S of the FET 1 is also interrupted, even if the switch SW1 or the switch SW2 is in the conduction state, the emitter terminal e and the collector terminal of the transistor TR1. c is interrupted. Thereby, the voltage supply from the DC voltage DC1 or the capacitor CD1 is stopped. By stopping the voltage supply, the capacitor CD4 starts to be discharged. Here, if the drain terminal D and the source terminal S of the FET 2 are in a cut-off state, even if the conduction between the drain terminal D and the source terminal S of the FET 3 is in a cut-off state, the voltage accompanying the discharge of the capacitor CD4 is Not applied to the disconnect signal output terminal. Therefore, the power failure signal SG1b output from the power interruption signal output terminal is stopped. On the other hand, the voltage accompanying the discharge of the capacitor CD4 is applied to the power supply output terminal via the diode D3 and to the input terminal IN of the reset IC via the diode D4. By this operation, the inner frame 12 or the front frame 14 is opened, and when about 4.4 seconds have passed since the opening, the power failure signal SG1b output from the power interruption signal output terminal is stopped and output from the power output terminal. The drive voltage Vb and the reset signal SG3b output from the reset signal output terminal are continuously output. Note that when the electric power stored in the capacitor CD4 becomes zero due to discharge, the output of the drive voltage Vb and the reset signal SG3b output from the power supply output terminal is stopped.

  Finally, the operation of the FET2 and FET3 when the inner frame 12 and the front frame 14 are closed will be described. When the inner frame 12 and the front frame 14 are closed, the voltage output from the OUT terminal of the timer IC 1 becomes approximately 10.6 volts, and the drain terminal D and the source terminal S of the FET 2 become conductive, but the switch SW1 and the switch SW2 is in a cut-off state. Therefore, when the inner frame 12 and the front frame 14 are closed, the drain terminal D and the source terminal S of the FET 2 become conductive, but no power is supplied from the DC power source DC1 or the capacitor CD1, and the capacitor CD4 Discharging continues. Here, since the drain terminal D and the source terminal S of the FET 2 become conductive, a path is generated in which a current accompanying the discharge of the capacitor CD4 flows into the resistor R5. However, in this case, since the inner frame 12 and the front frame 14 are closed, the terminal between the drain terminal D and the source terminal S of the FET 3 is also conductive. When the terminal between the drain terminal D and the source terminal S of the FET 3 becomes conductive, the impedance between the drain terminal D and the source terminal S of the FET 3 becomes about several Ω, which is higher than the resistance value 100 MΩ of the resistor R5. The value is sufficiently small. Therefore, when the inner frame 12 and the front frame 14 are closed, the drain terminal D and the source terminal S of the FET 2 are brought into conduction, and a path for the current accompanying the discharge of the capacitor CD4 to flow into the resistor R5 is generated. Since the current accompanying the discharge of CD4 flows into the drain terminal D of the FET 3, no current flows into the resistor R5. Thereby, the power failure signal SG1b is not output from the power interruption signal output terminal. Accordingly, when the inner frame 12 and the front frame 14 are closed, the power failure signal SG1b output from the power interruption signal output terminal is stopped, while the drive voltage Vb output from the power output terminal and the reset signal output terminal. The reset signal SG3b output from is continuously output. As described above, when the electric power stored in the capacitor CD4 becomes zero due to discharge, the output of the drive voltage Vb and the reset signal SG3b output from the power supply output terminal is stopped).

  The reset IC 2 outputs the voltage input to the input terminal IN as it is from the output terminal OUT if the voltage input to the input terminal IN exceeds 4.3 volts, while the voltage input to the input terminal IN When the voltage is 4.3 volts or less, the reset semiconductor circuit stops voltage output from the output terminal OUT (sets the output voltage of the output terminal OUT to zero volts). The input terminal IN of the reset IC 2 is connected to the cathode terminal of the backflow prevention diode D4. The anode terminal of the diode D4 is connected to the anode terminal of the backflow preventing diode D3, and is connected to one end of the resistor R4, one end of the capacitor CD4, and the collector terminal c of the transistor TR1. The cathode terminal of the diode D3 is connected to the power output terminal. The output terminal OUT of the reset IC 2 is connected to the reset signal output terminal.

  Although the output terminal OUT of the reset IC 2 is directly connected to the reset signal output terminal, a backflow preventing diode may be connected to the output terminal OUT of the reset IC 2. In this case, the anode terminal of the backflow prevention diode may be connected to the output terminal OUT of the reset IC 2 and the cathode terminal of the backflow prevention diode may be connected to the reset signal output terminal.

  Here, the operation of the reset IC 2 will be described. When the inner frame 12 or the front frame 14 is opened and about 4.4 seconds have elapsed since the opening, the capacitor CD4 discharges the stored power and starts supplying power to the power output terminal and the reset IC 2. Since the power supplied from the capacitor CD4 decreases with the discharge time, the voltage generated by the discharge of the capacitor CD4 also decreases with the discharge time. Since only the backflow prevention diode D3 is connected between the power supply output terminal and the capacitor CD4, the voltage (drive voltage Vb) output to the power supply output terminal is generated by the discharge of the capacitor CD4. The voltage drops from the voltage by the forward voltage of the diode D3 (about 0.7 volts). On the other hand, the reset IC 2 is connected between the reset signal output terminal and the capacitor CD4 in addition to the connection of the backflow prevention diode D4. As a result, the voltage output to the reset signal output terminal (reset signal SG3b) is a voltage obtained by dropping the voltage generated by discharging the capacitor CD4 by the forward voltage of the diode D4 (about 0.7 volts). When the voltage exceeds 3 volts, that is, when the voltage input to the input terminal IN of the reset IC 2 exceeds approximately 4.3 volts, the input voltage itself is obtained. On the other hand, when the voltage dropped by the forward voltage of the diode D4 from the voltage generated by the discharge of the capacitor CD4 is about 4.3 volts or less, that is, the voltage input to the input terminal IN of the reset IC 2 Is about 4.3 volts or less, the voltage output to the reset signal output terminal is zero volts.

  Thus, if the voltage input to the input terminal IN exceeds about 4.3 volts, the reset IC 2 outputs the voltage input to the input terminal IN as it is from the output terminal OUT to the reset signal output terminal. When the voltage is output (the reset signal SG3b is output) and the voltage input to the input terminal IN is about 4.3 volts or less, the voltage output from the output terminal OUT is stopped and the reset signal output terminal is output. The output voltage is set to zero volts (the reset signal SG3b is stopped). Since the voltage (drive voltage Vb) output to the power supply output terminal can be 4.3 volts or less, the voltage generated by the discharge of the capacitor CD4 after the voltage output from the reset signal output terminal becomes zero volts. Is continuously output until the voltage reaches zero volts.

  Here, in order to terminate the MPU 201 normally, when the driving voltage Vb of about 5 volts is supplied to the power terminal of the MPU 201, the MPU 201 is first reset during the period of 10 clocks with the operation clock of the MPU 201. The reset signal SG3b input to the terminal is stopped to make it impossible to perform arithmetic processing, and then the drive voltage supplied to the power supply terminal of the MPU 201 is made to be about 4.0 volts or less to make the operation impossible. There is a need. For example, if the operation clock of the MPU 201 is 100 MHz, in order to terminate the MPU 201 normally, when the driving voltage Vb of 5 volts is supplied to the power terminal of the MPU 201, the MPU 201 is first input to the reset terminal of the MPU 201. The reset signal SG3b is stopped for at least 100 nsec to make it impossible to perform arithmetic processing, and then the drive voltage Vb supplied to the power supply terminal of the MPU 201 is set to about 4.0 volts or less to make the operation impossible There is a need to. In order to realize this, the frame opening detection circuit 260 first sets the voltage input to the input terminal IN of the reset IC 2 to about 4.3 volts or less and stops the reset signal SG3b output from the reset signal output terminal. As a result, the MPU 201 is set in an inoperable state, and thereafter, the drive voltage Vb output from the power supply output terminal is set to about 4.0 volts or less to make the MPU 201 inoperable. Here, in the frame opening detection circuit 260, after the reset signal SG3b output from the reset signal output terminal is stopped, the drive voltage Vb output from the power supply output terminal is about 4.0 volts or less. A period of 0.5 seconds is secured. Thus, even when the MPU 201 is temporarily started up by the frame opening detection circuit 260 when the power of the pachinko machine 10 is off, the MPU 201 that has started up is normally terminated by the frame opening detection circuit 260. Can do.

  In addition, when the voltage input to the input terminal IN of the reset IC 2 exceeds 4.3 volts, when the voltage is input to the input terminal IN of the reset IC 2, it is delayed by about 40 μs from the input of the voltage. Thus, a voltage is output from the output terminal OUT. Due to the delay characteristic of the reset IC 2, the reset signal SG3b output to the reset signal output terminal is output with a delay of about 40 μs from the drive voltage Vb output to the power supply output terminal.

  Here, in order to start up the MPU 201 normally, first, the driving voltage Vb of about 5 volts is supplied to the power terminal of the MPU 201 to make the MPU 201 operable, and then at least 10 clocks of the operation clock of the MPU 201. It is necessary to enter a reset signal SG3b to the reset terminal of the MPU 201 so that the arithmetic processing can be executed. For example, in order to normally start up the MPU 201 whose operation clock is 100 MHz, the MPU 201 is first brought into an operable state by supplying a driving voltage Vb of 5 volts to the power terminal of the MPU 201, and then at least 100 nsec. It is necessary to enter a reset signal SG3b to the reset terminal of the MPU 201 so that the arithmetic processing can be executed. In order to realize this, the frame open detection circuit 260 first outputs the drive voltage Vb of about 5 volts from the power output terminal, and outputs the reset signal SG3b from the reset signal output terminal about 40 μs after the output. Thereby, even when the MPU 201 is temporarily started up by the frame opening detection circuit 260 when the power of the pachinko machine 10 is off, the startup can be performed normally.

  The TH terminal of the timer IC1 is a terminal that measures a voltage applied to the TH terminal, and is connected to the other end of the resistor R1, one end of the capacitor CD2, and the DCH terminal of the timer IC1. The voltage applied to the TH terminal of the timer IC1 is 2/3 the voltage (about 7.5 volts) of the DC voltage (about 11.3 volts) input to the VDD terminal of the timer IC1. In this case, the impedance of the DCH terminal is switched from an infinite state to a zero state. When the impedance of the DCH terminal becomes zero (ground state), a voltage cannot be applied to the capacitor CD2. On the other hand, when the impedance of the DCH terminal is infinite, a voltage can be applied to the capacitor CD2.

  The resistor R1 and the capacitor CD2 connected to the TH terminal of the timer IC1 and the DCH terminal of the timer IC1 open the inner frame 12 or the front frame 14 based on the time constant that is the product of the resistance value of the resistor R1 and the capacitor CD2. In this case, it is a component for determining the period until the voltage of about 10.6 volts output from the OUT terminal of the timer IC 1 is switched to zero volts to about 4.4 seconds. One end of the resistor R1 is connected to the other end of the switch SW1, the other end of the switch SW2, one end of the resistor R2, the input terminal of the NOTIC3, one end of the resistor R3, and the emitter terminal e of the transistor TR1. The other end of the resistor R1 is connected to the TH terminal of the timer IC1, the DCH terminal of the timer IC1, and one end of the capacitor CD2. The other end of the capacitor CD2 is grounded.

  Here, the resistor R1 and the capacitor CD2 will be described together with the TRG terminal of the timer IC1, the TH terminal of the timer IC1, the DCH terminal of the timer IC1, and the OUT terminal of the timer IC1.

  When the inner frame 12 and the front frame 14 are in the closed state (when the switch SW1 and the switch SW2 are in the cut-off state), no voltage is supplied to the resistor R1, so the voltage applied to the TH terminal of the timer IC1 is zero volts (about 7.5 volts). Thus, the impedance of the DCH terminal of the timer IC 1 is set to an infinite state. Therefore, a voltage can be applied to the capacitor CD2, and the capacitor CD2 is in a chargeable state (a state in which charge can be stored). However, when the switch SW1 and the switch SW2 are cut off, the connection between one end of the capacitor CD1 and the resistor R1 is cut off, so that no voltage is applied to the capacitor CD2, and the voltage applied to the capacitor CD2 is zero volts. It becomes. As described above, the capacitor CD2 is in a chargeable state but is not charged. At this time, the voltage at the OUT terminal of the timer IC 1 is about 10.6 volts, and the gap between the drain terminal D and the source terminal S of the FET 1 and the terminal between the drain terminal D and the source terminal S of the FET 2 are Conducted. However, since the switch SW1 and the switch SW2 are in the cut-off state, no voltage is generated in the resistor R3 (between the base terminal b and the emitter terminal e of the transistor TR1), and the emitter terminal e and the collector terminal c of the transistor TR1. And is cut off. Further, since the inner frame 12 and the front frame 14 are in a closed state, the terminals between the drain terminal D and the source terminal D of the FET 3 are in a conductive state. Therefore, the power from the capacitor CD4 can be supplied to the power output terminal and the reset IC 2 excluding the power interruption signal output terminal (when the power stored in the capacitor CD4 is zero due to discharge, the power Supply is not performed).

  Next, when the inner frame 12 or the front frame 14 is opened (see FIG. 5B) and the switch SW1 or the switch SW2 is turned on, the voltage applied to the TRG terminal of the timer IC1 is from zero volts. Switch to approximately 11.3 volts. At this time, the voltage at the OUT terminal of the timer IC1 is about 10.6 volts, and the terminal between the drain terminal D and the source terminal S of the FET1 and the terminal between the drain terminal D and the source terminal S of the FET2 are conductive. doing. A voltage is generated in the resistor R3 (between the base terminal b and the emitter terminal e of the transistor TR1), and the emitter terminal e and the collector terminal c of the transistor TR1 are conducted. As a result, a voltage of about 5.7 volts is generated at the collector terminal c of the transistor TR1, and the generated voltage becomes about 5.0 volts via the diode D3 and is output to the power output terminal. Further, the voltage of about 5.7 volts generated at the collector terminal c of the transistor TR1 becomes about 5.0 volts via the diode D4 and the reset IC2, and is output to the reset signal output terminal. In addition, since the inner frame 12 or the front frame 14 is in an open state and the drain terminal D and the source terminal D of the FET 3 are cut off, about 5.7 volts generated at the collector terminal c of the transistor TR1. The voltage becomes approximately 5.0 volts via the diode D5 and is output to the power interruption signal output terminal. Further, charging of the capacitor CD4 is started by a voltage of about 5.7 volts generated at the collector terminal c of the transistor TR1.

  At the same time that the voltage applied to the TRG terminal of the timer IC1 is switched from zero volts to about 11.3 volts, the voltage is applied to the capacitor CD2, and charging of the capacitor CD2 is started. At this time, the voltage applied to the TH terminal of the timer IC1 starts to rise.

  The voltage at the OUT terminal of timer IC1 is 2 / of the voltage applied to the TH terminal of timer IC1 (voltage applied to capacitor CD2) to the voltage (approximately 11.3 volts) input to the VDD terminal of timer IC1. Continue to maintain about 10.6 volts until equal to a voltage of 3, ie, about 7.5 volts. When the voltage applied to the TH terminal of the timer IC1 (the voltage applied to the capacitor CD2) rises and becomes equal to about 7.5 volts, the impedance of the DCH terminal of the timer IC1 is changed from an infinite state to a zero state (ground To the ( Then, the voltage applied to the capacitor CD2 becomes a zero volt state, and the electric charge stored in the capacitor CD2 is discharged. As a result, the voltage applied to the TH terminal of the timer IC 1 is switched from about 7.5 volts to zero volts. By switching the voltage applied to the TH terminal of the timer IC1, the voltage of the OUT terminal of the timer IC1 is switched from about 10.6 volts to zero volts. Then, the conduction between the drain terminal D and the source terminal S of the FET 1 and between the drain terminal D and the source terminal S of the FET 2 are interrupted, and the resistor R3 (the base terminal b and the emitter terminal e of the transistor TR1) is disconnected. The voltage generated between the terminals is zero volts. Thereby, the capacitor CD4 discharges the stored electric power and supplies the electric power to the power output terminal and the reset IC2.

  As described above, when the inner frame 12 or the front frame 14 is in an open state and the switch SW1 or the switch SW2 is in a conductive state (see FIG. 5B), the signal is output from the OUT terminal of the timer IC1. A period until the voltage of about 10.6 volts is switched to zero volts, that is, a period until the voltage applied to the TH terminal of the timer IC1 (voltage applied to the capacitor CD2) changes from zero volts to about 7.5 volts. Based on the time constant which is the product of the resistance value of the resistor R1 and the capacitance of the capacitor CD2, it is determined to be about 4.4 seconds. Then, when the inner frame 12 or the front frame 14 is opened, the frame open detection circuit 260 outputs a voltage to the power output terminal, the reset signal output terminal, and the power interruption signal output terminal for about 4.4 seconds. To do. When about 4.4 seconds elapse after the inner frame 12 or the front frame 14 is opened, the frame open detection circuit 260 applies a voltage of about 10.6 volts output from the OUT terminal of the timer IC1. Switching to zero volts cuts off the conduction between the emitter terminal e and the collector terminal c of the transistor TR1, stops the voltage output to the power interruption signal output terminal, and starts discharging the capacitor CD4. As a result, the frame open detection circuit 260 is connected to the power supply output terminals excluding the power interruption signal output terminal due to the discharge of the capacitor CD4 when about 4.4 seconds elapse after the inner frame 12 or the front frame 14 is opened. And outputs a voltage to the reset signal output terminal. As described above, when the voltage input to the input terminal IN of the reset IC 2 becomes about 4.3 volts or less due to the discharge of the capacitor CD4, the reset IC 2 outputs the voltage output from the output terminal OUT, that is, the reset signal output. Set the terminal voltage to zero volts. On the other hand, the voltage at the power output terminal is output until the discharge by the capacitor CD4 stops. Therefore, when about 4.4 seconds elapse after the inner frame 12 or the front frame 14 is opened, the frame open detection circuit 260 first applies a voltage (power failure signal SG1b) output to the power interruption signal output terminal. Next, the voltage output to the reset signal output terminal (reset signal SG3b) is stopped, and finally, the voltage output to the power supply output terminal (drive voltage Vb) is stopped. Therefore, even when the MPU 201 is temporarily activated when the pachinko machine 10 is powered off, the frame opening detection circuit 260 can normally terminate the activated MPU 201.

  In addition, after about 4.4 seconds have passed since the inner frame 12 or the front frame 14 is opened, the inner frame 12 and the front frame 14 are closed from the open state (the switches SW1 and SW2 are disconnected from the conductive state). In other words, when the voltage applied to the TRG terminal of the timer IC1 switches from about 11.3 volts to zero volts, the voltage at the OUT terminal of the timer IC1 switches from zero volts to about 10.6 volts. In this state, as described above, the terminal between the drain terminal D and the source terminal S of the FET 1 and the terminal between the drain terminal D and the source terminal S of the FET 2 are conductive, but the switch SW1 and the switch SW2 are cut off. Therefore, no power is supplied from the DC power source CD1 or the capacitor CD1, and the discharge state of the capacitor CD4 continues. When the inner frame 12 or the front frame 14 is in a closed state, the drain terminal D and the gate terminal S of the FET 3 are electrically connected, so that the voltage due to the discharge of the capacitor CD4 is the power output terminal, It is applied to the input terminal IN of the reset IC2.

  Here, when the power of the pachinko machine 10 is off, the inner frame 12 or the front frame 14 is opened, and before the elapse of about 4.4 seconds from the opening, the inner frame 12 and the front frame 14 are closed, When the switch SW1 and the switch SW2 are cut off, the voltage at the OUT terminal of the timer IC1 remains at about 10.6 volts without switching to zero volts. However, also in this case, the frame opening detection circuit 260 can stop the power failure signal SG1b, then stop the reset signal SG3b, and finally stop the drive voltage Vb. This case will be described. First, when the inner frame 12 or the front frame 14 is in an open state and the switch SW1 or the switch SW2 is turned on, the frame open detection circuit 260 has a power output terminal, a reset signal output terminal, and a power interruption signal output, as described above. A voltage is output to the terminal and the capacitor CD4 is charged. When the inner frame 12 and the front frame 14 are closed within about 4.4 seconds from the open state, the switches SW1 and SW2 are switched from the conductive state to the cut-off state, so that the emitter terminal e and the collector terminal c of the transistor TR1. And the discharge of the capacitor CD4 is started. Here, since the inner frame 12 and the front frame 14 are in a closed state, the drain terminal D and the source terminal S of the FET 3 are electrically connected. Therefore, when the inner frame 12 and the front frame 14 are closed, the voltage due to the discharge of the capacitor CD4 is not applied to the power interruption signal output terminal, so that the power failure signal SG1b is stopped. On the other hand, the voltage generated by the discharge of the capacitor CD4 is applied to the power supply output terminal and the input terminal IN of the reset IC2. Thereafter, the voltage accompanying the discharge of the capacitor CD4 decreases with time, the reset signal SG3b output from the reset signal output terminal is stopped, and finally the drive voltage Vb output from the power supply output terminal is stopped. . By this operation, even if the inner frame 12 and the front frame 14 are closed within about 4.4 seconds after the inner frame 12 or the front frame 14 is opened, the frame open detection circuit 260 It is possible to stop the power failure signal SG1b, then stop the reset signal SG3b, and finally stop the drive voltage Vb. Therefore, when the power of the pachinko machine 10 is off, the inner frame 12 or the front frame 14 is opened, and the inner frame 12 and the front frame 14 are closed before approximately 4.4 seconds from the opening, and the switch Even when the switch SW1 and the switch SW2 are shut off, the frame opening detection circuit 260 can normally terminate the started MPU 201 even if the MPU 201 is temporarily started.

  Returning to the description of FIG. The CNT terminal of the timer IC 1 is a terminal that adjusts the output period of the voltage output from the OUT terminal of the timer IC 1 by a signal input to the CNT terminal. The CNT terminal of the timer IC1 is connected to one end of the capacitor CD3. The other end of the capacitor CD3 is grounded. In this frame open detection circuit 260, the output period of the voltage output from the OUT terminal of the timer IC1 is not adjusted (the output period of the voltage output from the OUT terminal of the timer IC1 is fixed to about 4.4 seconds). The CNT terminal of the timer IC1 is AC-grounded by the capacitor CD3.

  As described above, when the power of the pachinko machine 10 is off, the frame opening detection circuit 260 opens the inner frame 12 or the front frame 14 and turns on the switch SW1 or the switch SW2 (see FIG. 5 (b)), and outputs a voltage to the power output terminal, the reset signal output terminal, and the power interruption signal output terminal. On the other hand, the frame open detection circuit 260 first stops the voltage (power failure signal SG1b) output to the power interruption signal output terminal when about 4.4 seconds have elapsed after the inner frame 12 or the front frame 14 is in the open state. At the same time, the capacitor CD4 starts to discharge, thereafter, the voltage output to the reset signal output terminal (reset signal SG3b) is stopped, and finally the drive voltage Vb output to the power supply output terminal is stopped. Therefore, even if the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily activated when the power of the pachinko machine 10 is off, the frame opening detection circuit 260 does not start the MPU 201 that has been activated. It can be completed normally.

  Although details will be described later, when the pachinko machine 10 is powered off, if the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily activated by the frame open detection circuit 260, the pachinko machine 10 turns off the off-in-frame release flag 203a. When the off-in-frame release flag 203a is turned on, the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned off can be specified. Although details will be described later, when the power of the pachinko machine 10 is off, when the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily activated by the frame open detection circuit 260, the pachinko machine 10 outputs a pulse signal having a pulse width of 1 msec to the hall computer 262 in addition to turning on the off-in-frame opening flag 203a. The output pulse signal is stored in the hall computer 262 that continues to operate for 24 hours.

  Here, there is a case where the game hall has a security contract with a private security company. In this case, if there is an intruder into the game hall, the security company's guards immediately rush to the game hall. However, fraudulent acts are carried out in a short time, so when security guards rush, in most cases the intruder has already escaped from the playground. Therefore, even if a security contract is signed with a private security company, there is a problem that it is impossible to determine which pachinko machine 10 has been cheated. The pachinko machine 10 that has been cheated must return to a normal state, but if it is not known which pachinko machine 10 has been cheated, the inner frame 12 and the front frame 14 of all the pachinko machines 10 are Opening them and inspecting them one by one was a heavy hard work to do in a game hall where many pachinko machines 10 were installed.

  However, according to the pachinko machine 10 of the present embodiment, when the power of the pachinko machine 10 is off, the inner frame 12 or the front frame 14 is opened, and the MPU 201 is temporarily activated by the frame open detection circuit 260. Then, in addition to turning on the off-in-frame opening flag 203a, a pulse signal having a pulse width of 1 msec is output to the hall computer 262. The output pulse signal is stored in the hall computer 262 that continues to operate for 24 hours. Therefore, the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened can also be specified by the pulse signal stored in the hall computer 262. Furthermore, the hall computer 262 outputs a pulse signal from the pachinko machine 10 and stores the output time of the output pulse signal, thereby allowing the inner frame 12 of the specified pachinko machine 10 to be opened or the front frame. 14 open times can be detected.

  However, as described above, when the power of the pachinko machine 10 is off, when the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily activated by the frame open detection circuit 260, the off-in-frame frame is released. Since the flag 203a is turned on, the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned off can be specified without using the hall computer 262. is there. Therefore, according to the pachinko machine 10 of the present embodiment, the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is off even in a game hall where the hall computer 262 has not been operated for 24 hours. And the pachinko machine 10 can be specified.

  Further, as described above, the frame opening detection circuit 260 is provided with the 1F capacitor CD1, so that the frame opening detection circuit 260 is supplied with power to the pachinko machine 10 and is supplied with 12 volts from the DC power supply DC1. Naturally, when a DC voltage is supplied, for example, the game hall is closed and power supply to the pachinko machine 10 is cut off, and a DC voltage of 12 volts is supplied from the DC power supply DC1. Even if not, the MPU 201 can be started up for a certain period of time by detecting the opening of the inner frame 12 and the opening of the front frame 14.

  For example, when the business hours of the amusement hall are over and the power supply to the pachinko machine 10 is cut off, and the DC voltage is supplied from the capacitor CD1 to the frame opening detection circuit 260, the inner frame 12 or the front frame 14 When the total supply period of the current from the capacitor CD1 due to opening is increased or the number of times of detecting the opening of the inner frame 12 or the front frame 14 is increased, the capacitance of the capacitor CD1 is increased (for example, the capacitor The capacity of CD1 is assumed to be 10F), and the capacitor CD1 may be changed to a secondary battery having a large charged amount.

  However, the amount that the frame opening detection circuit 260 consumes the power of the capacitor CD1 in a state where the power of the pachinko machine 10 is turned off and the inner frame 12 and the front frame 14 are closed is the standby power of the timer IC1 and the power consumption of the NOTIC3. Therefore, it does not cause a significant decrease in the charge amount of the capacitor CD1. Moreover, since only a voltage is applied to each gate terminal G in FET1 to FET3, the power consumed in FET1 to FET3 is very small. Therefore, the frame opening detection circuit 260 can be manufactured at low cost by setting the capacitance of the capacitor CD1 to 1F, which is widely used.

  In the door opening detection circuit 260, an LMC 555 is used for the timer IC 1 to detect the opening of the inner frame 12 or the opening of the front frame 14 and realize a circuit for making the transistor TR1 conductive for about 4.4 seconds. It is not limited to. That is, by using another integrated circuit or the like for the timer IC 1, a circuit that generates one pulse signal for one opening of the inner frame 12 or one opening of the front frame 14 is realized. What is necessary is just to energize transistor TR1 for a predetermined period based on a pulse signal.

  Next, referring to FIG. 8, while the pachinko machine 10 is powered off, either the inner frame 12 or the front frame 14 is opened and both the inner frame 12 and the front frame 14 are opened. An explanation will be given of the case. FIG. 8 shows the voltage at the TRG terminal of the timer IC1 and the voltage at the OUT terminal of the timer IC1 that change according to the state of the switch SW1 (the state of the inner frame 12) and the state of the switch SW2 (the state of the front frame 14). , The voltage of the capacitor CD4, the voltage of the power supply output terminal of the frame opening detection circuit 260 (output voltage to the multiplexer MP3), and the voltage of the reset signal output terminal of the frame opening detection circuit 260 (to the multiplexer MP2 and the input / output port 205) 6 is a timing chart showing the relationship between the output voltage) and the voltage at the power interruption signal output terminal of the frame open detection circuit 260 (output voltage to the multiplexer MP1). Note that A in FIG. 8F is an enlarged view of the voltage at the reset signal output terminal of the frame opening detection circuit 260 that changes from about t1 to about 0.01 seconds later. 8A, the voltage of the reset signal output terminal from t1 to about 0.01 second is illustrated, but from t3 to about 0.01 second, from t5 to about 0.01 second. The voltage of the reset signal output terminal until later and from about t7 to about 0.01 second later has the same waveform as the voltage of the reset signal output terminal from about t1 to about 0.01 second later, so illustration is omitted. doing.

  First, as shown in FIG. 8A, when the switch SW1 becomes conductive (the inner frame 12 is in an open state) at t1, as shown in FIG. 8C, the TRG terminal voltage of the timer IC1 is t1. Sometimes it switches from zero volts to about 11.3 volts. At this time, as shown in FIG. 8D, the timer IC1 continues to output a voltage of about 10.6 volts from the OUT terminal until about 4.4 seconds have elapsed since t1. As a result, the emitter terminal e and the collector terminal c of the transistor TR1 (see FIG. 7) become conductive, and charging of the capacitor CD4 (see FIG. 7) is started (at time t1) as shown in FIG. 8 (e). . This charging is completed in about 0.01 seconds after the switch SW1 becomes conductive as shown in FIG. 8 (e). When the charging of the capacitor CD4 is completed, the voltage of the capacitor CD4 becomes about 5.7 volts as shown in FIG. In addition, it takes about 0.01 seconds to charge the capacitor CD4, but it is physically impossible to open and close the inner frame 12 or the front frame 14 within about 0.01 seconds. Therefore, when the inner frame 12 or the front frame 14 is opened, the charging of the capacitor CD4 is always completed.

  Further, the voltage at the power supply output terminal of the frame open detection circuit 260 (output voltage to the input terminal I23 of the multiplexer MP3) starts to rise at t1 and is about 0 from t1 as shown in FIG. 8 (f). It will be about 5.0 volts after 0.01 second. As a result, the drive voltage Vb of about 5.0 volts is started to be output from the power output terminal of the frame opening detection circuit 260. The voltage at the reset signal output terminal of the frame opening detection circuit 260 (the output voltage to the input terminal I22 and the input / output port 205 of the multiplexer MP2) is as shown in A of FIGS. 8 (g) and 8 (f). The rise starts about 40 μs after t1, and becomes about 5.0 volts after about 0.01 seconds from t1. Thereby, the reset signal SG3b starts to be output from the reset signal output terminal of the frame opening detection circuit 260. Note that the voltage increase at the reset signal output terminal of the frame opening detection circuit 260 is about 40 μsec after t1 due to the delay characteristic of the reset IC 2 (see FIG. 7). As shown in FIGS. 8F and 8G, the voltage increase at the power supply output terminal of the frame open detection circuit 260 is about 40 μs earlier than the voltage increase at the reset signal output terminal of the frame open detection circuit 260. After the drive voltage Vb of about 5 volts is supplied to the power terminal of the MPU 201, the reset signal SG3b is input to the reset signal output terminal of the MPU 201. Therefore, the frame opening detection circuit 260 can normally start up the MPU 201 when the pachinko machine 10 is powered off.

  Although details will be described later, when the pachinko machine 10 is powered off, if the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily activated by the frame open detection circuit 260, the pachinko machine 10 turns off the off-in-frame release flag 203a. When the off-in-frame release flag 203a is turned on, the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened can be specified. Although details will be described later, when the power of the pachinko machine 10 is off, when the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily activated by the frame open detection circuit 260, the pachinko machine 10 outputs a pulse signal having a pulse width of 1 msec to the hall computer 262. The output pulse signal is stored in the hall computer 262 that continues to operate for 24 hours.

  Further, as shown in FIG. 8E, when the voltage of the capacitor CD4 reaches about 5.7 volts, the voltage at the power interruption signal output terminal of the open frame detection circuit 260 (the output voltage to the input terminal I21 of the multiplexer MP1). As shown in FIG. 8 (h), the rise starts at t1, and becomes about 5.0 volts about 0.01 seconds after t1. Here, since the switch SW1 is in a conductive state (the inner frame 12 is in an open state), the terminal between the drain terminal D and the source terminal S of the FET 3 is blocked. As a result, the power failure signal SG1b is started to be output from the power interruption signal output terminal of the frame opening detection circuit 260.

  When about 4.4 seconds elapse from t1, the timer IC1 switches the voltage at the OUT terminal from about 10.6 volts to zero volts as shown in FIG. 8 (d). Then, the conduction between the drain terminal D and the source terminal S of the FET1 is cut off, and the conduction between the emitter terminal e and the collector terminal c of the transistor TR1 (see FIG. 7) is cut off, so that the charging of the capacitor CD4 is completed. To do. Then, since the discharge of the capacitor CD4 is started, as shown in FIG. 8E, the voltage of the capacitor CD4 starts to drop (after about 4.4 seconds have elapsed from time t1). Following this, as shown in FIG. 8 (f), the voltage at the power supply output terminal of the open frame detection circuit 260 (the drive voltage Vb having a maximum value of about 5.0 volts) starts to drop (from t1). After about 4.4 seconds). Further, as shown in FIG. 8G, the voltage (reset signal SG3b) at the reset signal output terminal of the frame opening detection circuit 260 starts to drop (after about 4.4 seconds have elapsed from t1).

  When about 4.4 seconds elapse from t1, the conduction between the drain terminal D and the source terminal S of the FET 2 is cut off, so that no current is supplied to the power interruption signal output terminal of the frame opening detection circuit 260. Therefore, as shown in FIG. 8 (h), the voltage at the power interruption signal output terminal of the frame opening detection circuit 260 (the power failure signal SG1b) becomes zero volts when about 4.4 seconds have elapsed since t1. Therefore, when about 4.4 seconds elapse after the inner frame 12 is opened and the switch SW1 is turned on, the power failure signal SG1b output from the power interruption signal output terminal of the frame opening detection circuit 260 to the NMI terminal of the MPU 201 is Stopped.

  Next, when about 9.4 seconds have elapsed from time t1 (after about 4.4 seconds have elapsed from time t1, and further about 5.0 seconds have elapsed), as shown in FIG. Drops to about 5.0 volts. Then, as shown in FIG. 8 (f), the voltage of the power supply output terminal of the open frame detection circuit 260 (the drive voltage Vb having a maximum value of about 5.0 volts) drops to about 4.3 volts (from t1). After about 9.4 seconds). Further, as shown in FIG. 8 (g), the voltage (reset signal SG3b) at the reset signal output terminal of the frame opening detection circuit 260 drops to about 4.3 volts, and thereafter, the reset IC 2 operates to zero volts. (After about 9.4 seconds from t1). Therefore, when about 9.4 seconds have elapsed after the inner frame 12 is opened and the switch SW1 is turned on, the reset signal SG3b output from the reset signal output terminal of the frame open detection circuit 260 to the reset terminal of the MPU 201 is the power failure signal. Next to SG1b, it is stopped. As a result, the MPU 201 is set in a state where it cannot execute the arithmetic processing (after about 9.4 seconds have elapsed since t1).

  Further, when about 9.9 seconds elapse from t1 (after about 9.4 seconds elapse from t1 and further about 0.5 seconds elapse), as shown in FIG. Drop to about 4.7 volts. Then, as shown in FIG. 8 (f), the voltage at the power output terminal of the open frame detection circuit 260 (the drive voltage Vb having a maximum value of about 5.0 volts) drops to about 4.0 volts (from t1). After about 9.9 seconds). Here, the lower limit value of the operating voltage of the MPU 201 is about 4.0 volts. Therefore, when about 9.9 seconds have elapsed after the inner frame 12 is opened and the switch SW1 is turned on, the drive voltage Vb output from the power supply output terminal of the frame open detection circuit 260 to the power supply terminal of the MPU 201 is finally It is stopped and the MPU 201 becomes inoperable. That is, the MPU 201 is set in an inoperable state (after about 9.4 seconds have elapsed from t1) after being set in a state where execution of arithmetic processing is impossible (after about 9.4 seconds from t1). After). Therefore, even if the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off and the MPU 201 is temporarily activated by the frame opening detection circuit 260, the frame opening detection circuit 260 The launched MPU 201 can be normally terminated.

  When about 20 seconds elapse from t1, the voltage of the capacitor CD4 becomes zero volts as shown in FIG. 8 (e). Following this, the voltage at the power supply output terminal of the frame opening detection circuit 260 (also the drive voltage Vb) becomes zero volts (before about 20 seconds have elapsed since t1). Therefore, when about 20 seconds elapse from t1, the charge amount of the capacitor CD4 becomes zero.

  Finally, as shown in FIG. 8 (a), when the switch SW1 is cut off (the inner frame 12 is closed) at t2, as shown in FIG. 8 (c), the TRG terminal voltage of the timer IC1 is reduced to about At the same time as switching from 11.3 volts to zero volts, the OUT terminal voltage of the timer IC 1 switches from zero volts to about 10.6 volts (at time t2). Also, at t2, when the switch SW1 is cut off (the inner frame 12 is closed), the terminal between the drain terminal D and the source terminal S of the FET 3 becomes conductive. As a result, the frame opening detection circuit 260 is set again to a state in which the inner frame 12 and the front frame 14 can be detected.

  Next, as shown in FIG. 8B, when the switch SW2 is in a conductive state (the front frame 14 is in an open state) at t3, as shown in FIG. 8C, the TRG terminal voltage of the timer IC1 is At t3, the voltage switches from zero volts to about 11.3 volts. At this time, as shown in FIG. 8D, the timer IC1 continues to output a voltage of about 10.6 volts from the OUT terminal until about 4.4 seconds have elapsed since t3. As a result, the terminals of the emitter terminal e and the collector terminal c of the transistor TR1 (see FIG. 7) become conductive, and charging of the capacitor CD4 (see FIG. 7) is started as shown in FIG. 8 (e) ( t3). This charging is completed in about 0.01 seconds after the switch SW2 becomes conductive as shown in FIG. 8 (e). When the charging of the capacitor CD4 is completed, the voltage of the capacitor CD4 becomes about 5.7 volts as shown in FIG.

  Further, the voltage at the power supply output terminal of the frame opening detection circuit 260 (the output voltage to the input terminal I2 of the multiplexer MP3) starts to rise at t3 and is about 0 from t3 as shown in FIG. 8 (f). It will be about 5.0 volts after .01 seconds. As a result, the drive voltage Vb having a maximum value of about 5.0 volts is started to be output from the power supply output terminal of the frame opening detection circuit 260. Further, the voltage at the reset signal output terminal of the frame opening detection circuit 260 (the output voltage to the input terminal I2 of the multiplexer MP2 and the input / output port 205) is about 40 μs after t3 as shown in FIG. 8 (g). Ascending starts (see A in FIG. 8 (f)), and becomes about 5.0 volts after about 0.01 seconds from t3. As a result, the reset signal SG3 starts to be output from the reset signal output terminal of the frame opening detection circuit 260. Note that the voltage rise at the reset signal output terminal of the frame opening detection circuit 260 is about 40 μsec after t3, as described above, due to the delay characteristics of the reset IC 2 (see FIG. 7). As shown in FIGS. 8F and 8G, the voltage increase at the power supply output terminal of the frame open detection circuit 260 is about 40 μs earlier than the voltage increase at the reset signal output terminal of the frame open detection circuit 260. After the drive voltage Vb of about 5 volts is supplied to the power terminal of the MPU 201, the reset signal SG3b is input to the reset signal output terminal of the MPU 201. Therefore, when the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily started when the power of the pachinko machine 10 is turned off, the startup can be performed normally.

  Further, as shown in FIG. 8 (e), when the voltage of the capacitor CD4 becomes about 5.7 volts, the voltage of the power interruption signal output terminal of the open frame detection circuit 260 (the output voltage to the input terminal I2 of the multiplexer MP1). As shown in FIG. 8 (h), the rise starts at t3 and becomes about 5.0 volts about 0.01 seconds after t3. Here, since the switch SW2 is in a conductive state (the front frame 14 is in an open state), the terminal between the drain terminal D and the source terminal S of the FET 3 is blocked. As a result, the power failure signal SG1b is started to be output from the power interruption signal output terminal of the frame opening detection circuit 260.

  When about 4.4 seconds elapse from time t3, the timer IC1 switches the voltage at the OUT terminal from about 10.6 volts to zero volts as shown in FIG. 8 (d). Then, the conduction between the drain terminal D and the source terminal S of the FET 1 is cut off, and the conduction between the emitter terminal e and the collector terminal c of the transistor TR1 (see FIG. 7) is cut off. Charging to CD4 ends. Then, since the discharge of the capacitor CD4 is started, as shown in FIG. 8E, the voltage of the capacitor CD4 starts to drop (after about 4.4 seconds have elapsed from t3). Following this, as shown in FIG. 8 (f), the voltage at the power supply output terminal of the open frame detection circuit 260 (the driving voltage Vb having a maximum value of about 5.0 volts) starts to drop (from t3). After about 4.4 seconds). Further, as shown in FIG. 8G, the voltage (reset signal SG3b) at the reset signal output terminal of the frame opening detection circuit 260 starts to drop (after about 4.4 seconds have elapsed from t3).

  When about 4.4 seconds elapse from t3, the conduction between the drain terminal D and the source terminal S of the FET 2 is cut off, so that a current is supplied to the power interruption signal output terminal of the open frame detection circuit 260. Not. Therefore, as shown in FIG. 8 (h), the voltage at the power interruption signal output terminal of the frame opening detection circuit 260 (power failure signal SG1b) becomes zero volts when about 4.4 seconds elapse from t3. Therefore, when about 4.4 seconds elapse after the front frame 14 is opened and the switch SW2 is turned on, the power failure signal SG1b output from the power interruption signal output terminal of the frame opening detection circuit 260 to the NMI terminal of the MPU 201 is Stopped.

  Next, when about 9.4 seconds have passed since t3 (after about 4.4 seconds have passed since t3, and about 5.0 seconds have passed), as shown in FIG. Drops to about 5.0 volts. Then, as shown in FIG. 8 (f), the voltage at the power output terminal of the open frame detection circuit 260 (the drive voltage Vb having a maximum value of about 5.0 volts) drops to about 4.3 volts (from t3). After about 9.4 seconds). Further, as shown in FIG. 8 (g), the voltage (reset signal SG3b) at the reset signal output terminal of the frame opening detection circuit 260 drops to about 4.3 volts, and thereafter, the reset IC 2 operates to zero volts. (After about 9.4 seconds from t3). Accordingly, when about 9.4 seconds have elapsed after the front frame 14 is opened and the switch SW2 is turned on, the reset signal SG3b output from the reset signal output terminal of the frame open detection circuit 260 to the reset terminal of the MPU 201 is converted into a power failure signal. Next to SG1b, it is stopped. As a result, the MPU 201 is set in a state where it cannot execute the arithmetic processing (after about 9.4 seconds have elapsed since t3).

  Further, when about 9.9 seconds elapse from t3 (after about 9.4 seconds elapse from t3, and further about 0.5 seconds elapse), as shown in FIG. Drop to about 4.7 volts. Then, as shown in FIG. 8 (f), the voltage of the power supply output terminal of the open frame detection circuit 260 (the drive voltage Vb having a maximum value of about 5.0 volts) drops to about 4.0 volts (from t3). After about 9.9 seconds). Here, as described above, the lower limit value of the operating voltage of the MPU 201 is about 4.0 volts. Therefore, when about 9.9 seconds have elapsed after the front frame 14 is opened and the switch SW2 is turned on, the drive voltage Vb output from the power supply output terminal of the frame open detection circuit 260 to the power supply terminal of the MPU 201 is finally It is stopped and the MPU 201 becomes inoperable. In other words, the MPU 201 is set in an inoperable state (after about 9.4 seconds from t3 time) after being set in a state in which execution of arithmetic processing is impossible (after about 9.4 seconds from t3 time). After). Therefore, even if the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off and the MPU 201 is temporarily activated by the frame opening detection circuit 260, the frame opening detection circuit 260 The launched MPU 201 can be normally terminated.

  When about 20 seconds elapse from t3, the voltage of the capacitor CD4 becomes zero volts as shown in FIG. 8 (e). Following this, the voltage of the power supply output terminal of the frame opening detection circuit 260 (and the drive voltage) also becomes zero volts (before about 20 seconds have elapsed since t3). Therefore, when about 20 seconds elapse from t3, the charge amount of the capacitor CD4 becomes zero.

  Finally, as shown in FIG. 8 (a), when the switch SW2 is cut off (the front frame 14 is closed) at t4, as shown in FIG. 8 (c), the TRG terminal voltage of the timer IC1 is reduced to about The 11.3 volts is switched to zero volts, and the OUT terminal voltage of the timer IC 1 is switched from zero volts to about 10.6 volts (at time t4). At t4, when the switch SW2 is cut off (the front frame 14 is closed), the terminal between the drain terminal D and the source terminal S of the FET 3 becomes conductive. As a result, the frame opening detection circuit 260 is set again to a state in which the inner frame 12 and the front frame 14 can be detected.

  As described above, when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off, the frame open detection circuit 260 resets after outputting the drive voltage Vb and the power failure signal SG1b. The signal SG3b is output. Therefore, when the MPU 201 is temporarily started up when the power of the pachinko machine 10 is turned off, the startup can be performed normally. The frame opening detection circuit 260 opens the inner frame 12 or the front frame 14 when the power of the pachinko machine 10 is turned off, and the switch SW1 or the switch SW2 is turned on. When seconds elapse, first, the power failure signal SG1b is stopped. Then, the frame open detection circuit 260 stops the reset signal SG3b when about 9.4 seconds elapse after the switch SW1 or the switch SW2 is turned on. Further, the frame open detection circuit 260 reduces the drive voltage Vb output to the power supply terminal of the MPU 201 to about 4.0 volts when about 9.9 seconds have elapsed after the switch SW1 or the switch SW2 is turned on. Therefore, even when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off and the MPU 201 is temporarily started by the frame open detection circuit 260, the MPU 201 that has been started up is normal. Can be terminated.

  As described above, the operation of the frame opening detection circuit 260 is the same when the inner frame 12 is opened and when the front frame 14 is opened. Therefore, the operation of the frame opening detection circuit 260 from time t5 to time t6, which will be described next, will be described only when the inner frame 12 is opened.

  As shown in FIG. 8A, when the switch SW1 becomes conductive at t5 (the inner frame 12 is open), the TRG terminal voltage of the timer IC1 is t5 at t5, as shown in FIG. Switch from zero volts to approximately 11.3 volts. At this time, as shown in FIG. 8D, the timer IC1 continues to output a voltage of about 10.6 volts from the OUT terminal. As a result, the terminals of the emitter terminal e and the collector terminal c of the transistor TR1 (see FIG. 7) become conductive, and charging of the capacitor CD4 (see FIG. 7) is started as shown in FIG. 8 (e) ( t5). When the charging of the capacitor CD4 is completed, as shown in FIG. 8E, the voltage of the capacitor CD4 becomes about 5.7 volts (after about 0.01 second from t5).

  Further, the voltage at the power supply output terminal of the frame opening detection circuit 260 (the output voltage to the input terminal I23 of the multiplexer MP3) starts to rise at t5 and is about 0 from t5 as shown in FIG. 8 (f). It will be about 5.0 volts after .01 seconds. As a result, the drive voltage Vb of about 5.0 volts is started to be output from the power output terminal of the frame opening detection circuit 260. Further, the voltage of the reset signal output terminal of the frame opening detection circuit 260 (the output voltage to the input terminal I22 of the multiplexer MP2 and the input / output port 205) is about 40 μs after t5 as shown in FIG. 8 (g). The rise starts (see A in FIG. 8 (f)), and reaches about 5.0 volts after about 0.01 seconds from t5. Thereby, the reset signal SG3b starts to be output from the reset signal output terminal of the frame opening detection circuit 260. Note that the voltage increase at the reset signal output terminal of the frame opening detection circuit 260 is about 40 μs after t5 due to the delay characteristics of the reset IC 2 (see FIG. 7) as described above. As shown in FIGS. 8F and 8G, the voltage increase at the power supply output terminal of the frame open detection circuit 260 is about 40 μs earlier than the voltage increase at the reset signal output terminal of the frame open detection circuit 260. After the drive voltage Vb of about 5 volts is supplied to the power terminal of the MPU 201, the reset signal SG3b is input to the reset signal output terminal of the MPU 201. Therefore, when the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily started when the power of the pachinko machine 10 is turned off, the startup can be performed normally.

  Further, as shown in FIG. 8E, when the voltage of the capacitor CD4 reaches about 5.7 volts, the voltage at the power interruption signal output terminal of the open frame detection circuit 260 (the output voltage to the input terminal I21 of the multiplexer MP1). As shown in FIG. 8 (h), it starts to rise at t5 and becomes about 5.0 volts about 0.01 seconds after t5. Here, since the switch SW1 is in a conductive state (the inner frame 12 is in an open state), the terminal between the drain terminal D and the source terminal S of the FET 3 is blocked. As a result, the power failure signal SG1b is started to be output from the power interruption signal output terminal of the frame opening detection circuit 260.

  When the inner frame 12 is closed before about 4.4 seconds have elapsed from t5 (when the inner frame 12 is closed at t6 after about 3.0 seconds from t5), FIG. As shown, the timer IC 1 continues to output a voltage of about 10.6 volts without switching the voltage at the OUT terminal to about 10.6 volts. At this time, the terminal between the drain terminal D and the source terminal S of the FET 1 remains conductive, but the switch SW1 is cut off as the inner frame 12 is closed, so that the emitter of the transistor TR1 (see FIG. 7). A voltage is no longer applied to the terminal e and the base terminal b, and conduction between the emitter terminal e and the collector terminal c of the transistor TR1 is interrupted. As a result, the charging of the capacitor CD4 ends (time t6). Then, since the discharge of the capacitor CD4 is started, as shown in FIG. 8D, the voltage of the capacitor CD4 starts to drop (at time t6). Following this, as shown in FIG. 8 (f), the voltage of the power supply output terminal of the open frame detection circuit 260 (the driving voltage Vb having a maximum value of about 5.0 volts) starts to drop (at time t6). . Further, as shown in FIG. 8G, the voltage (reset signal SG3b) at the reset signal output terminal of the frame opening detection circuit 260 starts to drop (at time t6).

  When the inner frame 12 is closed and the switch SW1 is cut off (at time t6), the capacitor CD4 starts to be discharged. Not supplied. As described above, since the switch SW1 is cut off when the inner frame 12 is closed, the terminal between the drain terminal D and the source terminal S of the FET 3 becomes conductive and is generated by the discharge of the capacitor CD4. This is because the current does not flow through the resistor R5 but flows into the drain terminal D of the FET 3. Therefore, as shown in FIG. 8 (h), the voltage at the power interruption signal output terminal of the frame opening detection circuit 260 (power failure signal SG1b) becomes zero volts at t6. Accordingly, if the inner frame 12 is closed and the switch SW1 is shut off before about 4.4 seconds elapses after the inner frame 12 is opened, the frame open detection circuit is turned off when the switch SW1 is turned off. The power failure signal SG1b output from the power interruption signal output terminal 260 to the NMI terminal of the MPU 201 is first stopped.

  Next, when about 5.0 seconds elapse from t6, the voltage of the capacitor CD4 drops to about 5.0 volts as shown in FIG. Then, as shown in FIG. 8 (f), the voltage at the power output terminal of the open frame detection circuit 260 (the drive voltage Vb having a maximum value of about 5.0 volts) drops to about 4.3 volts (from t6). After about 5.0 seconds). Further, as shown in FIG. 8 (g), the voltage (reset signal SG3b) at the reset signal output terminal of the frame opening detection circuit 260 drops to about 4.3 volts, and thereafter, the reset IC 2 operates to zero volts. (After about 5.0 seconds from t6). Therefore, when about 5.0 seconds elapse after the inner frame 12 is closed and the switch SW1 is cut off, the reset signal SG3b output from the reset signal output terminal of the frame opening detection circuit 260 to the reset terminal of the MPU 201 is a power failure signal. Next to SG1b, it is stopped. As a result, the MPU 201 is set in a state where it cannot execute the arithmetic processing (after about 5.0 seconds have elapsed since t6).

  Further, when about 5.5 seconds have passed from t6 (after about 5.0 seconds have passed since t6, and further about 0.5 seconds have passed), as shown in FIG. Drop to about 4.7 volts. Then, as shown in FIG. 8 (f), the voltage of the power supply output terminal of the open frame detection circuit 260 (the drive voltage Vb having a maximum value of about 5.0 volts) drops to about 4.0 volts (from t6). After about 5.5 seconds). Here, the minimum operating voltage of the MPU 201 is about 4.0 volts. Therefore, when about 5.5 seconds elapse after the inner frame 12 is closed and the switch SW1 is cut off, the drive voltage Vb output from the power supply output terminal of the frame open detection circuit 260 to the power supply terminal of the MPU 201 is finally stopped. As a result, the MPU 201 becomes inoperable. That is, the MPU 201 is set in an inoperable state (after about 5.0 seconds from t6) after being set in a state in which execution of arithmetic processing is not possible (after about t6 o'clock). After). Therefore, even if the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off and the MPU 201 is temporarily activated by the frame opening detection circuit 260, the frame opening detection circuit 260 The launched MPU 201 can be normally terminated.

  When about 20 seconds elapse from t5, the voltage of the capacitor CD4 becomes zero volts as shown in FIG. Following this, the voltage at the power supply output terminal of the frame opening detection circuit 260 (also the drive voltage Vb) becomes zero volts (before about 20 seconds have elapsed since t5). Therefore, when about 20 seconds elapse from t5, the charge amount of the capacitor CD4 becomes zero.

  Here, in the operation of the frame opening detection circuit 260 from t5 to t6, the capacitor CD4 is discharged even after the inner frame 12 is closed at t6. Even in this case, when the inner frame 12 is closed at t6 and the switch SW1 is cut off, the frame open detection circuit 260 conducts between the drain terminal D and the source terminal S of the FET 3, so that the capacitor The current generated by the discharge of CD4 is allowed to flow to the drain terminal D of the FET 3 without flowing to the resistor R5. Therefore, when the inner frame 12 is closed at t6, as shown in FIG. 8 (h), the voltage (power failure signal SG1b) of the power interruption signal output terminal of the frame opening detection circuit 260 can be zero volts.

  After the power failure signal SG1b output from the power failure signal output terminal of the frame open detection circuit 260 is stopped, the voltage accompanying the discharge of the capacitor CD4 decreases with time, and the reset is output from the reset signal output terminal. The signal SG3b is stopped, and finally the drive voltage Vb output from the power supply output terminal is stopped. Even if the inner frame 12 is closed before about 4.4 seconds have elapsed from the time t5 when the inner frame 12 is opened by this operation (the inner frame 12 is not removed at about t6 after about 3.0 seconds from the time t5). Even if it is closed, the power failure signal SG1b can be stopped first, then the reset signal SG3b can be stopped, and finally the drive voltage Vb can be stopped. Therefore, when the power of the pachinko machine 10 is turned off, the inner frame 12 is opened, and the opened inner frame is released within about 4.4 seconds until the voltage output from the OUT terminal of the timer IC 1 is switched. Even if the frame 12 is closed, the MPU 201 can be temporarily started up by the frame opening detection circuit 260, and the MPU 201 thus started up can be normally terminated.

  After the inner frame 12 is closed at t6, as shown in FIG. 8 (e), the voltage of the capacitor CD4 drops to about 4.7 volts, and as shown in FIG. When the drive voltage Vb output from the output terminal to the end is about 4.0 volts and the MPU 201 is normally terminated, the frame opening detection circuit 260 is set to a state in which the inner frame 12 or the front frame 14 can be detected again. Is done.

  Finally, a case will be described in which the switch SW2 is in a conductive state (the front frame 14 is in an open state) when the switch SW1 is in a conductive state (the inner frame 12 is in an open state). As shown in FIG. 8A, at time t7, the switch SW1 becomes conductive (inner frame 12 is open), and as shown in FIG. 8B, at time t8, switch SW2 becomes conductive (front surface). When the frame 14 is in an open state), as shown in FIG. 8C, the TRG terminal voltage of the timer IC 1 switches from zero volts to about 11.3 volts at t7. At this time, as shown in FIG. 8D, the timer IC1 continues to output a voltage of about 10.6 volts from the OUT terminal until about 4.4 seconds elapse from t7. As a result, the terminals of the emitter terminal e and the collector terminal c of the transistor TR1 (see FIG. 7) become conductive, and charging of the capacitor CD4 (see FIG. 7) is started as shown in FIG. 8 (e) ( t7). This charging is completed in about 0.01 seconds after the switch SW1 becomes conductive as shown in FIG. 8 (e). When the charging of the capacitor CD4 is completed, the voltage of the capacitor CD4 becomes about 5.7 volts as shown in FIG.

  Further, the voltage at the power supply output terminal of the frame opening detection circuit 260 (the output voltage to the input terminal I23 of the multiplexer MP3) starts to rise at t7 and is about 0 from t7 as shown in FIG. It will be about 5.0 volts after 0.01 second. As a result, the drive voltage Vb of about 5.0 volts is started to be output from the power output terminal of the frame opening detection circuit 260. Further, the voltage at the reset signal output terminal of the frame opening detection circuit 260 (the output voltage to the input terminal I22 of the multiplexer MP2 and the input / output port 205) is about 40 μsec after t7 as shown in FIG. 8 (g). Starting to rise, it becomes about 5.0 volts about 0.01 seconds after t7. Thereby, the reset signal SG3b starts to be output from the reset signal output terminal of the frame opening detection circuit 260. Note that the voltage increase at the reset signal output terminal of the frame opening detection circuit 260 is about 40 μsec after t7 due to the delay characteristic of the reset IC 2 (see FIG. 7) as described above. As shown in FIGS. 8F and 8G, the voltage increase at the power supply output terminal of the frame open detection circuit 260 is about 40 μs earlier than the voltage increase at the reset signal output terminal of the frame open detection circuit 260. After the drive voltage Vb of about 5 volts is supplied to the power terminal of the MPU 201, the reset signal SG3b is input to the reset signal output terminal of the MPU 201. Therefore, when the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily started when the power of the pachinko machine 10 is turned off, the startup can be performed normally.

  Further, as shown in FIG. 8 (e), when the voltage of the capacitor CD4 becomes about 5.7 volts, the voltage of the power interruption signal output terminal of the open frame detection circuit 260 (the output voltage to the input terminal I21 of the multiplexer MP1). As shown in FIG. 8 (h), it starts to rise at t7 and becomes about 5.0 volts after about 0.01 seconds from t7. Here, since the switch SW1 is in a conductive state (the inner frame 12 is in an open state), the terminal between the drain terminal D and the source terminal S of the FET 3 is blocked. As a result, the power failure signal SG1b is started to be output from the power interruption signal output terminal of the frame opening detection circuit 260.

  When about 4.4 seconds elapse from t7, as shown in FIG. 8D, the timer IC1 switches the voltage at the OUT terminal from about 10.6 volts to zero volts. Then, the conduction between the drain terminal D and the source terminal S of the FET 1 is cut off, and the conduction between the emitter terminal e and the collector terminal c of the transistor TR1 (see FIG. 7) is cut off. Charging to CD4 ends. Then, since the discharge of the capacitor CD4 is started, as shown in FIG. 8E, the voltage of the capacitor CD4 starts to drop (after about 4.4 seconds have elapsed from t7). Following this, as shown in FIG. 8 (f), the voltage at the power supply output terminal of the open frame detection circuit 260 (the driving voltage Vb having a maximum value of about 5.0 volts) starts to drop (from t7). After about 4.4 seconds). Further, as shown in FIG. 8G, the voltage (reset signal SG3b) at the reset signal output terminal of the frame opening detection circuit 260 starts to drop (after about 4.4 seconds have elapsed from t7).

  When about 4.4 seconds elapse from t7, the conduction between the drain terminal D and the source terminal S of the FET 2 is cut off, so that a current is supplied to the power interruption signal output terminal of the open frame detection circuit 260. Not. Therefore, as shown in FIG. 8 (h), the voltage at the power interruption signal output terminal of the frame opening detection circuit 260 (power failure signal SG1b) becomes zero volts when about 4.4 seconds elapse from t7. Therefore, when about 4.4 seconds elapse after the inner frame 12 is opened and the switch SW1 is turned on, the power failure signal SG1b output from the power interruption signal output terminal of the frame opening detection circuit 260 to the NMI terminal of the MPU 201 is Stopped.

  Next, when about 9.4 seconds have passed since t7 (after about 4.4 seconds have passed since t7, and about 5.0 seconds have passed), as shown in FIG. Drops to about 5.0 volts. Then, as shown in FIG. 8 (f), the voltage at the power output terminal of the open frame detection circuit 260 (the drive voltage Vb having a maximum value of about 5.0 volts) drops to about 4.3 volts (from t7). After about 9.4 seconds). Further, as shown in FIG. 8 (g), the voltage (reset signal SG3b) at the reset signal output terminal of the frame opening detection circuit 260 drops to about 4.3 volts, and thereafter, the reset IC 2 operates to zero volts. (After about 9.4 seconds from t7). Therefore, when about 9.4 seconds have elapsed after the inner frame 12 is opened and the switch SW1 is turned on, the reset signal SG3b output from the reset signal output terminal of the frame open detection circuit 260 to the reset terminal of the MPU 201 is the power failure signal. Next to SG1b, it is stopped. As a result, the MPU 201 is set in a state where it cannot execute the arithmetic processing (after about 9.4 seconds have elapsed since t7).

  Further, when about 9.9 seconds elapse from t7 (after about 9.4 seconds elapse from t7, and further about 0.5 seconds elapse), as shown in FIG. Drop to about 4.7 volts. Then, as shown in FIG. 8 (f), the voltage at the power supply output terminal of the open frame detection circuit 260 (the drive voltage Vb having a maximum value of about 5.0 volts) drops to about 4.0 volts (from time t7). After about 9.9 seconds). Here, as described above, the lower limit value of the operating voltage of the MPU 201 is about 4.0 volts. Accordingly, when about 9.9 seconds have elapsed after the inner frame 12 is opened and the switch SW1 is turned on, the drive voltage Vb output from the power supply output terminal of the frame open detection circuit 260 to the power supply terminal of the MPU 201 is finally stopped. As a result, the MPU 201 becomes inoperable. In other words, the MPU 201 is set in an inoperable state (after about 9.4 seconds have elapsed from t7) after being set in a state in which execution of arithmetic processing is impossible (after about 9.9 seconds from t7). After). Therefore, even if the MPU 201 is temporarily activated by the frame opening detection circuit 260 when the power of the pachinko machine 10 is turned off, the frame opening detection circuit 260 may normally terminate the MPU 201 that has been started up. it can.

  When about 20 seconds elapse from t7, the voltage of the capacitor CD4 becomes zero volts as shown in FIG. 8 (e). Following this, the voltage at the power supply output terminal of the frame opening detection circuit 260 (also the drive voltage Vb) becomes zero volts (before about 20 seconds have elapsed since t7). Therefore, when about 20 seconds elapse from t7, the charge amount of the capacitor CD4 becomes zero.

  Finally, as shown in FIG. 8 (a), at time t9, the switch SW1 is turned off (the inner frame 12 is closed), and as shown in FIG. 8 (b), at time t10, the switch SW2 is turned off. When the state (the front frame 14 is closed), as shown in FIG. 8C, at time t10, the TRG terminal voltage of the timer IC 1 is switched from about 11.3 volts to zero volts, and the OUT terminal voltage of the timer IC 1 Switches from zero volts to about 10.6 volts. In addition, at time t10, when the switch SW2 is in a cut-off state (the front frame 14 is closed), the terminal between the drain terminal D and the source terminal S of the FET 3 becomes conductive. As a result, the frame opening detection circuit 260 is set again to a state in which the inner frame 12 and the front frame 14 can be detected.

  As described above, even when the switch SW1 is in the conductive state (the inner frame 12 is in the open state) and the switch SW2 is in the conductive state (the front frame 14 is in the open state), the timer IC1 is in the conductive period of the switch SW1. Regardless of the length of the inner frame 12 (the length of the opening period of the inner frame 12) and the length of the conduction period of the switch SW2 (the length of the opening period of the front frame 14), either the switch SW1 or the switch SW2 is in the conductive state. When about 4.4 seconds have elapsed from when the inner frame 12 or the front frame 14 is open, the voltage at the OUT terminal is switched from about 10.6 volts to zero volts. As a result, the frame opening detection circuit 260 stops the power failure signal SG1b and starts discharging the capacitor CD4 after about 4.4 seconds from when either the switch SW1 or the switch SW2 becomes conductive. . After that, the frame open detection circuit 260 stops the reset signal SG3b after about 9.4 seconds from when either the switch SW1 or the switch SW2 becomes conductive, and either the switch SW1 or the switch SW2 The drive voltage Vb is stopped after about 9.9 seconds from the time when one of them becomes conductive. Therefore, when the power of the pachinko machine 10 is turned off, the switch SW1 is in a conductive state (the inner frame 12 is in an open state), and then the switch SW2 is in a conductive state (the front frame 14 is in an open state) Even if the MPU 201 is temporarily activated by the frame opening detection circuit 260, the frame opening detection circuit 260 can normally terminate the started MPU 201.

  As described above, when the pachinko machine 10 is powered off, the frame opening detection circuit 260 is activated when one of the inner frame 12 or the front frame 14 and both the inner frame 12 and the front frame 14 are opened. After outputting the voltage Vb and the power failure signal SG1b, the reset signal SG3b is outputted. Therefore, even when the power of the pachinko machine 10 is turned off, the MPU 201 can be temporarily started up normally. Although details will be described later, when the MPU 201 is temporarily activated by the frame release detection circuit 260 when the power of the pachinko machine 10 is off, the pachinko machine 10 turns on the off-in-frame release flag 203a. To do. When the off-in-frame release flag 203a is turned on, the pachinko machine 10 uses the audio output device 226 and the lamp display device 227 when the power to the pachinko machine 10 is turned on next time, and the inner frame 12 or the front frame. Informs that 14 is opened. Therefore, the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off can be specified.

  As will be described in detail later, when the MPU 201 is temporarily activated by the frame release detection circuit 260 when the power of the pachinko machine 10 is off, the pachinko machine 10 turns on the off-in-frame release flag 203a. In addition, a pulse signal having a pulse width of 1 msec is output to the hall computer 262. The output pulse signal is stored in the hall computer 262 that continues to operate for 24 hours. Therefore, by analyzing the pulse signal stored in the hall computer 262, the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off is specified. Can do.

  Further, the frame open detection circuit 260 first stops the power failure signal SG1b when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on and about 4.4 seconds have elapsed after the turn-on. If the opened inner frame 12 or the opened front frame 14 is closed before the switch SW1 or the switch SW2 is turned on and about 4.4 seconds have passed since the turn-on, the stop signal is displayed at the time of closing. SG1b is stopped). Next, the frame open detection circuit 260 stops the reset signal SG3b when about 9.4 seconds have elapsed after the switch SW1 or SW2 is turned on (about 4.4 seconds have passed after the switch SW1 or switch SW2 is turned on). If the opened inner frame 12 or the opened front frame 14 is closed before, the reset signal SG3b is stopped after about 5.0 seconds from the closing). The frame opening detection circuit 260 reduces the drive voltage Vb output to the power supply terminal of the MPU 201 to about 4.0 volts when about 9.9 seconds have elapsed after the switch SW1 or SW2 is turned on (switch SW1 or SW2). If the opened inner frame 12 or the opened front frame 14 is closed before about 4.4 seconds have elapsed after the switch SW2 is turned on, the drive is performed after about 5.5 seconds have elapsed since the closing. Voltage Vb is reduced to about 4.0 volts). Therefore, even if the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off and the MPU 201 is temporarily activated by the frame opening detection circuit 260, the frame opening detection circuit 260 The launched MPU 201 can be normally terminated.

  Further, the frame opening detection circuit 260 opens the inner frame 12 or the front frame when approximately 4.4 seconds elapses after the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on. The transistor TR1 stops the output of the drive voltage Vb, the output of the reset signal SG3b, the output of the power failure signal SG1b, and the charging of the capacitor CD4 performed by the electric power supplied from the capacitor CD1, regardless of the open period 14. After the stop by the transistor TR1, the frame opening detection circuit 260 outputs the drive voltage Vb and the reset signal SG3b by discharging the capacitor CD4. Therefore, the frame opening detection circuit 260 is, for example, when the game hall is closed and the power supply to the pachinko machine 10 is cut off, and the DC power supply DC1 of 12 volts is not supplied to the frame opening detection circuit 260. That is, when a DC voltage of about 11.3 volts is supplied from the capacitor CD1 to the frame open detection circuit 260, the period during which power is supplied from the capacitor CD1 is the open period of the inner frame 12 or the front frame 14. Regardless, it can remain in about 4.4 seconds. Therefore, the frame opening detection circuit 260 can detect the opening of the inner frame 12 or the front frame 14 a plurality of times while suppressing the consumption of the electric power charged in the capacitor CD1.

  Further, the frame open detection circuit 260 is configured so that even if the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on, the inner frame 12 or the front frame 14 is opened before approximately 4.4 seconds elapses. When the frame 12 or the opened front frame 14 is closed, the switch SW1 or the switch SW2 is cut off, the output of the drive voltage Vb performed by the power supplied from the capacitor CD1, the output of the reset signal SG3b, the power failure signal SG1b And the charging of the capacitor CD4 are stopped. After the inner frame 12 and the front frame 14 are closed, the drive voltage Vb and the reset signal SG3 are output by discharging the capacitor CD4.

  As described above, when the charging of the capacitor CD4 is completed, the driving voltage Vb and the reset signal SG3b can be output by discharging the capacitor CD4. Therefore, the open period of the inner frame 12 or the front frame 14 is approximately If the time is within 4.4 seconds, the output voltage Vb, the reset signal SG3b, the power failure signal SG1b, and the capacitor CD4 charged by the power supply from the capacitor CD1 are further shortened. Can be stopped. Therefore, the power consumption of the capacitor CD1 due to the opening of the inner frame 12 or the front frame 14 can be further suppressed.

  Here, since the capacitor CD1 has a capacitance of 1F and the voltage applied to the capacitor CD1 is approximately 11.3 volts, the charge stored in the capacitor CD1 is the product of the capacitance of the capacitor CD1 and the applied voltage of the capacitor CD1. To about 11.3 C (coulomb). The charge of about 11.3 C stored in the capacitor CD1 is approximately during the periods of the output of the drive voltage Vb, the output of the reset signal SG3b, the output of the power failure signal SG1b, and the charge of the capacitor CD4 performed by the power supply from the capacitor CD1. In the case of 4.4 seconds, this corresponds to about 11 times of power supply. Therefore, for example, when the business hours of the amusement hall are over and the power supply to the pachinko machine 10 is shut off and a DC voltage of 12 volts is not supplied from the DC power supply DC1, the inner frame 12 is opened (the switch SW1 Continuity) or the opening of the front frame 14 (conduction of the switch SW2) is performed a plurality of times, the frame opening detection circuit 260 opens the inner frame 12 or the front frame 14 (conduction or conduction of the switch SW1). The conduction of the switch SW2) is reliably detected every time up to about 11 times, and the MPU 201 can be normally raised normally to turn on the off-in-frame release flag 203a. At this time, when the opening of the inner frame 12 or the opening of the front frame 14 is about 11 times, the power stored in the capacitor CD1 decreases, the drive voltage Vb decreases, the reset signal SG3b decreases, and the power failure signal SG1b decreases. A decrease and a decrease in the charge amount of the capacitor CD4 occur. However, when the inner frame 12 or the front frame 14 is opened, the voltage of the reset signal SG3b output from the reset signal output terminal of the frame open detection circuit 260 exceeds about 4.3 volts, and the frame open detection circuit 260 If the voltage of the drive voltage Vb output from the power supply output terminal and the voltage of the power failure signal SG1b output from the power interruption signal output terminal of the frame opening detection circuit 260 exceed about 4.0 volts, the power of the pachinko machine 10 is Even if it is off, the MPU 201 can be temporarily started up normally and the off-in-frame release flag 203a can be turned on. Furthermore, a pulse signal having a pulse width of 1 msec can be output to the hall computer 262.

  In the frame opening detection circuit 260, the capacitances of the capacitors CD1 and CD4 are each 1F. However, the capacitor CD1 has a frame when the power of the pachinko machine 10 is turned off and the inner frame 12 or the front frame 14 is opened. Since the capacitor serves as a power source for operating the open detection circuit 260, the capacitance value may be larger than the capacitance value of the capacitor CD4. By making the capacitance value of the capacitor CD1 larger than 1F, the opening of the inner frame 12 or the front frame 14 while the power of the pachinko machine 10 is turned off can be detected more than 11 times.

  In frame open detection circuit 260, when inner frame 12 and front frame 14 are closed (when switches SW1 and SW2 are shut off), the OUT terminal voltage of timer IC1 is about 10.6 volts. Therefore, the terminal between the drain terminal D and the source terminal S of the FET 1 of the frame opening detection circuit 260 and the terminal between the drain terminal D and the source terminal S of the FET 2 are brought into conduction. Further, since the inner frame 12 and the front frame 14 are closed, the terminal between the drain terminal D and the source terminal S of the FET 3 is in a conductive state. However, at this time, the conduction between the terminals of the emitter terminal e and the collector terminal c of the transistor TR1 is cut off, so that the terminal between the drain terminal D and the source terminal S of the FET1 and the drain terminal D and the source terminal of the FET2 are separated. The current from the capacitor CD1 does not flow between the terminals with S and between the drain terminal D and the source terminal S of the FET 3. Therefore, when the inner frame 12 and the front frame 14 are closed, the power charged in the capacitor CD1 is between the drain terminal D and the source terminal S of the FET1, and between the drain terminal D and the source terminal S of the FET2. It does not flow between terminals and between the drain terminal D and the source terminal S of the FET 3 and is not consumed.

  Further, the amount of power that the frame open detection circuit 260 consumes the power of the capacitor CD1 in a state where the power of the pachinko machine 10 is turned off and the inner frame 12 and the front frame 14 are closed is the standby power of the timer IC1 and the power consumption of the NOTIC3. Degree. Moreover, since only a voltage is applied to each gate terminal G in FET1 to FET3, the power consumed in FET1 to FET3 is very small. Therefore, the consumption of these powers does not cause a significant decrease in the charge amount of the capacitor CD1.

  Next, the display content of the third symbol display device 81 will be described with reference to FIG. FIG. 9 is a diagram for explaining the display screen of the third symbol display device 81, and FIG. 9A is a diagram schematically showing the area division setting and the effective line setting of the display screen, FIG. 9B is a diagram illustrating an actual display screen.

  The third symbol is composed of ten types of main symbols with numbers from “0” to “9” and one type of sub-shaped petal shape formed smaller than this main symbol. Each main symbol is composed of numbers from “0” to “9” on the rear symbol consisting of a wooden box, of which the main symbols with odd numbers (1, 3, 5, 7, 9) are A large number is added to almost the front of the wooden box. On the other hand, the main symbols with even numbers (0, 2, 4, 6, 8) are attached to the front of the wooden box almost to the full, and attached symbols imitating characters such as furoshiki and helmets, An even number is small in green on the lower right side of the attached symbol and is added so as to be displayed on the front side of the attached symbol.

  Further, in the pachinko machine 10 according to the present embodiment, when the lottery result by the main controller 110 is a big win, a variable display with the same main symbols is performed, and a big hit occurs after the variable display is finished. It is configured to When shifting to the high probability state (probability variation state) after the big hit, the variable display in which the main symbols (corresponding to “high probability symbols”) to which odd numbers are added is arranged. On the other hand, when shifting to the low probability state after the big hit, the variable display is performed in which the main symbols to which the even numbers are added (corresponding to “low probability symbols”) are arranged. Here, the high probability state refers to a state in which the subsequent jackpot probability is increased as an added value after the jackpot ends, that is, a so-called probability fluctuation (probability change). Further, the normal state (low probability state) refers to a time when the probability of hitting is not probable, and refers to a state where the probability of jackpot is normal, that is, a state where the probability of jackpot is lower than that during probability change.

  As shown in FIG. 9 (a), the display screen of the third symbol display device 81 is roughly divided into two vertically, and the lower 2/3 is the main display area Dm in which the third symbol is variably displayed, and the others. The upper third is a sub display area Ds for displaying a notice effect and a character.

  In the main display area Dm, three symbol rows Z1, Z2, and Z3 of left, middle, and right are displayed. In each symbol row Z1 to Z3, the above-described third symbols are displayed in a prescribed order. That is, in each symbol row Z1 to Z3, main symbols are arranged in ascending or descending numerical order, and one sub symbol is arranged between each main symbol. For this reason, a total of 20 third symbols of 10 main symbols and 10 sub-designs are set in each symbol row, and each symbol row Z1 to Z3 scrolls from top to bottom with periodicity. The display is changed. In particular, the left symbol row Z1 is arranged so that the numbers of the main symbols appear in descending order, and the middle symbol row Z2 and the right symbol row Z3 are arranged so that the numbers of the main symbols appear in ascending order.

  In the main display area Dm, the third symbols are displayed in the upper, middle, and lower three rows for each symbol row Z1 to Z3. Accordingly, the third symbol display device 81 displays a total of nine third symbols of 3 rows × 3 columns. In the main display area Dm, five effective lines, that is, an upper line L1, a middle line L2, a lower line L3, a right rising line L4, and a left rising line L5 are set. In each game, the variable display stops in the order of the left symbol row Z1 → the right symbol row Z3 → the middle symbol row Z2, and the combination of jackpot symbols on any active line at the time of the stop (in this embodiment, A jackpot moving image is displayed as a jackpot if the same combination of main symbols is arranged.

  The sub display area Ds is horizontally long above the main display area Dm, and is further equally divided into three notice areas Ds1 to Ds3 in the left-right direction. Here, the left and right notice areas Ds1, Ds3 are usually covered with double-open opaque doors that are electrically opened and closed by solenoids (not shown), and sometimes the solenoids are excited and the doors are on the front side. It is a display area that is visible to the player when it is opened. The center notice area Ds2 is a display area that is always visible without being covered by the door.

  As shown in FIG. 9B, on the actual display screen, a total of nine main symbols and sub-designs of the third symbol are displayed in the main display area Dm. In the sub display area Ds, the left and right doors are closed, and the left and right notice areas Ds1, Ds3 are covered and the display screen cannot be visually recognized. If either one of the left and right doors or both doors are opened during the variable display, a video is displayed in the left and right notice areas Ds1 and Ds3, and it is easy for the player to change to a big hit than usual. It is suggested. In the notice area Ds2 in the center, a predetermined character (a boy with a bee in this embodiment) usually performs a predetermined action, sometimes performs a special action different from the predetermined action, or another character A notice effect is performed by appearing. The display screen of the third symbol display device 81 is divided into upper and lower display areas Dm and Ds in principle, but the third symbol and characters are displayed larger across the display areas Dm and Ds. A display effect can be performed.

  Next, a counter and the like provided in the RAM 203 of the main controller 110 will be described with reference to FIG. These counters and the like are used by the MPU 201 of the main control device 110 to perform jackpot lottery, display setting of the first symbol display device 37, lottery of display results of the second symbol display device 82, and the like.

  For the jackpot lottery or display setting of the first symbol display device 37, the first hit random number counter C1 used for the jackpot lottery, the first hit type symbol counter C2 used for the jackpot symbol selection, and the stop pattern selection counter C3, a first initial value random number counter CINI1 used for setting the initial value of the first random number counter C1, and variation type counters CS1, CS2, and CS3 used for variation pattern selection are used. The second symbol random number counter C4 is used for the lottery of the second symbol display device 82, and the second initial random number counter CINI2 is used for setting the initial value of the second random number counter C4. Each of these counters is a loop counter that adds 1 to the previous value every time it is updated and returns to 0 after reaching the maximum value.

  Each counter is updated at an interval of 4 milliseconds, which is the execution interval of the main process (see FIG. 12), or at an interval of 2 milliseconds, which is the execution interval of the timer interrupt process (see FIG. 15). Are stored in the counter buffer set as follows. The RAM 203 is provided with a holding ball storage area composed of one execution area and four holding areas (holding first to fourth areas). The values of the first per-random number counter C1, the first per-type counter C2, and the stop pattern selection counter C3 are stored in accordance with the ball winning timing.

  Each counter will be described in detail. The first random number counter C1 is configured so that, for example, 1 is added in order within a range of 0 to 738, and after reaching the maximum value (that is, 738), it returns to 0. In particular, when the first random number counter C1 makes one round, the value of the first initial value random number counter CINI1 at that time is read as the initial value of the first random number counter C1. The first initial value random number counter CINI1 is configured as a loop counter that is updated in the same range as the first per-random number counter C1 (value = 0 to 738), and each time the timer interrupt process (see FIG. 15) is executed It is updated once and updated repeatedly within the remaining time of the main process (see FIG. 12). The value of the first per-random number counter C1 is updated, for example, periodically (in this embodiment, once for each timer interrupt process), and the stored ball is stored in the RAM 203 at the timing when the ball wins the first entrance 64. Stored in the area. The number of random number values that are jackpots is set at low probability and high probability, and the number of random numbers that are jackpots at low probability is 2, and the value is “373, 727” There are 14 random numbers that are big hits at high probability, and the values are "59, 109, 163, 211, 263, 317, 367, 421, 479, 523, 631, 683, 733".

  The first hit type counter C2 determines the display mode of the first symbol display device 37 at the time of the big hit. In the present embodiment, the first hit type counter C2 is incremented one by one within the range of 0 to 4, and the maximum value ( That is, it is configured to return to 0 after reaching 4). The value of the first hit type counter C2 is updated, for example, periodically (in this embodiment, once for each timer interrupt process), and the stored ball is stored in the RAM 203 at the timing when the ball wins the first entrance 64. Stored in the area. In addition, the value of the random number that becomes the high probability state after the big hit is “1, 2, 3”, the value of the random number that becomes the low probability state after the big hit is “0, 4”, and two types of hit types are determined. The Therefore, the display mode corresponding to the stop symbol displayed on the first symbol display device 37 is a display mode corresponding to two types of jackpots of a high probability state and a low probability state, and one type of display mode corresponding to a deviation. Any one of the three display modes is selected.

  The stop pattern selection counter C3 is, for example, incremented by 1 in the range of 0 to 238, and returns to 0 after reaching the maximum value (that is, 238). In the present embodiment, the stop pattern selection counter C3 selects the effect pattern displayed on the third symbol display device 81, and after reaching, the final stop symbol is shifted by one before and after the reach symbol. “Stop before and after detachment reach” (for example, a range of 0 to 8), and “Leach other than detachment before and after detachment” (for example, a range of 9 to 38) after the reach has occurred and the final stop symbol stops other than before and after the reach design. The three stop (effect) patterns are selected as “completely out” (for example, a range of 39 to 238) that does not cause reach. The value of the stop pattern selection counter C3 is updated, for example, periodically (once every timer interrupt process in this embodiment), and the reserved ball storage area of the RAM 203 at the timing when the ball wins the first entrance 64. Stored in

  Further, the stop pattern selection counter C3 is provided with a plurality of tables having different ranges of random number values from which the stop pattern is selected. This depends on whether the current state of the pachinko machine 10 is a high probability state or a low probability state, in which area of the reserved ball storage area each random number value is stored (ie, the number of reserved balls), etc. This is to change the stop pattern selection ratio.

  For example, in a high probability state, a table with a wide random value range of 10 to 238 corresponding to the stop pattern of “completely out” is selected so that a jackpot is likely to occur and a reach effect is not selected more than necessary. It becomes easy to select “completely off”. In this table, “front / rear out of reach” is narrowed to 0-5, and “reach other than front / rear out of reach” is also narrowed to 6-9, making it difficult to select “rear out of front / rear out of reach” or “reach out of front / rear out of reach”. Further, if each random number value is not stored in the holding ball storage area in a low probability state, a disturbance corresponding to the stop pattern of “completely off” in order to secure the time for the ball to enter the first entrance 64. A table with a narrow numerical value range of 51 to 238 is selected, and “completely out” is difficult to select. In this table, the range of random numbers corresponding to the stop pattern of “reach other than front / rear deviation” is as wide as 9 to 50, and “reach other than front / rear deviation” is easily selected. Therefore, in the low probability state, the ball entry time to the first entrance 64 can be secured, and therefore, the variable display by the third symbol display device 81 is easily performed continuously.

  Of the two variation type counters CS1 and CS2, one variation type counter CS1 is incremented one by one within a range of 0 to 198, for example, and reaches a maximum value (that is, 198) and then returns to 0. The other variation type counter CS2 is, for example, incremented by 1 within a range of 0 to 240, for example, and reaches the maximum value (that is, 240) and then returns to 0. In the following description, CS1 is also referred to as “first variation type counter”, and CS2 is also referred to as “second variation type counter”.

  Rough display modes such as so-called normal reach, super reach, and premium reach are determined by the first variation type counter CS1. Specifically, the display mode is determined by determining the variation time of the symbol variation. Further, the second variation type counter CS2 determines a variation time (in other words, the number of variation symbols) until the final stop symbol (in this embodiment, the middle symbol) stops after the reach occurs. Based on the variation time determined by the variation type counters CS1 and CS2, the display control device 114 determines the reach type of the third symbol displayed on the third display device 81 and the detailed symbol variation mode. Therefore, a variety of variation patterns can be easily realized by combining these variation type counters CS1 and CS2. It is also possible to determine the symbol variation mode only by the first variation type counter CS1, or to determine the symbol variation mode similarly by combining the first variation type counter CS1 and the stop symbol. The values of the variation type counters CS1 and CS2 are updated once every time a main process (see FIG. 12) described later is executed once, and are repeatedly updated within the remaining time in the main process.

  For example, the value of the variation type counter CS3 is sequentially incremented by 1 within a range of 0 to 162, and returns to 0 after reaching the maximum value (that is, 162). In the following description, CS3 is also referred to as a “third variation type counter”. The 3rd symbol display device 81 of this Embodiment performs the decorative production according to the display mode of the 1st symbol display device 37, and can slide the symbol which is changing in addition to the variation of a symbol. A notice effect such as passing a notice character for notifying the occurrence of the reach effect is performed. The effect pattern of the notice effect is selected by the variation type counter CS3. Specifically, the time required for the notice effect is added to the variable time, or on the contrary, the variable time is subtracted to shorten the variable display time, or an effect pattern that does not add or subtract the variable time is selected. . As with the stop pattern selection counter C3, the variation type counter CS3 is provided with a plurality of tables with different ranges of random values from which the production pattern is selected, and whether the current state of the pachinko machine 10 is in a high probability state. Depending on the low probability state or in which area of the reserved ball storage area each random value is stored, the selection ratio of each effect pattern is different.

  As described above, the variation time of the symbol variation is determined by the variation type counters CS1 and CS2, and the time to be added to or subtracted from the variation time is determined by the variation type counter CS3. Therefore, the final fluctuation time until the final stop symbol stops is determined by the fluctuation type counters CS1, CS2, CS3.

  The second random number counter C4 is configured as a loop counter that is incremented one by one within a range of 0 to 250, for example, and returns to 0 after reaching the maximum value (that is, 250). In this embodiment, the value of the second random number counter C4 is updated periodically, for example, every timer interrupt process, and the ball has passed through the second entrance (through gate) 67 on either the left or right side. Obtained when detected. The number of random number values to be won is 149, and the range is “5 to 153”. The second initial value random number counter CINI2 is configured as a loop counter that is updated in the same range as the second per-random number counter C4 (value = 0 to 250), and is once per timer interrupt process (see FIG. 15). In addition to being updated, it is repeatedly updated within the remaining time of the main process (see FIG. 12).

  Next, each control process executed by the MPU 201 in the main controller 110 will be described with reference to the flowcharts of FIGS. 11 to 17. The MPU 201 is roughly divided into a startup process that is started when the power is turned on, a main process that is executed after the startup process, and a startup process periodically (in this embodiment, at a cycle of 2 milliseconds). There are a timer interrupt process and an NMI interrupt process activated by the input of the power failure signal SG1 to the NMI terminal. For convenience of explanation, the timer interrupt process and the NMI interrupt process are described first, and then the startup process And the main process will be described.

  FIG. 15 is a flowchart showing the timer interrupt process. The timer interrupt process is executed by the MPU 201 of the main control device 110, for example, every 2 milliseconds. In the timer interrupt process, first, a process for reading various winning switches is executed (S501). That is, the state of various switches connected to the main controller 110 is read, and the state of the switch is determined and the detection information (winning detection information) is stored.

  Next, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are updated (S502). Specifically, the first initial value random number counter CINI1 is incremented by 1 and cleared to 0 when the counter value reaches the maximum value (738 in the present embodiment). Then, the updated value of the first initial value random number counter CINI 1 is stored in the corresponding buffer area of the RAM 203. Similarly, 1 is added to the second initial value random number counter CINI2, and when the counter value reaches the maximum value (250 in the present embodiment), it is cleared to 0, and the second initial value random number counter CINI2 is updated. The value is stored in the corresponding buffer area of the RAM 203.

  Further, the first per-random number counter C1, the first per-type counter C2, the stop pattern selection counter C3, and the second per-random number counter C4 are updated (S503). Specifically, 1 is added to each of the first per-random number counter C1, the first per-type counter C2, the stop pattern selection counter C3, and the second per-random number counter C4, and these counter values are the maximum values (this embodiment) Then, when they reach 738, 4, 238, 250), they are cleared to 0. Then, the updated values of the counters C1 to C4 are stored in the corresponding buffer area of the RAM 203.

  Thereafter, a start winning process (see FIG. 16) associated with winning in the first entrance 64 is executed (S504), a firing control process is executed (S505), and the timer interrupt process is terminated. Note that the launch control process detects that the player is touching the operation handle 51 with the touch sensor 51a and turns on the ball launch on the condition that the stop switch 51b for stopping the launch is not operated. This is a process for determining / off. The main controller 110 instructs the launch controller 112 to launch a sphere when the launch of the sphere is on.

  Here, the start winning process executed in the process of S504 will be described with reference to the flowchart of FIG. FIG. 16 is a flowchart showing the start winning process (S504) executed in the timer interrupt process (see FIG. 15).

  When this start winning process is executed, first, it is determined whether or not the ball has won a first winning opening 64 (start winning) (S601). If it is determined that the ball has won the first entrance 64 (S601: Yes), whether or not the number N of operation-reserved balls of the first symbol display device 37 is less than the upper limit (4 in the present embodiment). Is determined (S602). If there is a winning at the first entrance 64 and the number of operation-reserved balls N <4 (S602: Yes), the number N of operation-reserved balls is incremented by 1 (S603), and further updated in step S503. The values of the first per-random number counter C1, the first per-type counter C2, and the stop pattern selection counter C3 are stored in the first area among the free reserved areas in the reserved ball storage area of the RAM 203 (S604). On the other hand, if there is no winning at the first entrance 64 (S601: No), or even if there is a winning at the first entrance 64, if the number N of operational reserves is not N <4 (S602: No). , S603 and S604 are skipped, the start winning process is terminated, and the process returns to the timer interrupt process.

  FIG. 17 is a flowchart showing NMI interrupt processing. In the NMI interrupt process, the power of the pachinko machine 10 is turned on, and the power of the pachinko machine 10 is shut off due to the occurrence of a power failure while the power is on. In addition to the case where SG1a falls from 5 volts to zero volts, the power of the pachinko machine 10 is turned off. While the power is turned off, the inner frame 12 or the front frame 14 is opened, and the frame open detection circuit 260 This is a process executed by the MPU 201 of the main controller 110 when the MPU 201 is started up and the power failure signal SG1b output from the frame opening detection circuit 260 falls from 5 volts to zero volts. When the MPU 201 detects the falling edge of the power failure signal SG1a or the falling edge of the power failure signal SG1b, the MPU 201 interrupts the control being executed and starts the NMI interrupt process. Is stored in the RAM 203 (S701), and the NMI interrupt processing is terminated.

  The above NMI interrupt process is executed in the same manner by the payout and launch control device 111 when the power of the pachinko machine 10 is turned on, and the occurrence information of the power interruption is stored in the RAM 213 by the NMI interrupt process. The That is, when the power of the pachinko machine 10 is cut off due to the occurrence of a power failure or the like when the power of the pachinko machine 10 is turned on, the power failure signal SG1a (falling) is sent from the power failure monitoring circuit 252 in the payout and emission control device 111. Is output to the NMI terminal of the MPU 211, and the MPU 211 interrupts the control being executed and starts the NMI interrupt process.

  Next, referring to FIG. 11, a startup process when the main controller 110 is powered on will be described. FIG. 11 is a flowchart showing start-up processing executed by the MPU 201 in the main controller 110. This start-up process is started by a reset at power-on, and when the pachinko machine 10 is powered off, the inner frame 12 or the front frame 14 is opened and the frame open detection circuit 260 The drive voltage Vb and the reset signal SG3b are output, and the MPU 201 is activated by the drive voltage Vb. Thereafter, the MPU 201 is activated by the reset signal SG3b. In the start-up process, first, an initial setting process associated with power-on is executed (S101). Specifically, a predetermined value set in advance in the stack pointer is set, and the sub-side control devices (peripheral control devices such as the audio lamp control device 113 and the payout control device 111) become operable. In order to wait, a wait process (1 second in this embodiment) is executed. Next, access to the RAM 203 is permitted (S103). Due to this wait processing, the main control device 110 shifts to the main processing after the payout control device 111, the sound lamp control device 113, and the display control device 114 shift to the main processing. Therefore, the payout control device 111, the sound lamp control device 113, and the display control device 114 can reliably receive the command transmitted from the main control device 110 (the payout control device 111, the sound lamp control device 113, and the display control). It is possible to prevent the device 114 from receiving a command from the main control device 110).

  Thereafter, it is determined whether or not the RAM erase switch 122 (see FIG. 3) provided in the power supply device 115 is turned on (S104). If it is turned on (S104: Yes), the process proceeds to S115. On the other hand, if the RAM erasure switch 122 is not turned on (S104: No), it is further determined whether or not the information on occurrence of power interruption is stored in the RAM 203 (S105), and if not stored (S105: No). Since there is a possibility that the process at the time of the previous power-off was not completed normally, the process proceeds to S115 also in this case.

  If power failure occurrence information is stored in the RAM 203 (S105: Yes), a RAM determination value is calculated (S106). If the calculated RAM determination value is not normal (S107: No), that is, the calculated RAM If the determination value does not match the RAM determination value stored at the time of power-off, the backed up data has been destroyed. In such a case as well, the process proceeds to S115. Note that the RAM determination value is, for example, a checksum value at the work area address of the RAM 203, as will be described later in the processing of S223 in FIG. Instead of the RAM determination value, the validity of the backup may be determined based on whether or not the keyword written in a predetermined area of the RAM 203 is correctly stored. The pachinko machine 10 is determined to be No in the process of S107 because the RAM determination value is always abnormal when the power is first turned on after being shipped from the production factory. Also in this case, the process proceeds to S115.

  In the process of S115, a payout initialization command is transmitted in order to initialize the payout control device 111 serving as a sub-side control device (peripheral control device) (S115). Upon receiving this payout initialization command, the payout control device 111 clears an area (work area) other than the stack area of the RAM 213, sets an initial value, and enters a state in which game ball payout control can be started. After transmitting the payout initialization command, main controller 110 executes initialization processing (S116, S117) of RAM 203.

  As described above, in the pachinko machine 10, when RAM data is initialized when the power is turned on, for example, at the start of business in a game arcade, the power is turned on while the RAM erase switch 122 is being pressed. Therefore, if the RAM erase switch 122 is pressed during the start-up process, the RAM initialization process (S116, S117) is executed. Similarly, initialization processing (S116, S117) of the RAM 203 is executed even when the information on occurrence of power interruption is not set or when a backup abnormality is confirmed by the RAM determination value (checksum value or the like). . In the RAM initialization process (S116, S117), the used area of the RAM 203 is cleared to 0 and the off-in-frame release flag 203a is turned off (S116), and then the initial value of the RAM 203 is set (S117). After executing the initialization process of the RAM 203, the process proceeds to S110.

  On the other hand, if the RAM erase switch 122 is not turned on (S104: No), the information on occurrence of power interruption is stored (S105: Yes), and the RAM judgment value (checksum value etc.) is normal ( (S107: Yes), the power-off occurrence information is cleared while the backed up data is held in the RAM 203 (S108), a payout return command is transmitted to the payout control device 111 (S109), and the process proceeds to S110. .

  In the process of S110, the voltage (reset signal SG3b) output from the frame opening detection circuit 260 to the input / output port 205 is read (S110). Then, it is determined whether or not the output from the frame opening detection circuit 260 to the input / output port (reset signal SG3b) is high (S111). If the output from the frame open detection circuit 260 to the input / output port is high (S111: Yes), the off-frame open flag 203a is turned on (S112). On the other hand, if the output from the frame opening detection circuit 260 to the input / output port is not high (S111: No), the process of S112 is skipped. Whether the output from the frame open detection circuit 260 to the input / output port (reset signal SG3b) is high or not depends on whether the voltage output from the frame open detection circuit 260 to the input / output port exceeds about 4.3 volts. It is judged by whether or not.

  If it is determined that the output from the frame opening detection circuit 260 to the input / output port is high (S111: Yes), the inner frame 12 or the front frame 14 is opened while the pachinko machine 10 is powered off. In addition to the case where the switch SW1 or the switch SW2 is turned on, the drive voltage Vb, the power failure signal SG1b, and the reset signal SG3b are output from the frame opening detection circuit 260 and the MPU 201 is temporarily started, two other patterns are considered. It is done. In the first pattern, when the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned off, and the power of the pachinko machine 10 is turned on within about 9.4 seconds from the opening, that is, the pachinko machine 10 When the power source 10 is off, the inner frame 12 or the front frame 14 is opened, and the driving voltage Vb, the power failure signal SG1b, and the reset signal SG3b are output from the frame open detection circuit 260. This is when the power is turned on. The second pattern is a case where the power of the pachinko machine 10 is turned on, the inner frame 12 or the front frame 14 is opened, and the reset signal SG3b is output from the frame open detection circuit 260 before the processing of S110. Even in the case of corresponding to the first pattern or the second pattern, there is no problem even if the off-in-frame opening flag 203a is turned on (S112). In order to fall under the first pattern or the second pattern, it is essential that the power of the pachinko machine 10 is turned on. The first pattern and the second pattern are the sales clerk before the game hall business hours. It is because it is a case where it is performed by. That is, when the first pattern or the second pattern is performed by the store clerk, at least the store clerk releases the inner frame 12 or the front frame 14 by itself when the power of the pachinko machine 10 is turned off. It is recognized that the power of the pachinko machine 10 is turned on within about 9.4 seconds from the opening (first pattern) or immediately after the power of the pachinko machine 10 is turned on by itself (processing of S110) This is because it is recognized that the inner frame 12 or the front frame 14 is opened by itself (before the second pattern). That is, even if the off-in-frame release flag 203a is turned on, the store clerk recognizes that the off-in-frame release flag 203a is on, and then opens the inner frame 12 or the front frame 14. is there. More specifically, the store clerk can perform an operation to turn off the off-in-frame release flag 203a again. Therefore, even if the output from the frame opening detection circuit 260 to the input / output port is determined to be high in the above two patterns (S111: Yes), there is no problem. That is, the above two patterns cannot occur in the normal use of the pachinko machine 10, so there is no problem even if they are not taken into consideration.

  As described above, when the power of the pachinko machine 10 is off, the inner frame 12 or the front frame 14 is opened, the switch SW1 or the switch SW2 is turned on, and the drive voltage Vb, the power failure signal SG1b and the reset are supplied from the frame open detection circuit 260. In addition to the case where the signal SG3b is output and the MPU 201 is temporarily started, also in the above two patterns, the output from the frame open detection circuit 260 to the input / output port is determined to be high (S111: Yes). ), The off-in-frame release flag 203a is turned on (S112).

  When it is determined No in S111 or when the process of S112 is executed, a payout return command at the time of power recovery for returning the sub-side control device (peripheral control device) to the gaming state when the drive power supply is shut off. Is transmitted (S113), and the process proceeds to S114. When the payout control device 111 receives this payout return command, the payout control device 111 is in a state where the payout control of the game ball can be started while holding the data stored in the RAM 213. In the process of S114, an interrupt is permitted and the process proceeds to a main process described later.

  As described above, the power of the pachinko machine 10 is turned off, and the inner frame 12 or the front frame 14 is opened during the off state, and the drive voltage Vb, the power failure signal SG1b, and the reset signal SG3b are output from the frame open detection circuit 260. When the MPU 201 is temporarily started up, the output from the frame open detection circuit 260 to the input / output port 205 becomes high (S111: Yes), and the off-frame open flag 203a is turned on (S112). .

  Note that the processes of S110 to S112 are executed immediately after the process of S109 is completed or immediately after the process of S117 is completed. That is, the processing of S110 to S112 is executed immediately after the various settings of the MPU 201 are completed. Therefore, when the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned off, the opening can be detected immediately by the processing of S110 to S112.

  Next, with reference to FIG. 12, the main process executed after the above-described startup process will be described. FIG. 12 is a flowchart showing main processing executed by the MPU 201 in the main controller 110. In this main process, the main process of the game is executed. As its outline, each process of S201 to S212 is executed as a periodic process with a period of 4 milliseconds, and each process of S215 to S220 is executed in the remaining time.

  In the main process, first, output data such as a command updated in the previous process is transmitted to each control device (peripheral control device) on the sub-side (S201). Specifically, the presence / absence of winning detection information detected in the switch reading process of S501 is determined, and if there is winning detection information, a winning ball command corresponding to the number of acquired balls is transmitted to the payout control device 111. In addition, by this external output process, a variation pattern command, a stop symbol command, a stop command, an effect time addition command, etc. necessary for the third symbol variation display by the third symbol display device 81 are transmitted to the sound lamp control device 113. Further, when launching a sphere, a sphere launch signal is transmitted to the launch controller 112.

  Next, each value of the variation type counters CS1, CS2, CS3 is updated (S202). Specifically, 1 is added to the variation type counters CS1, CS2, and CS3, and when the counter values reach the maximum values (198, 240, and 162 in this embodiment), they are cleared to 0, respectively. Then, the update values of the variation type counters CS 1, CS 2, and CS 3 are stored in the corresponding buffer area of the RAM 203.

  When the update of the variation type counters CS1, CS2, and CS3 is completed, the prize ball counting signal and the payout abnormality signal received from the payout control device 111 are read (S203). Thereafter, it is determined whether or not the off-in-frame release flag 203a is on (S204). If the off-in-frame release flag 203a is on (S204: Yes), the inner frame 12 or the front frame 14 is open while the power of the pachinko machine 10 is off, or it corresponds to the two patterns described above. An off-in-frame release command is transmitted to the control device 113 (S205). When the voice lamp control device 113 receives the off-in-frame release command, it controls the voice output device 226 and the lamp display device 227 to start notifying that the inner frame 12 or the front frame 14 has been opened. Further, a pulse signal having a pulse width of about 1 ms is output to the hall computer 262 (S206). The output pulse signal is stored in the hall computer 262 that continues to operate for 24 hours. In addition, when the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned off and the MPU 201 is temporarily started up, power is not supplied to the audio lamp control device 113. Even when the off-frame opening command is transmitted to the audio lamp control device 113, the audio output device 226 and the lamp display device 227 do not perform notification. Therefore, even if the inner frame 12 or the front frame 14 is opened by a fraudster while the power of the pachinko machine 10 is turned off, the pachinko machine 10 sets the off-middle frame release flag 203a without being recognized by the fraudster. Can be used to store the opening of the inner frame 12 or the front frame 14 (without notification by the audio output device 226 and the lamp display device 227, the inner frame 12 or the front frame can be stored using the off-in-frame opening flag 203a. Only open memory of the frame 14 can be performed).

  On the other hand, if the off-in-frame release flag 203a is off (S204: No), it is determined whether the on-in-frame release flag 203b is on (S207). If the on-in-frame release flag 203b is on (S207: Yes), an on-in-frame release command is transmitted to the audio lamp control device 113 (S208). When receiving the on-frame opening command, the sound lamp control device 113 controls the sound output device 226 and the lamp display device 227 to start notifying that the inner frame 12 or the front frame 14 has been opened. On the other hand, if the on-in-frame release flag 203b is off (S207: No), an on-in-frame closing command is transmitted to the audio lamp control device 113 (S209). When the sound lamp control device 113 receives the on-frame closing command, the sound lamp control device 113 terminates the notification performed by the sound output device 226 and the lamp display device 227. When the on-in-frame release flag 203b is on (S207: Yes), a pulse signal having a pulse width of about 1 ms may be output to the hall computer 262 after the processing of S208. In this case, since the output pulse signal is stored in the hall computer 262 that continues to operate for 24 hours, the hall computer 262 also identifies the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened. be able to.

  After the process of S206, S208 or S209 is completed, a process for displaying on the first symbol display device 37 or a variation process for setting a variation pattern of the third symbol on the third symbol display device 81 is executed (S210). Details of the variation process will be described later with reference to FIG.

  After the end of the variation process, the large opening opening / closing process for opening or closing the specific winning opening (large opening) 65a of the variable winning device 65 is executed in the case of the big win state (S211). That is, the specific winning opening 65a is opened for each round of the big hit state, and it is determined whether the maximum opening time of the specific winning opening 65a has elapsed or whether a specified number of balls have won the specific winning opening 65a. When any of these conditions is met, the specific winning opening 65a is closed. The opening and closing of the specific winning opening 65a is repeated for a predetermined number of rounds.

  Next, a display control process for the second symbol (for example, a symbol “◯” or “x”) by the second symbol display device 82 is executed (S212). Briefly, on the condition that the ball has passed through the second entrance (through gate) 67, the value of the second random number counter C4 is acquired at the timing of the passage, and the second symbol display device 82 is obtained. In the display unit 83, the second symbol variation display is performed. Then, the lottery of the second symbol is performed according to the value of the second winning random number counter C4, and when the winning state of the second symbol is reached, the electric accessory attached to the first entrance 64 is released for a predetermined time.

  Thereafter, it is determined whether or not the information on occurrence of power interruption is stored in the RAM 203 (S213). Has not been launched temporarily. Moreover, the fall of the power failure signal SG1a output from the power failure monitoring circuit 252 is not detected, and the power supply of the pachinko machine 10 is not shut off. Therefore, in such a case, it is determined whether or not the execution timing of the next main process has been reached, that is, whether or not a predetermined time (4 ms in the present embodiment) has elapsed since the start of the previous main process (S214). ). If the predetermined time has already passed (S214: Yes), the process proceeds to S201, and the processes after S201 described above are repeatedly executed.

  On the other hand, if the occurrence information of power interruption is stored in the RAM 203 (S213: Yes), the power of the pachinko machine 10 is turned off, and the inner frame 12 or the front frame 14 is opened while the power is turned off. As a result of the MPU 201 being temporarily raised by the frame opening detection circuit 260 and the power failure signal SG1b output from the frame opening detection circuit 260 falling, the NMI interruption processing of FIG. 17 has been executed, or the pachinko machine 10 When the power supply is turned on, the power supply is shut down due to the occurrence of a power failure or power off, and the power failure signal SG1a output from the power failure monitoring circuit 252 falls, so that the NMI interrupt process of FIG. 17 is executed. Therefore, the process at the time of power-off after S221 is executed. First, the generation of each interrupt process is prohibited (S221), and a power-off command indicating that the power has been cut off is sent to other control devices (peripheral control devices such as the payout control device 111 and the sound lamp control device 113). (S222). Then, the RAM determination value is calculated and stored (S223), access to the RAM 203 is prohibited (S224), and the infinite loop is continued until the power supply is completely shut down and the process cannot be executed. Here, the RAM determination value is, for example, a checksum value in the stack area and work area to be backed up in the RAM 203.

  In the process of S214, if the predetermined time has not yet elapsed since the start of the previous main process (S214: No), the remaining time until the predetermined time is reached, that is, until the execution timing of the next main process is reached. , The first initial value random number counter CINI1, the second initial value random number counter CINI2, and the variation type counters CS1, CS2, CS3 are repeatedly updated (S215, S216).

  First, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are updated (S215). Specifically, 1 is added to the first initial value random number counter CINI1 and the second initial value random number counter CINI2, and when the counter value reaches the maximum value (738, 250 in this embodiment), it is cleared to 0. To do. Then, the updated values of the first initial value random number counter CINI1 and the second initial value random number counter CINI2 are stored in the corresponding buffer areas of the RAM 203, respectively.

  Next, the fluctuation type counters CS1, CS2, and CS3 are updated (S216). Specifically, 1 is added to the variation type counters CS1, CS2, and CS3, and when the counter values reach the maximum values (198, 240, and 162 in this embodiment), they are cleared to 0, respectively. Then, the update values of the variation type counters CS1, CS2, and CS3 are stored in the corresponding buffer areas of the RAM 203, respectively.

  Here, since the execution time of each process of S201-S212 changes according to the state of the game, the remaining time until the next main process execution timing is not constant and varies. Therefore, by repeatedly executing the update of the first initial value random number counter CINI1 and the second initial value random number counter CINI2 using the remaining time, the first initial value random number counter CINI1 and the second initial value random number counter CINI2 (that is, , The initial value of the first random number counter C1 and the initial value of the second random number counter C4) can be updated at random, and similarly, the variation type counters CS1, CS2, and CS3 can be updated at random.

  After the process of S216, the voltage (reset signal SG3b) output from the frame opening detection circuit 260 to the input / output port 205 is read (S217). Then, it is determined whether or not the output (reset signal SG3b) from the frame opening detection circuit 260 to the input / output port is high (S218). If the output from the frame open detection circuit 260 to the input / output port is high (S218: Yes), the on-frame open flag 203b is turned on (S219). On the other hand, if the output from the frame open detection circuit 260 to the input / output port is not high (S218: No), the on-frame open flag 203b is turned off (S220). After the process of S219 or the process of S220, the process proceeds to the process of S213, and the processes after S213 are executed.

  Note that the power of the pachinko machine 10 is turned off, the inner frame 12 or the front frame 14 is opened while the power is turned off, the MPU 201 is temporarily started up by the frame open detection circuit 260, and the frame open detection circuit When the reset signal SG3b is output from 260, in addition to the off-in-frame release flag 203a, the on-in-frame release flag 203b is also turned on. This takes about 4.4 seconds from when the power failure signal SG1b becomes 5 volts until the power failure signal SG1b output from the power interruption signal output terminal of the frame open detection circuit 260 falls from 5 volts to zero volts ( It takes about 4.4 seconds until it is determined to be “Yes” in the process of S213), and in the meantime, the process of S218 is executed in addition to the start-up process, and “Yes” is determined in this process. It is.

  However, even if the on-in-frame release flag 203b is turned on in addition to the off-in-frame release flag 203a, if the power to the pachinko machine 10 is turned on next time, “Yes” is determined in the process of S204. Thus, the process does not proceed to S207 for determining the state of the on-in-frame release flag 203b. Therefore, main controller 110 can transmit only the off-in-frame release command to audio lamp controller 113. Therefore, when the MPU 201 is temporarily activated by the frame open detection circuit 260, the on-in-frame release flag 203b is turned on in addition to the off-in-frame release flag 203a, but this does not cause any problem. is there.

  On the other hand, when the inner frame 12 and the front frame 14 are not opened while the power of the pachinko machine 10 is turned off (when the inner frame 12 and the front frame 14 are closed), of course, The off-in-frame release flag 203a is not turned on. Therefore, when the power of the pachinko machine 10 is turned on next time, it is determined as “No” in the process of S204, and in addition to the process of S207 for determining the state of the on-frame open flag 203b, Of course, the process of S218 is also executed. Accordingly, when the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned on, the opening is detected by the processing of S217 and the processing of S218, and the processing of S208 executed thereafter. Thus, the main control device 110 can transmit only the on-frame open command to the sound lamp control device 113.

  As described above, if the off-in-frame release flag 203a is turned on (S204: Yes), the pachinko machine 10 transmits an off-in-frame release command to the audio lamp control device 113 (S205), and also to the hall computer 262. A pulse signal having a pulse width of about 1 ms is output (S206).

  Note that the power of the pachinko machine 10 is turned off, and the inner frame 12 or the front frame 14 is opened while the power is turned off, and the drive voltage Vb, the power failure signal SG1b, and the reset signal SG3b are output from the frame open detection circuit 260. S201 to S213: Yes to S224, which are executed when the MPU 201 is temporarily started up, at least the reset signal of the frame open detection circuit 260 by the discharge of the capacitor CD4 (see FIG. 7). The program is programmed so that the execution is completed during the period until the reset signal SG3b output from the output terminal drops to about 4.3 volts, that is, during the period of about 5.0 seconds (see FIG. 8). ing. Note that the period of about 5.0 seconds is irrespective of the opening time of the inner frame 12 or the front frame 14 (the inner frame 12 or the front frame 14 opened immediately after the inner frame 12 or the front frame 14 is opened). This is a period that always occurs due to discharge of the capacitor CD4 (see FIG. 8). Therefore, even when the MPU 201 is temporarily started up, the pachinko machine 10 temporarily turns on the off-in-frame release flag 203a regardless of the opening time of the inner frame 12 or the front frame 14. The MPU 201 that has started up can be normally terminated.

  In addition, the process of S213 is the timing when the end of a series of processes corresponding to the game state change performed in S201 to S212, or the end of one cycle of the processes of S215 to S220 performed within the remaining time. It is running. Therefore, in the main process of the main controller 110, the occurrence information of the power supply interruption is confirmed at the timing when each setting is completed. Therefore, when returning from the power interruption state, the process is performed after the start-up process is completed. It can start from the process of S201. That is, the process can be started from the process of S201 as in the case where the process is initialized in the startup process. Therefore, in the process at power-off, the stack pointer is not stored in the initial setting process (S101) without saving the contents of each register used by the MPU 201 to the stack area or saving the value of the stack pointer. By setting to a predetermined value (initial value), it is possible to start from the process of S201. Therefore, it is possible to reduce the control burden on the main control device 110 and to perform accurate control without causing the main control device 110 to malfunction or run away.

  Next, the fluctuation process (S204) will be described with reference to FIG. FIG. 13 is a flowchart showing the variation process (S204) executed in the main process (see FIG. 12). In this variation process, first, it is determined whether or not a big hit is currently being made (S301). The jackpot includes the jackpot game displayed on the third symbol display device 81 and the first symbol display device 37 in the jackpot and the middle of a predetermined time after the jackpot game ends. As a result of the determination, if it is a big hit (S301: Yes), this processing is terminated as it is.

  If it is not a big hit (S301: No), it is determined whether or not the display mode of the first symbol display device 37 is changing (S302), and if the display mode of the first symbol display device 37 is not changing. (S302: No), it is determined whether or not the number N of active suspension balls is greater than 0 (S303). If the number N of active balls is 0 (S303: No), this process is terminated. If the number of the operation hold balls N> 0 (S303: Yes), the operation hold ball number N is decremented by 1 (S304), and the data stored in the hold ball storage area is shifted (S305). This data shift process is a process of sequentially shifting the data stored in the reserved first to fourth areas of the reserved ball storage area to the execution area side, and the reserved first area → execution area, reserved second area → The data in each area is shifted such as the first hold area, the third hold area → the second hold area, the fourth hold area → the third hold area. After the data shift process, the fluctuation start process of the first symbol display device 37 is executed (S306). The variation start process will be described later with reference to FIG.

  In the process of S302, if it is determined that the display mode of the first symbol display device 37 is changing (S302: Yes), it is determined whether or not the change time has elapsed (S307). The display time during the change of the first symbol display device 37 is determined according to the change pattern selected by the change type counters CS1 and CS2 and the addition time selected by the change type counter CS3. If it has not elapsed (S307: No), the display of the first symbol display device 37 is updated (S308).

  In the present embodiment, among the LEDs 37a of the first symbol display device 37, for example, if the currently lit LED is red until the variation time elapses after the variation starts, the red LED is Turn off and turn on the green LED. If the green LED is on, turn off the green LED and turn on the blue LED. If the blue LED is on, turn on the blue LED. A display mode for turning off the red LED and turning on the red LED is set.

  Although the variation process is executed every 4 milliseconds, if the LED lighting color is changed every time the variation process is executed, the player cannot confirm the change in the LED lighting color. Therefore, a counter (not shown) is counted once each time the variation process is executed so that the player can confirm the change in the lighting color of the LED. Change the lighting color of. That is, the lighting color of the LED is changed every 0.4 seconds. The counter value is reset to 0 when the lighting color of the LED is changed.

  On the other hand, if the variation time of the first symbol display device 37 has elapsed (S307: Yes), a display mode corresponding to the stop symbol of the first symbol display device 37 is set (S309). In the setting of the stop symbol, whether or not a big hit is determined according to the value of the first per-random number counter C1, and in the case of a big hit, a symbol that becomes a high probability state after the big hit by the value of the first per-type type counter C2 Or a symbol that is in a low probability state is determined. In this embodiment, a red LED is turned on when a high probability state is reached after a big hit, a green LED is turned on when a low probability state is reached, and a blue LED is turned on when it is out of place. . In addition, although the lighting of each LED is released when the next fluctuation display is started, it may be turned on only for a few seconds after the fluctuation stops.

  When the display mode of the first symbol display device 37 corresponding to the stop symbol is set in the processing of S309, the variation stop of the third symbol display device 81 is stopped to synchronize with the lighting of the LED in the first symbol display device 37. A command is set (S310). When the sound lamp control device 113 receives this stop command, it instructs the display control device 114 to stop. When the variation time elapses, the third symbol display device 81 stops the variation, and receives the stop command, whereby one variation effect in the third symbol display device 81 ends.

  Next, the variation start process will be described with reference to FIG. FIG. 14 is a flowchart showing the change start process (S306) executed in the change process (see FIG. 13). In the variation start process (S306), first, it is determined whether or not a big hit is made based on the value of the first hit random number counter C1 stored in the execution area of the reserved ball storage area (S401). Whether or not it is a big hit is determined based on the relationship between the value of the first random number counter C1 and the mode at that time. As described above, “373,727” is a winning value among the numerical values 0 to 738 of the first random number counter C1 at the normal low probability, and “59, 109, 163, 211, 263, 317, 367, "421,479,523,631,683,733" is the winning value.

  When it is determined that it is a big hit (S401: Yes), the value of the first hit type counter C2 stored in the execution area of the reserved ball storage area is confirmed, and the display mode for the big hit is set (S402). ). In the process of S402, based on the value of the first hit type counter C2, whether to shift to the high probability state or shift to the low probability state after the big hit is set. When the transition state after the big hit is set, the display mode of the first symbol display device 37 (the lighting state of the LED 37a) is set. Further, based on the transition state after the jackpot, the jackpot stop symbol stopped and displayed on the third symbol display device 81 is set by the sound lamp control device 113 and the display control device 114. That is, the stop symbol in the third symbol display device 81 is set by setting the transition state after the big hit by the process of S402. Of the numerical values 0 to 4 of the first hit type counter C2, when “0, 4”, the state shifts to the low probability state, and when “1, 2, 3”, the state shifts to the high probability state. .

  Next, a variation pattern at the time of jackpot is determined (S403). When the variation pattern is set in the process of S403, the display time of the first symbol display device 37 is set and the variation time of the third symbol until the third symbol display device 81 stops at the jackpot symbol is determined. The At this time, the values of the fluctuation type counters CS1 and CS2 stored in the counter buffer of the RAM 203 are confirmed, and rough symbol fluctuations such as normal reach, super reach, and premium reach are determined based on the value of the first fluctuation type counter CS1. In addition to determining the variation time, the variation time (in other words, the number of variation symbols) until the final stop symbol (in the present embodiment, the middle symbol Z2) stops after the occurrence of reach is determined based on the value of the second variation type counter CS2. decide.

  The relationship between the numerical value of the first variation type counter CS1 and the variation time, and the relationship between the numerical value of the second variation type counter CS2 and the variation time are respectively defined in advance by a table or the like. However, the fluctuation time can be set using only the value of the first fluctuation type counter CS1 without using the value of the second fluctuation type counter CS2, and can be set only with the value of the first fluctuation type counter CS1. Whether or not to set with both values of both variation type counters CS1 and CS2 is appropriately determined according to the value of the first variation type counter CS1 and the game conditions each time.

  If it is determined in the process of S401 that it is not a big hit (S401: No), the display mode at the time of disconnection is set (S404). In the process of S404, the display mode of the first symbol display device 37 is set to the display mode corresponding to the off symbol, and based on the value of the stop pattern selection counter C3 stored in the execution area of the reserved ball storage area, An effect to be displayed on the third symbol display device 81 is set to indicate whether the reach is front / rear out of reach, reach other than front / rear out, or complete out. In the present embodiment, as described above, the range of values corresponding to each stop pattern of the stop pattern selection counter C3 depends on whether the state is a high probability state, a low probability state, and the operation suspension number N. Different tables are set up.

  Next, the variation pattern at the time of detachment is determined (S405), the display time of the first symbol display device 37 is set, and the variation time of the third symbol until the third symbol display device 81 stops at the detachment symbol. Is determined. At this time, as in the process of S403, the values of the variation type counters CS1 and CS2 stored in the counter buffer of the RAM 203 are confirmed, and the normal reach, super reach, and premium reach are determined based on the value of the first variation type counter CS1. In addition to determining the fluctuation time of the rough symbol variation such as, the variation time until the final stop symbol (the middle symbol Z2 in the present embodiment) stops after the reach occurs based on the value of the second variation type counter CS2 (in other words, paraphrase) For example, the number of fluctuating symbols) is determined.

  When the process of S403 or the process of S405 is completed, the effect time to be added to or subtracted from the variation time determined by the first and second type counters CS1 and CS2 is determined (S406). At this time, the addition / subtraction of effect time is determined based on the value of the third type counter CS3 stored in the counter buffer of the RAM 203, the display time of the first symbol display device 37 is set, and the third symbol display The variation time of the device 81 is set. In the present embodiment, the effect time addition / subtraction is determined according to the value of the third variation type counter CS3 when the variation display time is not changed and when the variation display time is added for one second, the variation display time is set to 2. In the case of adding seconds, four types of addition values are determined for the case of subtracting 1 second from the variable display time.

  In addition, when the variable display time is added or subtracted, a notice effect that increases the expected value of the jackpot on the third symbol display device 81 (for example, a slip effect that causes the change time of the variable symbol to be longer than usual and is accompanied by a slip) An effect of displaying a notice character is produced, for example, an effect of making the change time of one change symbol shorter than usual and stopping it immediately). In addition, when the value of the first random number counter C1 is a big hit, the probability that an added value of 2 seconds is selected is set high, so that the player expects a big hit by confirming the notice effect. Can do.

  Next, a variation pattern command is set according to the variation pattern (variation time) determined in S403 or S405 (S407), and a stop symbol command is set according to the stop symbol set in S402 or S404. (S408). Then, an effect time addition command is set according to the added value of the effect time determined in the process of S406 (S409), and the process returns to the variation process.

  Next, processing performed by the sound lamp control device 113 will be described with reference to FIGS. FIG. 18 is a flowchart showing a start-up process executed by the MPU 221 in the audio lamp control device 113, and this start-up process is started when the power is turned on.

  When the start-up process is executed, first, an initial setting process associated with power-on is executed (S1001). Specifically, a predetermined value set in advance for the stack pointer is set. Thereafter, depending on whether or not the power-off process flag is turned on, the power-on process in S1115 (see FIG. 19) is performed due to an instantaneous voltage drop (momentary power failure, so-called “momentary power failure”). ) Is determined during execution (S1002). As will be described later with reference to FIG. 19, when the sound lamp control device 113 receives a power-off command from the main control device 110 (see S1112 of FIG. 19), it executes a power-off process of S1115. The power-off process flag is turned on before the power-off process is executed, and the power-off process flag is turned off after the power-off process ends. Therefore, whether or not the power-off process in S1115 is in the middle of execution can be determined by the state of the power-off process in progress flag.

  If the power-off process flag is off (S1002: No), the current start-up process is started after the power supply is completely shut off, or after a momentary power failure occurs, and the power-off process at S1115 It was started after the execution of the process was completed, or started only after the MPU 221 of the sound lamp control device 113 was reset due to noise or the like (without receiving a power-off command from the main control device 110). is there. Therefore, in these cases, it is confirmed whether or not the data in the RAM 223 is destroyed (S1003).

  Confirmation of data destruction of the RAM 223 is performed as follows. That is, data as a keyword “55AAh” is written in a specific area of the RAM 223 by the process of S1006. Therefore, the data stored in the specific area is checked, and if the data is “55AAh”, there is no data destruction in the RAM 223. Conversely, if the data is not “55AAh”, the data destruction in the RAM 223 can be confirmed. If data destruction of the RAM 223 is confirmed (S1003: Yes), the process proceeds to S1004, and initialization of the RAM 223 is started. On the other hand, if data destruction of the RAM 223 is not confirmed (S1003: No), the process proceeds to S1008.

  If the current start-up process is started after the power supply is completely shut down, the keyword “55AAh” is not stored in the specific area of the RAM 223 (the memory in the RAM 223 is lost due to the power-off). ), It is determined that the data in the RAM 223 is destroyed (S1003: Yes), and the process proceeds to S1004. On the other hand, this startup process was started after an instantaneous power failure and after completing the power-off process in S1115, or reset only to the MPU 221 of the audio lamp control device 113 due to noise or the like. When the process starts, since the keyword “55AAh” is stored in the specific area of the RAM 223, the data in the RAM 223 is determined to be normal (S1003: No), and the process proceeds to S1008.

  If the power-off process flag is on (S1002: Yes), the startup process of this time is after an instantaneous power failure, and during the execution of the power-off process of S1115, the sound lamp control device 113. The MPU 221 is started after being reset. In such a case, since the power-off process is being executed, the storage state of the RAM 223 is not necessarily correct. Therefore, since control cannot be continued in such a case, the process proceeds to S1004 and initialization of the RAM 223 is started.

  In the processing of S1004, the entire storage area of the RAM 223 is checked (S1004). As a check method, first, “0FFh” is written for each byte, and it is read for each byte to check whether it is “0FFh”. If “0FFh”, it is determined as normal. The writing and checking for each byte are performed in the order of “55h”, “0AAh”, and “00h” after “0FFh”. This RAM 223 read / write check clears all storage areas of the RAM 223 to zero.

  If it is determined that the read / write check is normal for all the storage areas of the RAM 223 (S1005: Yes), the keyword “55AAh” is written in the specific area of the RAM 223, and the RAM destruction check data is set (S1006). By checking the keyword “55AAh” written in the specific area, it is checked whether or not there is data corruption in the RAM 223. On the other hand, if an abnormality in the read / write check is detected in any storage area of the RAM 223 (S1005: No), the abnormality of the RAM 223 is notified (S1007), and an infinite loop is performed until the power is shut off. The abnormality of the RAM 223 is notified by the display lamp 34. Note that the audio output device 226 may output a sound to notify the RAM 223 of an abnormality.

  In the process of S1008, it is determined whether or not the power-off flag is turned on (S1008). Since the power-off flag is turned on when the power-off process in S1115 is executed (see S1114 in FIG. 19), the power-off flag is turned on by the process in S1114 as described later with reference to FIG. In other words, since the power-off flag is turned on before the power-off process in S1115 is executed, the current start-up process is instantaneous because the power-off flag is turned on to reach the process in S1008. This is a case where a power failure has occurred and started in a state where the execution of the power-off process in S1115 is not completed. Therefore, in such a case (S1008: Yes), the RAM work area is cleared to initialize each process of the sound lamp control device 113 (S1009), and the initial value of the RAM 223 is set (S1010), and then the interrupt is performed. The permission is set (S1011), and the process proceeds to the main process. Note that the work area of the RAM 223 is an area other than an area for storing commands received from the main control device 110.

  On the other hand, when the power-off flag is turned off, the process of S1008 is reached because the current start-up process is started after, for example, the power supply is completely shut down. This is a case where the processing has been reached, or the MPU 221 of the sound lamp control device 113 is reset only (without receiving a power-off command from the main control device 110) due to noise or the like. Therefore, in such a case (S1008: No), S1009 which is the work area clear process of the RAM 223 is skipped, the process proceeds to S1010, the initial value of the RAM 223 is set (S1010), and the interrupt permission is set. Then (S1011), the process proceeds to the main process.

  The reason for skipping the clear process of S1009 is that when the process from S1004 to S1006 is reached via the process of S1006, all the storage areas of the RAM 223 have already been cleared by the process of S1004. When only the MPU 221 of the sound lamp control device 113 is reset due to noise or the like and the start-up process is started, the data in the work area of the RAM 223 is stored without being cleared, so that the sound lamp control device 113 is saved. This is because the control can be continued.

  Next, with reference to FIG. 19, the main process executed after the startup process of the sound lamp control device 113 will be described. FIG. 19 is a flowchart showing main processing executed by the MPU 221 of the sound lamp control device 113. When the main process is executed, it is first determined whether or not 1 msec or more has elapsed since the main process was started (S1101). If 1 msec or more has not elapsed (S1101: No), S1102 to S1109. The process proceeds to S1110 without performing the process. Whether or not 1 msec has passed in the processing of S1101 is the processing related to display (production) in S1102 to S1109, and it is not necessary to edit in a short cycle (within 1 msec), whereas in S1110 This is because it is preferable to execute the counter update process and the command reception process of S1111 in a short cycle. As a result, it is possible to prevent omission of a command transmitted from the main controller 110.

  If 1 msec or more has elapsed in the processing of S1101 (S1101: Yes), the setting of the lighting mode of the display lamp 34 and the output of each lamp are set so that the lighting mode of the lamp edited in the processing of S1107 described later is set. (S1102) Then, a power-on notification process is executed (S1103). In the power-on notification process, when the power is turned on, a notification is given to notify that the power is turned on for a predetermined time (for example, 30 seconds). The notification is performed by the audio output device 226 or the lamp display device 227. Is called. Moreover, it is good also as what transmits a command to the display control apparatus 114 to alert | report that power was supplied on the screen of the 3rd symbol display apparatus 81. FIG. If the power is not turned on, the process proceeds to S1104 without performing the notification by the power-on notification process.

  In the process of S1104, a waiting-for-customer effect is executed, and then a hold number display update process is executed (S1105). In the customer waiting effect, when a time during which the pachinko machine 10 is not played by the player has elapsed for a predetermined time, setting for switching the display of the third symbol display device 81 to the title screen is performed, and the setting is displayed as a command as a display control device. 114. In the number-of-holds display update process, a process for turning on the hold lamp 85 in accordance with the operation hold ball N is performed.

  Thereafter, frame button input monitoring / effect processing is executed (S1106). This frame button input monitoring / production process monitors the input of whether or not the frame button 22 operated by the player has been pressed to enhance the production effect, and corresponds to the case where the input of the frame button 22 is confirmed. This is a process for setting to produce an effect. For example, when a notice character appears at the start of fluctuation display, the expected value of the jackpot due to the current fluctuation is displayed by pressing the frame button 22, or the feeling of expectation for the jackpot is displayed by pressing the frame button 22 during reach production. It is good also as a decision button for changing to the production which can have, or selecting one reach production out of a plurality of reach productions. If the frame button 22 is not provided, the process of S1106 is omitted.

  When the frame button input monitoring / production process ends, the lamp editing process is executed (S1107), and then the sound editing / output process is executed (S1108). In the lamp editing process, lighting patterns and the like of the illumination units 29 to 33 are set so as to correspond to the display performed on the third symbol display device 81. In the sound editing / output process, an output pattern of the sound output device 226 is set so as to correspond to the display performed on the third symbol display device 81, and sound is output from the sound output device 226 according to the setting.

  Thereafter, a liquid crystal effect execution management process is executed (S1109), and the process proceeds to S1110. In the liquid crystal effect execution management process, a time synchronized with the time required for the variable display performed by the third symbol display device 81 is set based on the change pattern command and the effect time addition command transmitted from the main control device 110. Based on the time set in the liquid crystal effect execution monitoring process, the effect time of the lamp editing process in S1107 and the sound editing / output process in S1108 is set.

  In the process of S1110, the variable display process of the third symbol display device 81 is executed. In this variation display process, a plurality of counters (a counter for setting a stop symbol at the time of big hit, a counter for selecting a stop symbol at the time of disconnection, etc.) mounted on the sound lamp control device 113 are updated. Based on the variation pattern command and the stop symbol command transmitted from the control device 110, the symbol to be stopped and displayed on the third symbol display device 81 is set, or the variation display pattern (rear / rear out, front / rear non-rear reach, complete out) Etc. are set. The stop symbol and the variation pattern are transmitted to the display control device 114 as a command.

  In the process of S1110, for example, when the command of the variation pattern transmitted from the main controller 110 is “completely out”, a complete out A pattern is selected from a plurality of patterns corresponding to complete out, and the third symbol display A command is transmitted to the display control device 110 so that the device 81 can produce a completely off A pattern. Therefore, since the detailed variation pattern displayed on the third symbol display device 81 is determined by the sound lamp control device 113 with respect to one variation pattern determined by the main control device 110, the control of the main control device 110 is performed. The burden can be reduced. Furthermore, since the pattern of each effect determined in the main controller 110 can be reduced, the storage capacity of the ROM 202 can be reduced and the cost can be reduced.

  Then, the command from the main control device 110 is received (S1111). When a command from the main control device 110 is received, if the command is used in the sound lamp control device 113 according to the command, processing corresponding to the command is performed, the processing result is stored in the work RAM 233, and the display control device 114 If it is a command to be used, the command is transmitted to the display control device 114.

  When the processing of S1111 is completed, it is determined whether or not the information on occurrence of power interruption is stored in the work RAM 233 (S1112). The information on the occurrence of power-off is stored when a power-off command is received from the main controller 110. If power failure occurrence information is stored in the processing of S1112 (S1112: Yes), both the power interruption flag and the power interruption processing flag are turned on (S1114), and the power interruption processing is executed (S1115). After the power-off process is executed, the power-off process flag is turned off (S1116), and then the process loops infinitely. In the power-off process, the generation of the interrupt process is prohibited and each output port is turned off to turn off the output from the audio output device 226 and the lamp display device 227. Further, the storage of the information on occurrence of power interruption is also erased.

  On the other hand, if the information on the occurrence of power interruption is not stored in the process of S1112 (S1112: No), either the inner frame 12 or the front frame 14 is opened, or both the inner frame 12 and the front frame 14 are opened. If there is, a door opening notification process (S1113) for performing notification using the audio output device 226 and the lamp display device 227 is executed.

  Here, the door opening notification process (S1113) will be described with reference to FIG. FIG. 20 is a flowchart showing a door opening notification process executed by the MPU 221 of the sound lamp control device 113. In this door opening notification process, it is determined whether the voice lamp control device 113 has received any command of an off-frame open command, an on-frame open command, or a frame close command, and a notification is made according to the determination. It is a process that starts or ends execution.

  In the door opening notification process, first, in the process of S1111 (see FIG. 19), an off-in-frame release command indicating that the inner frame 12 or the front frame 14 has been opened while the power of the pachinko machine 10 is turned off is received. It is determined whether or not it has been done (S1201). When the off-in-frame release command is received (S1201: Yes), the voice output device 226 and the lamp display device indicate that the inner frame 12 or the front frame 14 has been released while the power of the pachinko machine 10 is turned off. Notification is started using 227 (S1202). Specifically, in this notification, for example, in order to indicate that the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned off using the lamp display device 227, for example, 1 The flashing is started once per second, or the voice output device 226 is used to start notification with an electronic sound “please check”. Thereby, it is possible to notify an unspecified number of persons that the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned off.

  After the processing of S1202, this frame release notification processing is terminated. In addition, when the notification by the process of S1202 is already executed, when the off-in-frame release command is received again by the process of S1111 (S1201: Yes), the process of S1202 is not performed again. The process of S1202 that has already been executed is continued.

  On the other hand, in the process of S1111 (see FIG. 19), when the off-in-frame release command is not received (S1201: No), the power of the pachinko machine 10 is turned on in the process of S1111 (see FIG. 19). It is determined whether or not an on-in-frame frame release command indicating that the inner frame 12 or the front frame 14 has been opened is received (S1203). When the on-frame opening command is received (S1203: Yes), the voice output device 226 and the lamp display device indicate that the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned on. Notification is started using 227 (S1204). Specifically, in this notification, for example, in order to indicate that the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned on using the lamp display device 227, for example, 2 Flashing once per second is started, or the sound output device 226 is used to start notification with an electronic sound that “the door is open”. Thereby, it is possible to notify an unspecified number of persons that the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned on.

  Further, if the on-frame release command has not been received in the processing of S1111 (see FIG. 19) (S1203: No), the power of the pachinko machine 10 is turned on in the processing of S1111 (see FIG. 19). During this time, it is determined whether or not an on-medium frame closing command indicating that the inner frame 12 and the front frame 14 are closed is received (S1205). When the on-in-frame closing command is received (S1205: Yes), the notification started in the process of S1204 is terminated (S1206). Thereafter, the frame opening notification process is terminated. If the on-in-frame closing command has not been received in the processing of S1111 (see FIG. 19) (S1205: No), this frame opening notification processing is terminated.

  As described above, when the voice lamp control device 113 receives the off-in-frame release command in the process of S1111 (see FIG. 19), the inner frame 12 or the front frame while the power of the pachinko machine 10 is turned off. 14 starts to be notified using the audio output device 226 and the lamp display device 227 (S1202). This notification is made until the RAM erase switch 122 is operated, the power of the pachinko machine 10 is turned on, and the off-in-frame release flag 203a is turned off in S116 of the start-up process of the main controller 110. Continued.

  Thus, in order to turn off the off-in-frame release flag 203a once turned on, the RAM erase switch 122 is operated and the power of the pachinko machine 10 is turned on, and the used RAM area is not cleared in the process of S116. The off-in-frame release flag 203a cannot be turned off. Therefore, when the power of the pachinko machine 10 is turned on, the pachinko machine 10 does not reliably confirm that the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned off. It is possible to notify a specific number of people.

  Further, as described above, when the sound lamp control device 113 receives the on-in-frame release command in the process of S1111 (see FIG. 19), Notification that the front frame 14 has been opened is started using the audio output device 226 and the lamp display device 227 (S1204). This notification is continuously performed until the inner frame 12 and the front frame 14 are closed and the on-in-frame closing command is received. An unspecified number of people can be notified that the frame 14 is open.

  Returning to the description of FIG. After the door opening notification process (S1113) is executed, it is determined whether or not the RAM 223 is destroyed based on the keyword stored in the RAM 223 (S1117). If the RAM 223 is not destroyed (S1117: No), Returning to the process, the main process is repeatedly executed. On the other hand, if the RAM 223 is destroyed (S1117: Yes), the process is looped infinitely in order to stop the subsequent processes. Here, if it is determined that the RAM is destroyed and an infinite loop is performed, the main process is not executed, and thereafter the display on the third symbol display device 81 does not change. Therefore, since the player can know that an abnormality has occurred, he can call a hall clerk or the like and request repair of the pachinko machine 10 or the like. Further, when it is confirmed that the RAM 223 is destroyed, the sound output device 226 or the lamp display device 227 may notify the RAM destruction.

  As described above, according to the pachinko machine 10, when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is off, the frame open detection circuit 260 detects the drive voltage Vb and After outputting the power failure signal SG1b, the reset signal SG3b is output. Therefore, even when the power of the pachinko machine 10 is turned off, the MPU 201 can be temporarily started up normally. When the power of the pachinko machine 10 is off and the MPU 201 is temporarily activated by the frame opening detection circuit 260, the pachinko machine 10 turns on the off-frame open flag 203a. When the off-in-frame release flag 203a is turned on, the pachinko machine 10 uses the audio output device 226 and the lamp display device 227 when the power to the pachinko machine 10 is turned on next time, and the inner frame 12 or the front frame. Informs that 14 is opened. Therefore, the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off can be specified. Therefore, even in a game arcade where the hall computer 262 has not been operated for 24 hours, it is possible to detect that the inner frame 12 or the front frame 14 has been opened when the pachinko machine 10 is powered off.

  Further, the off-in-frame release flag 203a is turned off when the RAM deletion switch 122 is operated and the used RAM area is cleared in the process of S116 of the startup process of the main controller 110. Therefore, once the off-in-frame release flag 203a is turned on, the off-in-frame release flag 203a cannot be turned off unless the RAM erase switch 122 is operated to clear the used RAM area in the process of S116. Therefore, when the inner frame 12 or the front frame 14 is opened and the off-in-frame release flag 203a is turned on when the power of the pachinko machine is turned off, the fraudster then turns off the off-in-frame. It is possible to disable the release flag 203a from being turned off. Further, the off-frame open flag 203a cannot be turned off unless the RAM erase switch 122 is operated to clear the used RAM area in the process of S116. Therefore, when the power of the pachinko machine 10 is turned on, The pachinko machine 10 can reliably notify an unspecified number of people that the inner frame 12 or the front frame 14 has been opened when the power of the pachinko machine 10 is turned off.

  In addition, when the MPU 201 is temporarily activated by the frame opening detection circuit 260 when the power of the pachinko machine 10 is off, the pachinko machine 10 turns on the off-in-frame opening flag 203a, in addition to turning on the hall computer A pulse signal having a pulse width of 1 msec is output to 262. The output pulse signal is stored in the hall computer 262 that continues to operate for 24 hours. Therefore, by analyzing the pulse signal stored in the hall computer 262, the pachinko machine 10 in which the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off is specified. Can do. Furthermore, the hall computer 262 outputs a pulse signal from the pachinko machine 10 and stores the output time of the output pulse signal, thereby allowing the inner frame 12 of the specified pachinko machine 10 to be opened or the front frame. 14 open times can be detected.

  Further, the frame open detection circuit 260 first stops the power failure signal SG1b when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on and about 4.4 seconds have elapsed after the turn-on. If the opened inner frame 12 or the opened front frame 14 is closed before the switch SW1 or the switch SW2 is turned on and about 4.4 seconds have passed since the turn-on, the stop signal is displayed at the time of closing. SG1b is stopped). Next, the frame open detection circuit 260 stops the reset signal SG3b when about 9.4 seconds have elapsed after the switch SW1 or SW2 is turned on (about 4.4 seconds have passed after the switch SW1 or switch SW2 is turned on). If the opened inner frame 12 or the opened front frame 14 is closed before, the reset signal SG3b is stopped after about 5.0 seconds from the closing). The frame opening detection circuit 260 reduces the drive voltage Vb output to the power supply terminal of the MPU 201 to about 4.0 volts when about 9.9 seconds have elapsed after the switch SW1 or SW2 is turned on (switch SW1 or SW2). If the opened inner frame 12 or the opened front frame 14 is closed before about 4.4 seconds have elapsed after the switch SW2 is turned on, the drive is performed after about 5.5 seconds have elapsed since the closing. Voltage Vb is reduced to about 4.0 volts). Therefore, even if the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine 10 is turned off and the MPU 201 is temporarily activated by the frame opening detection circuit 260, the frame opening detection circuit 260 The launched MPU 201 can be normally terminated.

  Further, the frame opening detection circuit 260 opens the inner frame 12 or the front frame when approximately 4.4 seconds elapses after the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on. The transistor TR1 stops the output of the drive voltage Vb, the output of the reset signal SG3b, the output of the power failure signal SG1b, and the charging of the capacitor CD4 performed by the electric power supplied from the capacitor CD1, regardless of the open period 14. After the stop by the transistor TR1, the frame opening detection circuit 260 outputs the drive voltage Vb and the reset signal SG3b by discharging the capacitor CD4. Therefore, the frame opening detection circuit 260 is, for example, when the game hall is closed and the power supply to the pachinko machine 10 is cut off, and the DC power supply DC1 of 12 volts is not supplied to the frame opening detection circuit 260. That is, when a DC voltage of about 11.3 volts is supplied from the capacitor CD1 to the frame open detection circuit 260, the period during which power is supplied from the capacitor CD1 is the open period of the inner frame 12 or the front frame 14. Regardless, it can remain in about 4.4 seconds. Therefore, the frame opening detection circuit 260 can detect the opening of the inner frame 12 or the front frame 14 a plurality of times while suppressing the consumption of the electric power charged in the capacitor CD1.

  Further, the frame open detection circuit 260 is configured so that even if the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on, the inner frame 12 or the front frame 14 is opened before approximately 4.4 seconds elapses. When the frame 12 or the opened front frame 14 is closed, the switch SW1 or the switch SW2 is cut off, the output of the drive voltage Vb performed by the power supplied from the capacitor CD1, the output of the reset signal SG3b, the power failure signal SG1b And the charging of the capacitor CD4 are stopped. After the inner frame 12 and the front frame 14 are closed, the drive voltage Vb and the reset signal SG3b are output by discharging the capacitor CD4.

  As described above, when the charging of the capacitor CD4 is completed, the driving voltage Vb and the reset signal SG3b can be output by discharging the capacitor CD4. Therefore, the open period of the inner frame 12 or the front frame 14 is approximately If the time is within 4.4 seconds, the output voltage Vb, the reset signal SG3b, the power failure signal SG1b, and the capacitor CD4 charged by the power supply from the capacitor CD1 are further shortened. Can be stopped. Therefore, the power consumption of the capacitor CD1 due to the opening of the inner frame 12 or the front frame 14 can be further suppressed.

  Here, since the capacitor CD1 has a capacitance of 1F and the voltage applied to the capacitor CD1 is approximately 11.3 volts, the charge stored in the capacitor CD1 is the product of the capacitance of the capacitor CD1 and the applied voltage of the capacitor CD1. To about 11.3 C (coulomb). The charge of about 11.3 C stored in the capacitor CD1 is approximately during the periods of the output of the drive voltage Vb, the output of the reset signal SG3b, the output of the power failure signal SG1b, and the charge of the capacitor CD4 performed by the power supply from the capacitor CD1. In the case of 4.4 seconds, this corresponds to about 11 times of power supply. Therefore, for example, when the business hours of the amusement hall are over and the power supply to the pachinko machine 10 is shut off and a DC voltage of 12 volts is not supplied from the DC power supply DC1, the inner frame 12 is opened (the switch SW1 Continuity) or the opening of the front frame 14 (conduction of the switch SW2) is performed a plurality of times, the frame opening detection circuit 260 opens the inner frame 12 or the front frame 14 (conduction or conduction of the switch SW1). The conduction of the switch SW2) is reliably detected every time up to about 11 times, and the MPU 201 can be normally raised normally to turn on the off-in-frame release flag 203a. At this time, when the opening of the inner frame 12 or the opening of the front frame 14 is about 11 times, the power stored in the capacitor CD1 decreases, the drive voltage Vb decreases, the reset signal SG3 decreases, the power failure signal SG1 decreases. Decrease and the charge amount of the capacitor CD4 occur. However, when the inner frame 12 or the front frame 14 is opened, the voltage of the reset signal SG3b output from the reset signal output terminal of the frame open detection circuit 260 exceeds about 4.3 volts, and the frame open detection circuit 260 If the voltage of the drive voltage Vb output from the power supply output terminal and the voltage of the power failure signal SG1b output from the power interruption signal output terminal of the frame opening detection circuit 260 exceed about 4.0 volts, the power of the pachinko machine 10 is Even if it is off, the MPU 201 can be temporarily started up normally and the off-in-frame release flag 203a can be turned on. Furthermore, a pulse signal having a pulse width of 1 msec can be output to the hall computer 262.

  In frame open detection circuit 260, when inner frame 12 and front frame 14 are closed (when switches SW1 and SW2 are shut off), the OUT terminal voltage of timer IC1 is about 10.6 volts. Therefore, the terminal between the drain terminal D and the source terminal S of the FET 1 of the frame opening detection circuit 260 and the terminal between the drain terminal D and the source terminal S of the FET 2 are brought into conduction. Further, since the inner frame 12 and the front frame 14 are closed, the terminal between the drain terminal D and the source terminal S of the FET 3 is in a conductive state. However, at this time, the conduction between the terminals of the emitter terminal e and the collector terminal c of the transistor TR1 is cut off, so that the terminal between the drain terminal D and the source terminal S of the FET1 and the drain terminal D and the source terminal of the FET2 are separated. The current from the capacitor CD1 does not flow between the terminals with S and between the drain terminal D and the source terminal S of the FET 3. Therefore, when the inner frame 12 and the front frame 14 are closed, the power charged in the capacitor CD1 is between the drain terminal D and the source terminal S of the FET1, and between the drain terminal D and the source terminal S of the FET2. It does not flow between terminals and between the drain terminal D and the source terminal S of the FET 3 and is not consumed.

  Further, the amount of power that the frame open detection circuit 260 consumes the power of the capacitor CD1 in a state where the power of the pachinko machine 10 is turned off and the inner frame 12 and the front frame 14 are closed is the standby power of the timer IC1 and the power consumption of the NOTIC3. Degree. Moreover, since only a voltage is applied to each gate terminal G in FET1 to FET3, the power consumed in FET1 to FET3 is very small. Therefore, the consumption of these powers does not cause a significant decrease in the charge amount of the capacitor CD1.

  In the pachinko machine 10 according to the present embodiment, the notification that the inner frame 12 or the front frame 14 has been opened is performed using the audio output device 226 and the lamp display device 227 controlled by the audio lamp control device 113. However, it is not limited to this. The notification that the inner frame 12 or the front frame 14 has been opened is not performed using the audio output device 226 and the lamp display device 227 controlled by the audio lamp control device 113, but can be operated with the rise of the MPU 201. Of course, it is also possible to use an audio output device or a lamp display device that the MPU 201 controls. However, in this case, when the power of the pachinko machine 10 is turned off, the inner frame 12 or the front frame 14 is opened by an unauthorized person, and the MPU 201 is temporarily started up by the frame opening detection circuit 260. Then, the audio output device and the lamp display device that are controlled by the MPU 201 are also started up, and when the off-in-frame opening flag 203a is turned on, the unauthorized person is notified. This is executed when the power of the pachinko machine 10 is turned off, the inner frame 12 or the front frame 14 is opened while the power is turned off, and the MPU 201 is temporarily started up by the frame open detection circuit 260. The processing of S201 to S213: Yes to S224 (see FIG. 12), which is performed, is performed when at least the reset signal SG3b output from the reset signal output terminal of the frame opening detection circuit 260 by the discharge of the capacitor CD4 is about 4. The program is programmed to complete execution during the period until it drops to 3 volts, that is, during a period of about 5.0 seconds (see FIG. 8). Taking advantage of this specification, when the MPU 201 performs notification using a sound output device or a lamp display device, the time from when the power of the pachinko machine 10 is turned on is counted by a counter. For example, the power of the pachinko machine 10 is What is necessary is just to comprise so that alerting | reporting may be started 30 seconds after turning on (after a counter time-measures 30 seconds). Then, when the MPU 201 is temporarily started up by the frame opening detection circuit 260, 30 seconds after the pachinko machine 10 is turned on, that is, before the counter measures 30 seconds. Since the MPU 201 is shut down (because it is terminated), the notification is not executed. On the other hand, if the MPU 201 is started up with the power of the pachinko machine 10 turned on normally, the notification is performed. Notification can be performed when the power of the pachinko machine 10 is turned on normally, while preventing notification to the actor.

  In the pachinko machine 10 of the present embodiment, the driving is performed when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is conductive when the power of the pachinko machine 10 is turned off. Although the output of the voltage Vb, the output of the reset signal SG3b, the output of the power failure signal SG1b, and the charging of the capacitor CD4 are started, the present invention is not limited to this. That is, when the connection of each component mounted on the frame opening detection circuit 260 of the pachinko machine 10 is changed, the inner frame 12 or the front frame 14 is opened, and the opened inner frame 12 or the front frame 14 is closed In addition, from the closing time, the output of the drive voltage Vb, the output of the reset signal SG3b, the output of the power failure signal SG1b, and the charging of the capacitor CD4 may be started.

  However, in the frame open detection circuit 260 of the pachinko machine 10 according to the present embodiment, the output of the reset signal SG3b is started when the inner frame 12 or the front frame 14 is opened and the switch SW1 or the switch SW2 is turned on. Thus, the opening of the inner frame 12 or the front frame 14 can be detected quickly. Therefore, particularly during business hours when the power of the pachinko machine 10 is turned on, the inner frame 12 or the front frame 14 is opened before the main controller 110 or the game board 13 is cheated. Alternatively, the opening of the front frame 14 can be detected. Accordingly, it is possible to prevent an abnormal operation due to an illegal act that occurs when power is supplied to the pachinko machine 10.

  In addition, the main frame opening detection circuit 260 is used to separately store which of the inner frame 12 and the front frame 14 is opened using a flag, and separately notify the opening of the inner frame 12 or the front frame 14. When it is desired to separately store in the hall computer 262 which of the inner frame 12 and the front frame 14 is opened, the following configuration may be used. First, one new frame opening detection circuit 260 used in this embodiment is added, the switch SW2 connected in parallel to the switch SW1 is disconnected, and the disconnected switch SW2 is newly added to the newly opened frame opening detection circuit 260. Connecting. Specifically, one end of the disconnected switch SW2 is connected to one end of the capacitor CD1 of the newly added frame opening detection circuit 260, the VDD terminal of the timer IC1, and the RES terminal of the timer IC1, and other than the disconnected switch SW2. The ends may be connected to one end of the resistor R1 of the newly provided frame opening detection circuit 260, one end of the resistor R2, the input terminal of the NOTIC3, one end of the resistor R3, and the emitter terminal e of the transistor TR1.

  Then, the power supply output terminal, reset signal output terminal, and power interruption signal output terminal of the added frame opening detection circuit 260 are replaced with the power supply output terminal, reset signal output terminal, and power interruption signal output of the existing frame opening detection circuit 260, respectively. Connect in parallel to the terminals. Further, the reset signal output terminal of the added frame opening detection circuit 260 is connected to an input port different from the input port to which the reset signal output terminal of the existing frame opening detection circuit 260 is connected to the input / output port 205. Thus, the MPU 201 can be temporarily activated separately when the switch SW1 is conductive (the inner frame 12 is opened) and when the switch SW2 is conductive (the front frame 14 is opened). Further, when the switch SW1 is conductive (the inner frame 12 is opened), the reset signal SG3b output from the existing frame open detection circuit 260 and the switch SW2 is conductive (the front frame 14 is opened). In addition, the reset signal SG3b output from the newly added frame opening detection circuit 260 can be separately output to the input / output port 205.

  In addition, the RAM 203 is provided with four flags: an off-inner frame release flag, an off-front frame release flag, an on-inner frame release flag, and an on-front frame release flag. In step S110 of the start-up process (see FIG. 11), the voltage (reset signal SG3b) output from the existing frame opening detection circuit 260 to the input / output port 205 is read, and a newly added frame opening detection is performed. The voltage (reset signal SG3b) output from the circuit 260 to the input / output port 205 may be read. In accordance with the read result, in the process of S112, the off inner frame release flag or the off front frame release flag is turned on separately.

  In the process of S205 of the main process (see FIG. 12), when the off-inner frame release flag is turned on, an “off-inner frame release command” is transmitted from the MPU 201 to the sound lamp controller 113, and the off-inner frame release command is turned off. When the middle front frame release flag is turned on, the MPU 201 transmits an “off middle front frame release command” to the sound lamp control device 113. When the voice lamp control device 113 receives each command transmitted from the MPU 201 when the power of the pachinko machine 10 is turned on, the voice lamp control device 113 receives the off-inner frame release command and is off. Different notifications are made when a front frame release command is received. For example, a different warning sound is emitted from the audio output device 226 or the lighting mode of the lamp display device 227 is changed.

  Further, the pulse width of the pulse signal transmitted from the pachinko machine 10 to the hall computer 262 may be changed in the process of S206 according to the on state of each flag of the off-inner frame open flag or the off-front frame open flag. For example, a pulse signal with a pulse width of about 1 msec is transmitted to the hall computer 262 when the off-inner inner frame opening flag is on, and when the off-front frame opening flag is on, the pulse width is about 2 msec. A pulse signal may be transmitted to the hall computer 262. Thus, when the pachinko machine 10 is powered off, the pachinko machine 10 can separately notify whether the inner frame 12 has been opened or the front frame 14 has been opened. It can be stored separately in the computer 262.

  Further, in the process of S217 of the main process (see FIG. 12), the voltage (reset signal SG3b) output from the existing frame opening detection circuit 260 to the input / output port 205 is read, and a newly added frame opening detection circuit. The voltage (reset signal SG3b) output from 260 to the input / output port 205 may be read. Depending on the read result, in the process of S219 or S220, the on-inner frame release flag or the on-front frame release flag is turned on separately.

  Then, in the process of S208 of the main process (see FIG. 12), when the on-inner frame release flag is turned on, an “on-inner frame release command” is transmitted from the MPU 201 to the audio lamp control device 113 and turned on. When the middle front frame opening flag is turned on, the MPU 201 transmits an “on middle front frame opening command” to the sound lamp control device 113. When the voice lamp control device 113 receives each command transmitted from the MPU 201, the voice lamp control device 113 differs depending on whether it receives an on-inner inner frame release command or an on-in front frame release command. An aspect is notified. For example, a different warning sound is emitted from the audio output device 226 or the lighting mode of the lamp display device 227 is changed. Thereby, when the power of the pachinko machine 10 is turned on, the pachinko machine 10 can separately notify whether the inner frame 12 is opened or the front frame 14 is opened.

  In the present embodiment, the pulse signal output from the pachinko machine 10 is output to the hall computer 262 having a different installation location from the pachinko machine 10, but the present invention is not limited to this. A dedicated storage device having the function of the hall computer 262 may be provided for each pachinko machine 10, and the dedicated storage device may be provided on the back side of each pachinko machine 10 provided with the main control device 110 and the like. In this case, more preferably, a dedicated storage device such as the main control device 110, the payout control device 111, and the launch control device 112 is stored in the substrate box, and the box base and the box cover provided in the substrate box are stored. Are connected by a sealing unit (not shown) so that they cannot be opened (connection by caulking structure). Then, a seal seal (not shown) is pasted on the connecting portion between the box base and the box cover over the box cover and the box base.

  Next, a pachinko machine according to a second embodiment will be described with reference to FIGS. The pachinko machine of the second embodiment is obtained by changing the start-up process, timer interrupt process, and main process of the pachinko machine 10 of the first embodiment. Specifically, the pachinko machine of the second embodiment is provided with a power-on counter 203c (not shown) that starts timing when the MPU 201 is started up in the RAM 203, and the timing period by the power-on counter 203c is long. If there is information on the occurrence of power interruption, even though it is within a predetermined period (within this embodiment, within 5.0 seconds), the inner frame 12 or the front frame when the power of the pachinko machine is turned off. 14 is opened, and the frame open detection circuit 260 determines that the MPU 201 is temporarily started up, and turns on the off-frame open flag 203a.

  According to the pachinko machine of the second embodiment, whether the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off is determined according to the timing of the power-on counter 203c. To do. Therefore, when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off, power is supplied from the frame opening detection circuit 260 to the input / output port 205, and the frame opening detection circuit 260 is supplied. It is not necessary for the MPU 201 to detect whether or not the output to the input / output port 205 is high. Therefore, according to the pachinko machine of the second embodiment, when the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine is turned off, the power is supplied from the frame open detection circuit 260 to the input / output port 205. Compared with the pachinko machine 10 of the first embodiment (the power supply is supplied from the frame opening detection circuit 260 to the input / output port 205 and the frame opening detection circuit 260 outputs to the input / output port 205. As compared with the pachinko machine 10 of the first embodiment in which the MPU 201 detects whether or not is high), it is possible to suppress the consumption of the electric power stored in the capacitor CD1.

  The power-on counter 203c (not shown) is turned on by the pachinko machine 10, and a startup process (FIG. 21) is executed. A predetermined period (from FIG. In this embodiment, it is a counter that measures whether or not 5.0 seconds) has elapsed. The power-on counter 203c is set to “0 (zero)” in the start-up process, and starts counting up every time the timer interrupt process (see FIG. 22) is executed (every 2 milliseconds). ) Count up by one. Then, when this count-up exceeds “2500 (5.0 seconds)” and becomes “2501”, the count-up is terminated. Therefore, the power-on counter 203c can count whether 5.0 seconds have elapsed since the start-up process S119.

  Next, a startup process executed by the MPU 201 of the pachinko machine according to the second embodiment will be described with reference to FIG. FIG. 21 is a flowchart showing start-up processing executed by the MPU 201 of the pachinko machine according to the second embodiment. In addition, the same number is attached | subjected to the same part as the starting process of the pachinko machine 10 of 1st Embodiment mentioned above in FIG. 11, the description is abbreviate | omitted, and only a different part is demonstrated.

  In the pachinko machine startup process of the second embodiment, the processes of S110 to S112 of the startup process of the pachinko machine 10 of the first embodiment are deleted, and the processes of S118 and S119 are added. In the pachinko machine start-up process of the second embodiment, the power-on counter 203c is set to “0 (zero)” after the process of S109 or S117 (S118). The power-on counter 203c starts counting up (S119). Thereafter, the process proceeds to S113.

  Note that the processing of S118 to S119 is executed immediately after the completion of the processing of S109 or immediately after the completion of the processing of S117. That is, the processing of S118 to S119 is executed immediately after various settings of the MPU 201 are completed. Therefore, when the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine 10 is turned off, the opening can be immediately detected by the processing of S118 to S119.

  Next, with reference to FIG. 22, a timer interrupt process executed by the MPU 201 of the pachinko machine according to the second embodiment will be described. FIG. 22 is a flowchart showing a timer interrupt process executed by the MPU 201 of the pachinko machine according to the second embodiment. The timer interrupt process of the pachinko machine according to the second embodiment is executed by the MPU 201 of the main control device 110, for example, every 2 milliseconds, similarly to the timer interrupt process of the pachinko machine 10 according to the first embodiment. In addition, the same number is attached | subjected to the part same as the timer interruption process of the pachinko machine 10 of 1st Embodiment mentioned above in FIG. 15, The description is abbreviate | omitted, and only a different part is demonstrated.

  In the timer interrupt process of the pachinko machine of the second embodiment, the processes of S506 and S507 are added to the timer interrupt process of the pachinko machine 10 of the first embodiment. In the timer interrupt process of the pachinko machine of the second embodiment, after the process of S503, it is determined whether or not the count value of the power-on counter 203c is greater than “2500” (S506). Since the timer interrupt process is executed every 2 msec, if the count value of the power-on counter 203c is “2500”, it will be 5.0 (2500 (count value) × 2 msec), and the process of S119 This indicates that 5.0 seconds have elapsed since the power-on counter 203c started counting up.

  If the count value of the power-on counter 203c is equal to or less than “2500” (S506: No), 5.0 seconds have elapsed since the count-up of the power-on counter 203c is started (after the processing of S119 is started). Therefore, the count value of the power-on counter 203c is incremented by “1” (S507). On the other hand, if the count value of the power-on counter 203c is larger than “2500”, that is, if the count value of the power-on counter 203c is “2501” (S506: Yes), the power-on counter 203c starts counting up. Since 5.0 seconds have elapsed since the start of the process of S119, the process of S507 is skipped and the count-up of the power-on counter 203c is stopped.

  Note that if “Yes” is determined in the process of S506 and if the process of S507 is completed, the process proceeds to S504.

  Next, with reference to FIG. 23, the main process performed by MPU201 of the pachinko machine of 2nd Embodiment is demonstrated. FIG. 23 is a flowchart illustrating main processing executed by the MPU 201 of the pachinko machine according to the second embodiment. In addition, the same number is attached | subjected to the part same as the main process of the pachinko machine 10 of 1st Embodiment mentioned above in FIG. 12, the description is abbreviate | omitted, and only a different part is demonstrated.

  In the main process of the pachinko machine of the second embodiment, the processes of S225 and S226 are added to the main process of the pachinko machine 10 of the first embodiment. In the main process of the pachinko machine of the second embodiment, after the process of S222, the count value of the power-on counter 203c is “2500” or less (S225), that is, the power-on counter 203c is incremented by the process of S119. It is determined whether or not 5.0 seconds have elapsed since the start. If the count value of the power-on counter 203c is “2500” or less (S225: Yes), the off-in-frame release flag 203a is turned on (S226), and the process proceeds to S223. When the count value of the power-on counter 203c is equal to or less than “2500”, the following two patterns are conceivable, but the off middle frame release flag 203a is turned on regardless of which pattern occurs.

  The first pattern is a case where the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily activated by the frame open detection circuit 260 when the power of the pachinko machine is turned off. In this case, the fall of the power failure signal SG1b is input to the MPU 201 together with the drive voltage Vb and the reset signal SG3b from the frame opening detection circuit 260, and the NMI interrupt process (see FIG. 17) is executed. After the raising process (FIG. 21), it is determined that there is power-off occurrence information in the process of S213 (S213: Yes), and the processes of S221 to S225 are executed. Here, when the MPU 201 is temporarily started up by the frame open detection circuit 260, the power failure signal SG1b output from the frame open detection circuit 260 is output from the start of the power failure signal SG1b (MPU 201 is started up). ) And will fall in about 4.4 seconds. Therefore, if the count value of the power-on counter 203c is set to “2500” (set to 5.0 seconds), the processing is performed until the count value of the power-on counter 203c reaches “2500”. The process can proceed to S225. Therefore, when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off and the MPU 201 is temporarily activated by the frame open detection circuit 260, the count value of the power-on counter 203c Is “2500” or less (S225: Yes), it is determined that the inner frame 12 or the front frame 14 has been released when the power of the pachinko machine is turned off, and the off-in-frame release flag 203a is turned on. (S226).

  The second pattern is a case where the power of the pachinko machine is turned on and the power of the pachinko machine is turned off within about 4.4 seconds from the time when the power is turned on. In this case, after the power of the pachinko machine is turned off (before the determination in S213), the power failure signal SG1a output from the power failure monitoring circuit 252 falls and the NMI interrupt process (see FIG. 17) is executed. In the process of S213, it is determined that there is power-off occurrence information (S213: Yes), and the processes of S221 to S225 are executed. Here, since the count value of the power-on counter 203c is set to “2500” (because it is set to 5.0 seconds), the power of the pachinko machine is turned on, and about 4.4 from the time of power-on. Even when the power of the pachinko machine is turned off within 2 seconds, it is determined that the count value of the power-on counter 203c is “2500” or less (S225: Yes), and the off-in-frame release flag 203a is turned on (S226).

  In the second pattern, the pachinko machine needs to be turned on and off, so that it cannot be executed by an unauthorized person and is limited to being executed by a store clerk. Therefore, in the case of the second pattern, the store clerk can recognize that the off-in-frame release flag 203a is turned on by his / her own action, so the off-in-frame release flag 203a that has been turned on is turned off again. can do. Therefore, even in the case of the second pattern, there is no problem even if the off-in-frame release flag 203a is turned on in the process of S226.

  If the count value of the power-on counter 203c is not “2500” or less in the process of S225 (S225: No), at least 5.0 seconds have elapsed since the count-up of the power-on counter 203c was started in the process of S119. Since it does not correspond to any of the two patterns described above, the process of S226 is skipped and the process proceeds to S223. Since the frequency of occurrence of the two patterns described above is low, 5.0 seconds have elapsed after the count-up of the power-on counter 203c is started in the process of S119, that is, the count value of the power-on counter 203c is “2500. It is normal to determine that it is not less than (S225: No).

  Thus, according to the pachinko machine of the second embodiment, whether or not the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off depends on the timing of the power-on counter 203c. Accordingly, the determination is made (depending on whether or not 5.0 seconds have elapsed since the start of counting up of the power-on counter 203c in the process of S119). Therefore, when the power of the pachinko machine is turned off and the inner frame 12 or the front frame 14 is opened, power is supplied from the frame open detection circuit 260 to the input / output port 205, and the frame open detection circuit 260 supplies the input / output port. The MPU 201 does not need to detect whether the output to 205 is high. Therefore, according to the pachinko machine of the second embodiment, when the power of the pachinko machine is turned off and the inner frame 12 or the front frame 14 is opened, power is supplied from the frame open detection circuit 260 to the input / output port 205. Compared to the pachinko machine 10 of the first embodiment (whether power is supplied from the frame opening detection circuit 260 to the input / output port 205 and the output from the frame opening detection circuit 260 to the input / output port 205 is high). As compared with the pachinko machine 10 of the first embodiment in which the MPU 201 detects whether or not), the consumption of the electric power stored in the capacitor CD1 can be suppressed.

  Next, a pachinko machine according to a third embodiment will be described with reference to FIGS. The pachinko machine of the third embodiment is obtained by changing the start-up process and the main process of the pachinko machine 10 of the first embodiment. Specifically, the pachinko machine according to the third embodiment outputs a pulse signal having a pulse width of about 1 msec to the hall computer 262 every time the start-up process is executed.

  According to the pachinko machine of the third embodiment, every time the start-up process is executed, a pulse signal having a pulse width of about 1 msec is output to the hall computer 262, so that the power of the pachinko machine is turned off. Sometimes, the fact that the inner frame 12 or the front frame 14 is opened and the MPU 201 is temporarily activated by the frame opening detection circuit 260 can be stored in the hall computer 262 that continues to operate for 24 hours. As described above, when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off, a pulse signal of about 1 msec is output to the hall computer 262 to open the hall. Since it is stored in the computer 262, when the power of the pachinko machine is turned off, the off-in-frame open flag 203a for storing that the inner frame 12 or the front frame 14 is opened can be made unnecessary. Therefore, the memory capacity of the RAM 203 can be reduced. Furthermore, since the determination regarding the off-in-frame release flag 203a (the processes of S110 to S112 in FIG. 11 and S204 to S206 in FIG. 12) can be made unnecessary, the process for determining the off-in-frame release flag 203a. Program capacity can be reduced.

  First, with reference to FIG. 24, the start-up process executed by the MPU 201 of the pachinko machine according to the third embodiment will be described. FIG. 24 is a flowchart showing start-up processing executed by the MPU 201 of the pachinko machine according to the third embodiment. In addition, the same number is attached | subjected to the same part as the starting process of the pachinko machine 10 of 1st Embodiment mentioned above in FIG. 11, the description is abbreviate | omitted, and only a different part is demonstrated.

  In the pachinko machine startup process of the third embodiment, the processes of S110 to S112 of the startup process of the pachinko machine 10 of the first embodiment are deleted, and the process of S120 is added. In the pachinko machine start-up process of the third embodiment, the processing content of S116 of the start-up process of the pachinko machine 10 of the first embodiment is changed to be the process of S121.

  In the start-up process of the pachinko machine according to the third embodiment, after the process of S101, a pulse signal having a pulse width of about 1 msec is output to the hall computer 262 (S120). Thereafter, the process proceeds to S102. In the process of S120, since a pulse signal having a pulse width of about 1 msec is output, at this time, at least about 1 msec is required to complete the process of S120. When shortening the time until the completion of the processing of S120 (about 1 msec), output of a pulse signal to the hall computer 262 is started in the processing of S120, and then the processing proceeds to S102 and the weight of S102 The pulse signal being output may be stopped within about 1 ms after the start of the processing of S120. Since the wait process of S102 waits for about 1.0 second, there is no problem even if the process of stopping the pulse signal started to be output in the wait process is executed.

  In the pachinko machine start-up process of the third embodiment, after the process of S115, the used area of the RAM 203 is cleared to 0 (S121), and then the process proceeds to S117. In the pachinko machine of the third embodiment, the off-in-frame release flag 203a is unnecessary, and therefore the process of turning off the off-in-frame release flag 203a performed in the start-up process of the pachinko machine 10 of the first embodiment (S116). (Execution in the process) becomes unnecessary. Therefore, in the process of S121, only the process of clearing the used area of the RAM 203 to 0 is executed.

  Next, with reference to FIG. 25, the main process performed by MPU201 of the pachinko machine of 3rd Embodiment is demonstrated. FIG. 25 is a flowchart illustrating main processing executed by the MPU 201 of the pachinko machine according to the third embodiment. In addition, the same number is attached | subjected to the part same as the main process of the pachinko machine 10 of 1st Embodiment mentioned above in FIG. 12, the description is abbreviate | omitted, and only a different part is demonstrated.

  In the main process of the pachinko machine of the third embodiment, the processes of S204 to S206 of the main process of the pachinko machine 10 of the first embodiment are deleted. That is, in the main process of the pachinko machine of the third embodiment, after the process of S203, it is determined whether or not the on-in-frame release flag 203b is on (S207). If the on-frame open flag 203b is on (S207: Yes), the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine is on, so the on-frame open to the sound lamp controller 113 is released. A command is transmitted (S208), and the process proceeds to S210. On the other hand, if the on-in-frame release flag 203b is off (S207: No), the inner frame 12 or the front frame 14 is not opened (because the inner frame 12 and the front frame 14 are closed), so the sound lamp An on-frame closing command is transmitted to the control device 113 (S209), and the process proceeds to S210.

  Here, there is no determination (the processing of S204 to S206) about the off-in-frame release flag 203a provided in the pachinko machines of the first and second embodiments for the following reason. That is, the pachinko machine according to the third embodiment has a pulse width of about 1 ms when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off. By outputting the signal, it can be stored in the hall computer 262 that has been operating for 24 hours, that the inner frame 12 or the front frame 14 has been opened. Thereby, in the pachinko machine of the third embodiment, when the power of the pachinko machine is turned off, the off-in-frame release flag 203a for storing that the inner frame 12 or the front frame 14 is released is unnecessary. Become. For this reason, in the pachinko machine of the third embodiment, there is no determination regarding the off-in-frame release flag 203a.

  As described above, according to the pachinko machine of the third embodiment, the off-in-frame release flag 203a is unnecessary, so that the memory capacity of the RAM 203 can be reduced. Further, according to the pachinko machine of the third embodiment, the determination about the off-in-frame release flag 203a (the processing of S110 to S112 in FIG. 11 and S204 to S206 in FIG. 12) is unnecessary. It is possible to reduce the program capacity of the process for performing the determination on the flag 203a.

  Also, according to the pachinko machine of the third embodiment, every time the start-up process is executed, a pulse signal having a pulse width of about 1 msec is output to the hall computer 262, so that the power of the pachinko machine is turned off. When the inner frame 12 or the front frame 14 is open, the fact that the MPU 201 is temporarily started up by the frame open detection circuit 260 can be stored in the hall computer 262 that continues to operate for 24 hours. Therefore, the pachinko machine in which the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off can be identified by the pulse signal stored in the hall computer 262. Further, the hall computer 262 outputs a pulse signal from the pachinko machine, and stores the output time of the output pulse signal, so that the opening time of the inner frame 12 of the specified pachinko machine or the front frame 14 The opening time can be detected.

  Next, a pachinko machine according to a fourth embodiment will be described with reference to FIGS. The pachinko machine of the fourth embodiment is obtained by changing the start-up process and the main process of the pachinko machine 10 of the first embodiment. Specifically, the pachinko machine of the fourth embodiment determines whether or not the off-in-frame release flag 203a is on in the start-up process, and if the off-in-frame release flag 203a is on, the sound lamp control device An off-frame opening command is transmitted to 113, and then a pulse signal having a pulse width of about 1 msec is output to the hall computer 262.

  According to the pachinko machine of the fourth embodiment, if the off-in-frame opening flag 203a is on, the off-in-frame opening command is transmitted to the audio lamp control device 113 within the start-up process, and then the hall computer Since a pulse signal having a pulse width of about 1 ms is output to 262, when the power of the pachinko machine is turned off, the inner frame 12 or the front frame 14 is opened, and the MPU 201 is temporarily opened by the frame open detection circuit 260. It can be recognized immediately when the power of the pachinko machine is turned on next time.

  First, with reference to FIG. 26, the start-up process performed by MPU201 of the pachinko machine of 4th Embodiment is demonstrated. FIG. 26 is a flowchart showing start-up processing executed by the MPU 201 of the pachinko machine according to the fourth embodiment. In addition, the same number is attached | subjected to the same part as the starting process of the pachinko machine 10 of 1st Embodiment mentioned above in FIG. 11, the description is abbreviate | omitted, and only a different part is demonstrated.

  In the start-up process of the pachinko machine of the fourth embodiment, the processes of S204 to S206, which are executed in the main process of the pachinko machine 10 of the first embodiment, are the processes of S227 to S229, and are added before the process of S113. doing.

  In the pachinko machine start-up process of the fourth embodiment, it is determined whether or not the off-in-frame opening flag 203a is on after the determination in S111 is “No” or after the process in S112 (S227). . If the off-in-frame release flag 203a is on (S227: Yes), an off-in-frame release command is transmitted to the audio lamp control device 113 (S228). When the voice lamp control device 113 receives the off-in-frame release command, it controls the voice output device 226 and the lamp display device 227 to start notifying that the inner frame 12 or the front frame 14 has been opened. Further, a pulse signal having a pulse width of about 1 ms is output to the hall computer 262 (S229). In addition, when the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine is turned off and the MPU 201 is temporarily started up, the power supply to the audio lamp control device 113 is not performed. Even when the off-frame opening command is transmitted to the sound lamp control device 113, the sound output device 226 and the lamp display device 227 do not perform notification. Therefore, even if the inner frame 12 or the front frame 14 is opened by a fraudster while the power of the pachinko machine is turned off, the pachinko machine uses the off-border frame opening flag 203a without being recognized by the fraudster. The opening of the inner frame 12 or the front frame 14 can be stored (without notification by the audio output device 226 and the lamp display device 227, the inner frame 12 or the front frame 14 can be stored using the off-in-frame opening flag 203a. Only open memory).

  On the other hand, if the off-in-frame release flag 203a is off (S227: No), the process of S228 and S229 is skipped and the process proceeds to S113.

  Next, with reference to FIG. 27, the main process performed by MPU201 of the pachinko machine of 4th Embodiment is demonstrated. FIG. 27 is a flowchart illustrating main processing executed by the MPU 201 of the pachinko machine according to the fourth embodiment. In addition, the same number is attached | subjected to the part same as the main process of the pachinko machine 10 of 1st Embodiment mentioned above in FIG. 12, the description is abbreviate | omitted, and only a different part is demonstrated.

  In the main process of the pachinko machine of the fourth embodiment, the processes of S204 to S206 of the main process of the pachinko machine 10 of the first embodiment are deleted. That is, in the main process of the pachinko machine of the fourth embodiment, after the process of S203, it is determined whether or not the on-in-frame release flag 203b is on (S207). If the on-frame open flag 203b is on (S207: Yes), the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine is on, so the on-frame open to the sound lamp controller 113 is released. A command is transmitted (S208), and the process proceeds to S210. On the other hand, if the on-in-frame release flag 203b is off (S207: No), the inner frame 12 or the front frame 14 is not opened (because the inner frame 12 and the front frame 14 are closed), so the sound lamp An on-frame closing command is transmitted to the control device 113 (S209), and the process proceeds to S210.

  As described above, according to the pachinko machine of the fourth embodiment, if the off-in-frame release flag 203a is on, the off-in-frame release command is transmitted to the audio lamp control device 113 within the startup process, and thereafter Since the pulse signal having a pulse width of about 1 ms is output to the hall computer 262, the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off, and the MPU 201 is opened by the frame open detection circuit 260. It can be recognized immediately when the power of the pachinko machine is turned on next time.

  Further, the process of S228 for transmitting the off-frame open command to the sound lamp control device 113 and the process of S229 for outputting a pulse signal having a pulse width of 1 msec to the hall computer 262 are executed in the start-up process of the pachinko machine. Therefore, the processes of S228 and S229 can be made non-executed in the main process in which the update of the variation type counters CS1, CS2, CS3, etc. is repeatedly executed. Therefore, it is possible to prevent the OFF middle frame opening command and the pulse signal from being repeatedly output.

  It should be noted that a change made by the pachinko machine of the fourth embodiment to delete the processes of S204 to S206 in the main process, and to add the deleted processes of S204 to S206 before S113 in the start-up process, You may apply to the pachinko machine of 2 embodiment. Specifically, in the pachinko machine of the second embodiment, the processes of S204 to S206 are deleted from the main process (see FIG. 23) of the pachinko machine of the second embodiment. Then, the deleted processes of S204 to S206 may be added between S119 and S113 of the pachinko machine start-up process (see FIG. 21) of the second embodiment.

  The present invention has been described above based on one embodiment. However, the present invention is not limited to the above embodiment, and various modifications and improvements can be easily made without departing from the spirit of the present invention. Can be inferred.

  Needless to say, the pachinko machines having the functions of the respective embodiments can be realized by combining the pachinko machines described in the first to fourth embodiments.

  In the first embodiment to the fourth embodiment, when the off-in-frame opening flag 203a is on, the off-in-frame opening command is transmitted to the sound lamp control device 113, and the pulse width is 1 ms for the hall computer 262. Although a signal is output, the present invention is not limited to this. When the off-in-frame opening flag 203a is on, the main control device 110 does not transmit a command to the audio lamp control device 113, contrary to the pachinko machines of the first to fourth embodiments, and the hall When the off-in-frame opening flag 203a is off while the pulse signal is not output to the computer 262, the main controller 110 transmits a command to the audio lamp controller 113 and sends the pulse signal to the hall computer 262. You may comprise so that it may output. When the main control device 110 is configured in this way, the sound lamp control device 113 does not receive a command from the main control device 110 within a predetermined time from the power-on of the pachinko machine. What is necessary is just to comprise so that it may determine with the inner frame 12 or the front frame 14 open | released during off. Similarly, when the hall computer 262 does not receive a pulse signal from the main control device 110 within a predetermined time from the power-on of the pachinko machine, the hall frame 12 or the front frame 14 is opened during the power-off of the pachinko machine. What is necessary is just to comprise so that it may determine. With the above configuration, a pachinko machine that does not transmit a command to the sound lamp control device 113 and does not output a pulse signal to the hall computer 262 can be realized when the off-in-frame opening flag 203a is on.

  In the first to fourth embodiments, a pulse signal having a pulse width of about 1 msec is output from the pachinko machine to the hall computer 262, and the opening of the inner frame 12 or the front frame 14 is stored in the hall computer 262. However, it is not limited to this. For example, a pachinko machine is provided with an EEPROM (Electronically Erasable and Programmable Read Only Memory) and a backup RAM. The EEPROM or backup RAM and the input / output port 205 are connected via a bus line. With this configuration, the opening of the inner frame 12 or the front frame 14 can be stored in the EEPROM or the backup RAM. Then, when the power of the pachinko machine is turned on, the storage of the EEPROM and the backup RAM is confirmed by the MPU 201. Thereby, the opening of the inner frame 12 or the front frame 14 can be detected using a pachinko machine without using the hall computer 262. That is, the role of the hall computer 262 can be assigned to the EEPROM or the backup RAM (the role of the “specific device” described in the claims can be assigned to the EEPROM or the backup RAM). Note that the RAM 203 may be used as the backup RAM.

  Further, in the first to fourth embodiments, the MPU 201 is the target to be temporarily started by outputting the drive voltage, the reset signal SG3, and the power failure signal SG1 from the frame opening detection circuit 260, but is not limited to this. is not. For example, when the CPU (MPU) and RAM different from the MPU 201 are provided in the main controller 110, and the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off, The CPU (MPU) and the RAM may be temporarily started up by the frame opening detection circuit 260. Specifically, first, an off-frame open flag 203a is provided in a separately provided RAM. Then, a CPU (MPU) provided separately from the power output terminal, reset signal output terminal, and power interruption signal output terminal of the frame opening detection circuit 260 is connected, and a RAM provided separately to the power output terminal of the frame opening detection circuit 260. Connect. Further, a separately provided CPU (MPU) and a separately provided RAM are connected. As a result, when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off, the CPU (MPU) and RAM separately provided by the frame open detection circuit 260 are temporarily raised. The off-in-frame release flag 203a provided in another RAM is turned on. Therefore, when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off, the opening can be stored in a separately provided RAM. Note that a single-chip integrated circuit in which a CPU (MPU) provided separately from the frame opening detection circuit 260 and a RAM provided separately is integrated may be used. In this case, since the signals (drive voltage Vb, power failure signal SG1b, and reset signal SG3b) output from the frame opening detection circuit 260 are directly input to the CPU (MPU), the first embodiment to the third embodiment. The multiplexers MP1 to MP3 used in the pachinko machine are not necessary. Further, the RAM provided separately from the CPU (MPU) provided separately may be provided not in the main control device 110 but in the power supply device 115 outside the main control device 110, for example.

  In the first to fourth embodiments, the voltage output from the OUT terminal of the timer IC1 provided in the frame opening detection circuit 260 is the inner frame 12 or the front frame depending on the time constant of the resistor R1 and the capacitor CD2. Although it was set to be zero volts about 4.4 seconds after 14 was opened, it is not limited to this. For example, when the resistance value of the resistor R1 is set to 200 kΩ, the capacitance value of the capacitor CD2 is set to 10 μF, and the time constant is set to about 2 seconds, the voltage output from the OUT terminal of the timer IC1 is changed to the inner frame 12 or the front surface. It can be zero volts about 2 seconds after the frame 14 is opened. Therefore, the startup process (see FIG. 11) that is executed when the MPU 201 is temporarily started up by the frame opening detection circuit 260 and the main processes S201 to S213: Yes to S224 (see FIG. 12). ) Can be executed in a relatively short time (specifically, the above processing is performed for about 2 seconds when the inner frame 12 or the front frame 14 is opened and the voltage is output from the OUT terminal of the timer IC1). When the reset signal SG3 output from the reset signal output terminal of the frame opening detection circuit 260 can be executed in a total of 7 seconds, ie, about 5 seconds until the reset signal SG3 drops to about 4.3 volts), As described above, by setting the time constant to about 2 seconds, the output period of the voltage output from the OUT terminal of the timer IC 1 after the inner frame 12 or the front frame 14 is opened can be suppressed to about 2 seconds. Kill. Therefore, when the inner frame 12 or the front frame 14 is opened when the power of the pachinko machine is turned off, it is possible to suppress the consumption of the electric power stored in the capacitor CD1.

  In the first to fourth embodiments, when the inner frame 12 or the front frame 14 is opened, the notification is executed using the audio lamp control device 113. However, the present invention is not limited to this. . When the inner frame 12 or the front frame 14 is opened, notification may be executed using the display control device 114 in addition to the notification using the sound lamp control device 113. In this case, when the voice lamp control device 113 receives the OFF middle frame release command or the ON middle frame release command, the voice lamp control device 113 receives the OFF middle frame release command or the ON middle frame release command received to the display control device 114. Send. When the display control device 114 receives the off-in-frame release command or the on-in-frame release command, the display control device 114 starts displaying “Please check” or “The door is open” on the third symbol display device 81. What is necessary is just to comprise. With this configuration, in addition to the notification of the sound lamp control device 113, the display control device 113 also provides notification, so that it is easier to understand and can notify an unspecified number of people that the inner frame 12 or the front frame 14 has been opened. it can.

  In the first to fourth embodiments, the signals (driving voltage Va, power failure signal SG1a and reset signal SG3a) output from the power supply device 115 and the signals (driving voltage Vb, The switching between the power failure signal SG1b and the reset signal SG3b) is performed using the multiplexers MP1 to MP3, but is not limited thereto. Switching between signals (drive voltage Va, power failure signal SG1a and reset signal SG3a) output from the power supply device 115 and signals (drive voltage Vb, power failure signal SG1b and reset signal SG3b) output from the frame opening detection circuit 260, Instead of the multiplexers MP1 to MP3, three OR circuits that are OR circuits may be used.

  In the first to fourth embodiments, the process in S218 for determining whether or not the inner frame 12 or the front frame 14 is opened while the power of the pachinko machine is turned on, and the process in S218. Depending on the determination, the process of S219 for turning on the on-in-frame release flag 203b and the process of S220 for turning off the on-in-frame release flag 203b were executed in the remaining time of the main process, but this is limited. It is not a thing. You may perform the process of S218-S220 within the regular process of a 4 msec period of a main process. Moreover, you may perform this process of S218-S220 within the timer interruption process performed every 2 milliseconds.

  In the first embodiment, the second embodiment, and the fourth embodiment, when the off-in-frame opening flag 203a is on, the sound output device 226 and the lamp display device 227 are used for notification and the hall Although a 1-msec pulse signal is output to the computer 262, the present invention is not limited to this. In other words, when the off-in-frame opening flag 203a is on, the hall computer 262 is not output a 1-msec pulse signal, and only the notification is performed using the audio output device 226 and the lamp display device 227. May be. Conversely, when the off-in-frame opening flag 203a is on, notification is not performed using the audio output device 226 and the lamp display device 227, and only the pulse signal is output to the hall computer 262. It may be configured.

  Further, for example, in each of the above embodiments, each command is transmitted from the main control device 110 to the sound lamp control device 113, and the sound lamp control device 113 gives a display instruction to the display control device 114. However, the command may be directly transmitted from the main control device 110 to the display control device 114. Further, an audio lamp control device may be connected to the display control device, and a command instructing the output of each sound and the lighting of the lamp may be transmitted from the display control device to the audio lamp control device. Furthermore, the sound lamp control device and the display control device may be configured as one control device.

  Moreover, in the said embodiment, although it was comprised so that the winning to the 1st entrance 64 and the passage of the 2nd entrance 67 might be held up to 4 times, respectively, the maximum number of times of holding was 4 times. It is not limited and may be set to 3 times or less, or 5 times or more (for example, 8 times). In addition, the number of times the variable display is held based on the winning at the first entrance 64 is different for the part of the third symbol display device 81 by a number or by dividing the number of four divided areas by the number of times of the hold. It may be displayed in a mode (for example, color or lighting pattern), and a light emitting member such as a lamp is provided separately from the first symbol display device 37, and the number of holding times is notified by the light emitting member. You may do it.

  Further, as shown in the above embodiment, the variable display, which is a kind of dynamic display, is not limited to the one that scrolls the symbol as identification information in the vertical direction on the display screen of the third symbol display device 81, It may be performed by moving and displaying symbols along a predetermined route such as a horizontal direction or an L shape. In addition, the dynamic display of the identification information is not limited to the display of variation of the symbol. The effect display etc. which are displayed are also included. In this case, one or more characters are used as the third symbol.

  You may implement this invention in the pachinko machine etc. of a type different from the said embodiment. For example, the present invention may be applied to a so-called second type pachinko gaming machine having a winning device having a special area such as a V zone. Further, in addition to the pachinko machine, the game machine may be implemented as another game machine such as an alepacchi or a sparrow ball.

  You may implement this invention in the pachinko machine etc. of a type different from the said embodiment. For example, once a big hit, a pachinko machine that raises the expected value of the big hit until a big hit state occurs (for example, two times or three times) including that (for example, a two-time right item, a three-time right item) May also be implemented. Further, after the jackpot symbol is displayed, it may be implemented as a pachinko machine that generates a special game that gives a player a predetermined game value on the condition that a ball is won in a predetermined area. Further, the present invention may be implemented in a pachinko machine that has a special area such as a V-zone and has a special gaming state as a necessary condition for winning a ball in the special area. Further, in addition to the pachinko machine, the game machine may be implemented as various game machines such as an alepatchi, a sparrow ball, a slot machine, a game machine in which a so-called pachinko machine and a slot machine are integrated.

  In the slot machine, for example, a symbol is changed by operating a control lever in a state where a symbol effective line is determined by inserting coins, and a symbol is stopped and confirmed by operating a stop button. Is. Accordingly, the basic concept of the slot machine is that it is provided with a display device for confirming and displaying the identification information after variably displaying the identification information string composed of a plurality of identification information, and resulting from the operation of the starting operation means (for example, the operation lever) The variation display of the identification information is started, and the variation display of the identification information is stopped and fixedly displayed due to the operation of the operation means for stop (for example, the stop button) or when a predetermined time elapses. It is a slot machine that generates a special game that gives a player a predetermined game value on the condition that the combination of identification information at the time is a specific condition. In this case, the game medium is typically a coin, medal, etc. Take as an example.

  In addition, as a specific example of a gaming machine in which a pachinko machine and a slot machine are fused, a display device is provided that displays a symbol after a symbol string composed of a plurality of symbols is variably displayed, and has a handle for launching a ball. What is not. In this case, after throwing a predetermined amount of spheres based on a predetermined operation (button operation), for example, the change of the symbol is started due to the operation of the operation lever, for example, due to the operation of the stop button, or With the passage of time, the variation of the symbol is stopped, and a special game that gives a predetermined game value to the player is generated on the condition that the determined symbol at the time of stoppage is a so-called jackpot symbol. In this case, a large amount of balls are paid out to the lower tray.

  Hereinafter, in addition to the gaming machine of the present invention, concepts of various inventions included in the various embodiments described above are shown. In a gaming machine comprising a main body, a door body that opens and closes the front surface of the main body, and an arithmetic means that performs arithmetic processing related to game control, door opening detection means for detecting the opening of the door body with respect to the main body, and Storage means for storing the opening detection of the door body by the door opening detection means, and when the opening of the door body is detected by the door opening detection means, the opening detection is stored based on the calculation processing of the calculation means. And when the door opening detection unit detects that the door is open while the gaming machine is powered off, the storage unit, the storage execution unit, and the calculation unit are activated for a predetermined period. The game machine A1 further comprises a start-up unit that makes it possible to execute storage of the release detection by the storage execution unit.

  According to the gaming machine A1, even when the power of the gaming machine is turned off and the computing means is stopped, if the door opening detection is detected by the door opening detecting means, the rising means is the storage means, The storage execution means and the calculation means are activated for a predetermined period of time, and the storage execution means can perform the detection of door opening detection. Thus, for example, even if the door body is opened due to an unauthorized act by someone after the store is closed with all the gaming machines turned off, the storage execution means stores the opening detection of the door body in the storage means. Can do. Therefore, it is possible to grasp the opening of the door even when the power of the gaming machine is turned off.

  In general, the calculation means is provided in a space formed by the door body and the main body. Furthermore, the inside of the space formed by the door body and the main body indicates the back surface or the back surface side (including the back surface side of the main body) of the door body which cannot be touched by the hand when the door body is closed.

  The gaming machine A1 is provided with an off-time operation means that is filled when the gaming machine is turned on and that enables the storage means, storage execution means, calculation means, and start-up means to operate with the charged power. A gaming machine A2.

  According to the gaming machine A2, it is provided with an off-operation means that is filled when the gaming machine is powered on, and the storage means, the storage execution means, the calculation means, and the startup means are filled in the off-operation means. Operates with power. Therefore, the storage means, the storage execution means, the calculation means, and the start-up means can be operated even after the gaming machine is turned off.

  In the gaming machine A1 or A2, the start-up means is configured to detect the storage means, the storage execution means, and the computing means when the door opening detection means detects that the door body is open while the gaming machine is powered off. An operation period determining means for setting the operation period as the first operation period, and when the first operation period determined by the operation period determining means is ended, the operation periods of the storage means, the storage execution means and the calculation means are set to the second operation period. An extension means for extending to an operation period, and the sum of a second operation period extended by the extension means and a first operation period determined by the operation period determination means is the predetermined period, The extension means is configured to be able to operate the storage means, the storage execution means, and the calculation means with less power than the power consumed by the operation period determination means. .

  According to the gaming machine A3, when the first operation period determined by the operation period determining means ends, that is, when the first operation period elapses, the extension means stores the storage means, the storage execution means, and the calculation. The operation period of the means is extended to the second operation period. Here, the sum of the first operation period determined by the operation period determination unit and the second operation period extended by the extension unit is defined as a predetermined period during which the start-up unit starts up the storage unit, the storage execution unit, and the calculation unit. Yes. Therefore, of the predetermined period, the period during which the power charged in the off-operation means is consumed by the operation period determination means is kept in the first operation period, and thereafter the extension means that consumes less power than the operation period determination means. The storage means, the storage execution means, and the calculation means can be operated. Accordingly, it is possible to suppress the consumption of the electric power charged in the off-operation means, increase the operable number of times of the storage means, the storage execution means, the calculation means, and the rising means, and increase the number of detectable opening of the door body.

  In the gaming machine A3, the operation period determining means, when the door opening detection means detects the opening of the door body in a period shorter than the first operation period, the storage means, the storage execution means, and the calculation means The first operation period, which is an operation period of the first operation period, is set to the short operation period, and the extension unit is configured to store the storage unit, the storage execution unit, and the calculation unit after the short operation period determined by the operation period determination unit The second operation period is extended to the second operation period, and the second operation period extended by the extension means is set to a period in which the storage execution means can perform the storage of the open detection. A gaming machine A4.

  According to the gaming machine A4, when the door opening detection means detects the opening of the door body in a period shorter than the first operation period, the operation period determination means operates the storage means, the storage execution means, and the calculation means. The period is the short operation period. Then, after the end of the short operation period determined by the operation period determination unit, the extension unit extends the operation period of the storage unit, the storage execution unit, and the calculation unit to the second operation period. The second operation period is set to a period during which the storage execution means can store the door opening detection. Therefore, even if the door is opened within a short period, the detection of opening of the door can be reliably stored in the storage by the storage execution unit. In addition, when the door is opened within a short period, the period during which the power charged in the off-operation means is consumed by the operation period determination means can be kept short. Therefore, it is possible to suppress the consumption of the electric power charged in the off-operation means, increase the operable number of times of the storage means, the storage execution means, the calculation means, and the rising means, and increase the number of detectable opening of the door body. .

  In the gaming machine A3 or A4, the extension means operates when the operation period of the storage means, the storage execution means, and the calculation means is within the first operation period determined by the operation period determination means. When the first operation period determined by the operation period determination unit is completed while being charged by the power supplied by the unit, the storage unit, the storage execution unit, and the calculation are performed by using the charged power. The gaming machine A5 is characterized in that power is supplied to the means to extend the operation period to the second operation period.

  According to the gaming machine A5, when the operation period of the storage means, the storage execution means, and the calculation means is within the first operation period determined by the operation period determination means, the extension means is supplied by the off-time operation means. Filled with electric power. On the other hand, when the first operation period determined by the operation period determining means ends, the extension means supplies power to the storage means, the storage execution means, and the calculation means by using the charged power. Due to the power supply of the extension means, the operation period of the storage means, the storage execution means and the calculation means is extended to the second operation period. In this way, by reliably filling the extension means from the off-operation means, the extension means can reliably extend the operation period of the storage means, the storage execution means, and the calculation means to the second operation period. it can.

  In any one of the gaming machines A3 to A5, the arithmetic means inputs a driving voltage input means for inputting a driving voltage that enables the arithmetic means to start up and an operation signal that makes the arithmetic processing executable. Operating signal input means, and when the door opening detection means detects the opening of the door body while the gaming machine is powered off, the rising means is connected to the drive voltage input means. A drive voltage supply means for supplying a voltage, and an operation signal for outputting the operation signal to the operation signal input means when the opening of the door is detected by the door opening detection means while the gaming machine is powered off. Output means, and during the second operation period extended by the extension means, the operation signal output by the operation signal output means is stopped and then supplied by the drive voltage supply means. Gaming machine A6, characterized in that those stopping the driving voltage that.

  According to the gaming machine A6, when the opening of the door is detected by the door opening detecting means while the gaming machine is powered off, an operation signal is output from the operation signal output means of the start-up means to the operation signal input means of the arithmetic means. At the same time, the drive voltage is supplied from the drive voltage supply means of the rising means to the drive voltage input means of the calculation means. The rising means first stops the operation signal output by the operation signal output means during the second operation period extended by the extension means, and then drives the drive voltage supplied by the drive voltage supply means. To stop. Therefore, the calculation means is first set in a state where the calculation process cannot be performed, and then is lowered. Therefore, even if the door opening detection means detects the opening of the gaming machine while the gaming machine is turned off and the rising means starts the calculation means for a predetermined period, the calculation means is lowered during the second operation period. Can do.

  In the gaming machine A6, the calculation means is configured to be able to start up when the drive voltage input to the drive voltage input means is equal to or higher than a first value, and the operation signal output means is connected to the extension means. When connected and the voltage supplied by the extension means is greater than or equal to the second value exceeding the first value, the supplied voltage is output as the operation signal to the operation signal input means, When the voltage supplied by the extension means becomes less than the second value exceeding the first value, the operation signal output to the operation signal input means is stopped, and the drive voltage supply means is It is connected to the extension means and outputs the supplied voltage as the drive voltage to the drive voltage input means regardless of the voltage supplied by the extension means. Tricks machine A7.

  According to the gaming machine A7, the operation signal output means and the drive voltage supply means are both connected to the extension means. When the voltage supplied by the extension means is equal to or higher than the second value exceeding the first value, the operation signal output means of the start-up means uses the supplied voltage as the operation signal as an operation signal. Output to. On the other hand, the operation signal output means of the start-up means stops the operation signal output to the operation signal output means of the calculation means when the voltage supplied by the extension means is less than the second value. Unlike the operation of the operation signal output means, the drive voltage supply means outputs the supplied voltage as the drive voltage to the drive voltage input means of the calculation means regardless of the voltage supplied by the extension means. That is, even when the voltage supplied by the extension means becomes less than the second value, the drive voltage supply means continues to output the supplied voltage to the drive voltage input means of the calculation means as the drive voltage. Here, the calculation means is configured to be startable (operable) when the drive voltage input to the drive voltage input means is equal to or higher than the first value. Therefore, even if the drive voltage supplied from the drive voltage supply means of the start-up means to the drive voltage input means of the calculation means is less than the second value, if the drive voltage is greater than or equal to the first value, the calculation means is continuously started up. (Can continue to operate). As a result, the computing means is first set in a state in which the computation processing cannot be performed, and then lowered. Therefore, even if the door opening detection means detects the opening of the gaming machine while the gaming machine is turned off and the rising means starts the calculation means for a predetermined period, the calculation means can be lowered during the second period. it can.

  In a gaming machine comprising a main body, a door body that opens and closes the front surface of the main body, and arithmetic means that executes arithmetic processing related to game control, door opening detection means that detects the opening of the door body with respect to the main body, Storage means capable of holding the detection of opening of the door body by the door opening detection means even when the gaming machine is turned off, and opening of the door body is detected by the door opening detection means while the gaming machine is turned off. The storage means and the calculation means within a predetermined period, and an off-operation means for supplying power to the startup means, and the calculation processing executed by the calculation means A gaming machine B1 comprising a storage execution process for causing the storage means to hold the detection of opening of the door when the arithmetic means is started up by the upper means within a predetermined period.

  According to the gaming machine B1, even when the power of the gaming machine is turned off and the calculation means is finished, when the door opening detection is detected by the door opening detection means, the power supplied by the off-operation means is used. The start-up means starts up the storage means and the calculation means within a predetermined period. Then, the computing means started up within a predetermined period executes the storage execution process, and causes the storage means to hold the door body opening detection. Therefore, for example, even if the door is opened due to an unauthorized act by someone after the store is closed with all the gaming machines turned off, the detection of the opening of the door is stored by the storage execution process executed by the computing means. The means can be held. Therefore, it is possible to grasp the opening of the door even when the power of the gaming machine is turned off.

  In the gaming machine B1, the calculation process executed by the calculation unit includes a termination process for terminating the started calculation unit, and the termination unit and the storage execution process are started by the calculation unit by the startup unit. A gaming machine B2 that is configured to complete the processing within a predetermined period.

  According to the gaming machine B2, even if the opening of the door is detected by the door opening detecting means while the gaming machine is turned off and the calculating means is started up by the rising means, the calculating means performs the storage execution process and the end. The processing can be completed within a predetermined period. Therefore, even if the door is opened while the power of the gaming machine is turned off, the detection of the opening of the door can be held in the storage means by the storage execution process, and the calculation means that has been started up for a predetermined period of time It can be terminated by a termination process.

  The gaming machine B1 or B2 includes detection signal receiving means for receiving a detection signal indicating opening detection of the door body by the door opening detection means, and the rising means opens the door body by the door opening detection means. Is detected signal output means for outputting a detection signal to the detection signal receiving means, and when the door opening detection is detected by the door opening detection means while the gaming machine is powered off. Is configured to start up the storage unit, the calculation unit, the detection signal output unit, and the detection signal reception unit within a predetermined period, and the calculation unit receives the detection signal by the detection signal reception unit. In this case, the storage device executes the storage execution process.

  According to the gaming machine B3, when the door opening detection means detects the opening of the door body while the gaming machine is powered off, the start-up means includes a storage means, a calculation means, and a detection signal output means for outputting a detection signal. A detection signal receiving means for receiving the detection signal is activated within a predetermined period. Then, when the detection signal output from the detection signal output means is received by the detection signal receiving means, the calculation means executes a storage execution process to hold the door body open detection in the storage means. That is, the calculation means executes the storage execution process for the first time when the detection signal receiving means receives the detection signal after being started up by the start-up means within a predetermined period. Therefore, the storage execution process by the computing means can be executed for the first time only when the door is reliably opened while the gaming machine is powered off.

  In the gaming machine B1 or B2, the game machine B1 or B2 includes a clocking unit that clocks the operation period of the computing unit, and the start-up unit is detected by the door opening detection unit when the opening of the door body is turned off. In this case, the storage unit, the calculation unit, and the timing unit are started up within a predetermined period, and the calculation unit has an operation period measured by the timing unit within a predetermined second period. However, when the termination process is executed, the storage execution process is executed assuming that the door is opened while the gaming machine is powered off. .

  According to the gaming machine B4, when the opening of the door is detected by the door opening detection means while the gaming machine is powered off, the start-up means counts the storage means, the calculation means and the operation period of the calculation means. Is launched within a predetermined period. In the case where the calculation means performs the end process even though the operation period timed by the time measuring means is within the predetermined second period, the door body was opened while the gaming machine was turned off. The memory execution process is executed. In other words, the computing means executes the storage execution process for the first time when the termination process is executed within the second period after being started up by the rising means within a predetermined period. Therefore, the storage execution process by the arithmetic means can be executed for the first time only when it is determined that the door body is reliably opened while the gaming machine is powered off by the operation period timed by the time measuring means.

  The gaming machine B3 or B4 includes backup means capable of holding data even after the gaming machine is powered off, and the arithmetic processing executed by the arithmetic means determines whether the data held in the backup means is valid. When the determination process is determined to be valid by the determination process, the data stored in the backup unit is used to return to the state before the power is turned off, and the determination process is determined to be invalid. In this case, an initialization process for initializing data held in the backup unit is provided, and the start of reception of the detection signal by the detection signal reception unit or the start of timing of the operation period by the timing unit is performed by the return process or the initial stage. A gaming machine B5, which is performed immediately after execution of any one of the merging processes.

  According to the gaming machine B5, when the opening of the door body is detected by the door opening detecting means while the power of the gaming machine is turned off and the calculating means is started up within a predetermined period by the rising means, after the return process or the initial stage Immediately after the conversion processing, that is, as soon as various settings of the calculation means are completed, the detection signal reception means starts receiving the detection signal or the time measurement means starts timing. Therefore, when the door is opened while the gaming machine is turned off, the opening of the door can be immediately detected.

  In the gaming machine B5, it is provided with notifying means for notifying when the opening detection of the door body is held in the storing means by the storing execution process, and the notifying means is provided when the gaming machine is turned on. On the other hand, while the game machine is powered off, even when the door opening detection means detects the opening of the door body, the startup by the rising means is not executed. A gaming machine B6 characterized by being a thing.

  According to the gaming machine B6, the notification means is activated when the power of the gaming machine is turned on, and notifies if the detection of opening of the door body is held in the storage means. On the other hand, when the door is detected to be opened by the door opening detection means while the gaming machine is powered off, the notification means is not activated by the rising means (even by the rising means) Is never). In other words, the notification means is started up when the power of the gaming machine is turned on, but the opening of the door body is detected by the door opening detection means while the power of the gaming machine is turned off, and is calculated by the startup means. Even if the means is started up within a predetermined period, the start-up means is not started up. Therefore, for example, even if the door is opened by an unauthorized person after closing the store where all the gaming machines are turned off and the detection of the opening of the door is held in the storage by the storage execution process, the notification means No notification will be made. Accordingly, the storage means can be held without the knowledge of the fraudster that the door has been opened while the power of the gaming machine is off. In addition, if the gaming machine is turned on and the detection of the opening of the door body is held in the storage means, the notification means will notify the game machine that the door body has been opened while the gaming machine is powered off. Can be specified.

  In the gaming machine B6, the gaming machine B6 includes erasing means for setting the detection of opening of the door held in the storage means by the storage execution process to an erasable state, and the detection of opening of the door held in the storage means The erasure means sets the release detection to an erasable state, and erasure is executed when the gaming machine is turned on and the arithmetic means is started up. A gaming machine B7.

  According to the gaming machine B7, the detection of the opening of the door held in the storage means is set so that the detection of the opening of the door can be erased by the erasing means, and the arithmetic means is turned on when the gaming machine is turned on. When it is launched, it is erased. That is, firstly, when the opening detection of the door body is set to a state that can be erased by the erasing means, and secondly, when the gaming machine is turned on and the arithmetic means is started up, it is held in the memory means for the first time. The detected door opening detection is erased. Therefore, once the door opening detection is held in the storage means, the door opening detection cannot be erased from the storage means unless the above procedure is followed. Therefore, when the detection of the opening of the door is held in the storage means, it is possible to make it difficult to erase the detection of the opening of the door by an unauthorized person.

  In any one of the gaming machines B1 to B7, the game machine includes output means for outputting a predetermined signal to a specific device based on the arithmetic processing of the arithmetic means, and the rising means is configured to open the door body by the door opening detection means. When detected while the gaming machine is powered off, the output means is started up within a predetermined period, and the calculation process executed by the calculation means is the detection of opening of the door by the storage execution process. An output process for causing the output means to output detection of opening of the door as a predetermined signal when held in the storage means, and the output process is performed within a predetermined period during which the arithmetic means is started up by the rising means. A gaming machine B8, which is configured to complete the processing at.

  According to the gaming machine B8, when the opening of the door is detected by the door opening detection means while the gaming machine is powered off, the start-up means raises the output means within a predetermined period in addition to the storage means and the calculation means. . Then, the computing means started up within a predetermined period executes an output process, and causes the output means to output detection of opening of the door as a predetermined signal. Here, the predetermined signal is output to the specific device. Therefore, for example, even if the door body is opened due to an unauthorized act by somebody after the store is closed with all the gaming machines turned off, the gaming machine with the door body opened can be determined by the specific device. .

  In addition, a predetermined signal output from output means provided for each of a plurality of gaming machines may be received by one specific device, or a specific device is provided for each gaming machine, and the specific device is provided to each gaming machine. It may be arranged. When a specific device is installed in each gaming machine, the box base and the box cover covering the opening of the box base are connected to each other, and the specific device is specified in the space formed by the box cover and the box base. Store the device. Then, the box cover and the box base are connected by the sealing unit so that they cannot be opened. Further, a seal seal is attached to the connecting portion between the box cover and the box base over the box cover and the box base. In addition, a specific device may be disposed on the back surface or the back surface side of the door body.

  In a gaming machine comprising a main body, a door body that opens and closes the front surface of the main body, and an arithmetic means that performs arithmetic processing related to game control, door opening detection means for detecting the opening of the door body with respect to the main body, and A game machine C1 comprising: a calculation start-up means for starting up the calculation means for a predetermined period when the door opening detection means detects the opening of the door body while the gaming machine is powered off. .

  According to the gaming machine C1, even when the power of the gaming machine is turned off and the calculation means is stopped, when the door opening detection is detected by the door opening detection means, the calculation start-up means Is launched for a predetermined period. Therefore, the computing means that has been started up for a predetermined time can be used, for example, to store the detection of door opening or to output the door opening detection to a specific device (specific device). it can.

  In a gaming machine comprising a main body, a door body that opens and closes the front surface of the main body, and an arithmetic means that performs arithmetic processing related to game control, door opening detection means for detecting the opening of the door body with respect to the main body, and When the opening of the door is detected by the door opening detection means while the gaming machine is turned off, the calculation start-up means for starting up the calculation means for a predetermined period, and the calculation started by the calculation start-up means The game machine D1 further comprising output means for outputting the detection of opening of the door body to the specific device based on the arithmetic processing of the means.

  According to the gaming machine D1, even when the power of the gaming machine is turned off and the computing means is stopped, if the door opening detection is detected by the door opening detecting means, the computing start-up means Launched for a predetermined period. Then, based on the calculated calculation process of the calculation means, the output means outputs the door body opening detection to the specific device. Therefore, for example, even if the door is opened due to an unauthorized act by someone after the store is closed with all the gaming machines turned off, the detection of the opening of the door can be output to the specific device. Therefore, it is possible to grasp the opening of the door even when the power of the gaming machine is turned off.

  Based on the main body, the door body that opens and closes the front face of the main body, arithmetic processing related to game control, and signals output from the main arithmetic means, arithmetic processing related to control of the electrical device is performed. A door opening detecting means for detecting opening of the door body with respect to the main body in a gaming machine comprising: a sub-operating means to perform; and a power supply means for supplying driving power to the main computing means, the sub-calculating means and the electrical device. , When the door opening detection means detects the opening of the door body even when the driving power from the power supply means is not supplied, and when the driving power from the power supply means is not supplied. When opening of the door body is detected by the door opening detection means, the holding means and the main arithmetic means are raised for a predetermined period, and the rising means for holding the opening detection of the door body by the holding means, Electric When the drive power from the means is not supplied and the door opening detection means detects the opening of the door body, the off-operation means for supplying drive power to the rising means, and the power supply means Output means for outputting a predetermined signal according to the holding state of the holding means for holding the detection of opening of the door body when driving power is supplied to the main calculation means, the sub calculation means and the electrical device. A gaming machine E1 characterized by being.

  According to the gaming machine E1, even when drive power is not supplied from the power supply means to the main calculation means, the sub calculation means, and the electrical device, when the door opening detection means detects the opening of the door body, the rising means Uses the drive power supplied by the off-operation means to start up the holding means and the main calculation means for a predetermined time and hold the door body open detection in the holding means. When driving power is supplied from the power supply means to the main arithmetic means, the sub arithmetic means, and the electrical device, the output means outputs a predetermined signal according to the holding state of the holding means. Thus, for example, after closing a store where the drive power from the power supply means is not supplied in all gaming machines, even if the door body is opened by an unauthorized act by somebody, the opening of the door body is maintained and the power supply means When driving power is supplied, a predetermined signal can be output. Therefore, it is possible to grasp the opening of the door performed when the driving power by the power supply means is not supplied, that is, when the power of the gaming machine is turned off.

  In the gaming machine E1, the main calculation means is a startup process that is executed once when driving power is supplied from the power supply means, and is executed after the startup process, and repeatedly executes a plurality of calculation processes. Processing and output control processing for outputting a second predetermined signal to the sub-calculation means by the output means in accordance with the holding state of the holding means for holding the detection of opening of the door body. A gaming machine E2 that is executed in the start-up process and then moves to the normal process.

  According to the gaming machine E2, according to the holding state of the holding means for holding the detection of opening of the door body, the output control process for outputting the second predetermined signal to the sub-calculating means by the output means is supplied with the driving power by the power supply means. In this case, it is executed in the start-up process of the main calculation means executed once. As described above, when the driving power is supplied by the power supply means, the output control process is immediately executed and the second predetermined signal is output to the sub-calculation means. Therefore, the operation is performed when the power of the gaming machine is turned off. The opening of the broken door can be immediately grasped by the sub-calculation means. In addition, when the 2nd predetermined signal is output to the sub calculating means, the sub calculating means performs an alert | report by controlling an electrical apparatus, for example. Further, since the output control process is executed within the startup process of the main arithmetic means, the output control process can be made non-executable in the normal process in which a plurality of arithmetic processes are repeatedly executed.

  In the gaming machine E1 or E2, the main calculation means is provided separately from the main calculation means and is electrically connected to a specific device that detects the operating status of the gaming machine. When opening of the door body is detected by the door opening detection means when drive power from the power supply means is not supplied, a third predetermined signal is sent to the specific device according to the holding state of the holding means. A gaming machine E3, characterized in that the third output means for outputting is activated for a predetermined period.

  According to the gaming machine E3, when the door opening detection means detects the opening of the door body when the driving power from the power supply means is not supplied, the rising means starts up the third output means for a predetermined time. And a 3rd output means outputs a 3rd predetermined signal to a specific apparatus according to the holding | maintenance state of the holding means holding the opening detection of a door body. Therefore, when the drive power from the power supply means is not supplied, that is, when the opening of the door body is detected by the door opening detection means when the power of the gaming machine is turned off, at that time, The specific device can grasp the opening of the door performed while the power of the gaming machine is turned off.

  In the gaming machine E3, the main calculation means causes the third output means to output a third predetermined signal to the specific device according to the holding state of the holding means for holding the detection of opening of the door body. A gaming machine E4, characterized in that the third output control process is executed in the start-up process and then the process proceeds to the normal process.

  According to the gaming machine E4, the third output control process for outputting the third predetermined signal to the specific device by the third output means according to the holding state of the holding means for holding the opening detection of the door body is driven by the power supply means. It is executed in the start-up process of the main computing means that is executed once when power is supplied. As described above, when the driving power is supplied by the power supply means, the third output control process is immediately executed and the third predetermined signal is output to the specific device. Therefore, when the power of the gaming machine is turned off. The specific opening of the door body performed can be immediately grasped. Further, since the third output control process is executed within the startup process of the main arithmetic means, the third output control process can be made non-executable in the normal process in which a plurality of arithmetic processes are repeatedly executed. .

Needless to say, it is naturally possible to realize a gaming machine in which the above gaming machines A1 to A7, gaming machines B1 to B8, gaming machine C1, gaming machine D1, and gaming machines E1 to E4 are appropriately combined. .
<Others>
In a pachinko machine, when a ball that has been driven into the game area enters the symbol operating port, a lottery is performed at the timing of the entry (for example, Patent Document 1: Japanese Patent Laid-Open No. 2001-198332). Further, in a spinning-type game machine using a slot machine or a game ball, when a start lever is operated, a lottery is performed at the operation timing. As a result of the lottery, for example, when a big hit is made, a large amount of prize balls and coins can be paid out. Since the control for determining the lottery and the jackpot is performed by the main control device, the main control device is likely to be an object of fraud.
Specifically, for example, the main control device may be replaced with an unauthorized one that frequently generates jackpots, or an illegal board (for example, a “hanging board”) may be connected to the main control apparatus. There are things that illegally generate. In addition, in the case of a pachinko machine, there is also a fraudulent act that makes it easier for a ball to enter a winning port or a symbol operating port by illegally bending a nail that has been driven onto the game board surface.
In the case of a pachinko machine, the main control device is mounted on the back of the game board. A frame body is provided on the back surface of the game board, and an inner frame on which the game board is mounted is provided on the front surface of the frame body. The inner frame can be opened and closed with respect to the frame. A glass frame is provided on the front surface of the inner frame, and the glass frame can be opened and closed with respect to the inner frame. Therefore, when a cheating person performs cheating on the game board surface or the main control device, the inner frame or the glass frame must be opened, but when the inner frame or the glass frame is opened, Opening is detected by a sensor and notified to the hall computer that manages the amusement hall, as well as to which pachinko machine by informing the outside that the inner frame or glass frame has been opened by lighting the lamp or outputting sound. It is possible to easily grasp whether cheating has been done.
However, if, for example, late at night after the amusement hall is closed, a fraudulent person enters, and the intruder opens the inner frame or the glass frame and conducts a fraudulent action, the pachinko machine is turned off at that time. Since the pachinko machine is stopped, the opening of the inner frame or the glass frame cannot be detected, and it is very difficult to grasp the opening.
This technical idea was made to solve the above-mentioned problems and the like, and when the door is opened while the power of the gaming machine is turned off, the opening can be grasped. It aims at providing the gaming machine which can be.
<Means>
In order to achieve this object, the gaming machine described in the technical idea 1 includes a main body, a door body that opens and closes the front surface of the main body, main arithmetic means that executes arithmetic processing related to game control, and the main arithmetic means. Sub-calculation means for performing arithmetic processing related to control of an electrical device based on an output signal, and power supply means for supplying driving power to the main computation means, the sub-calculation means, and the electrical device The door opening detection means for detecting the opening of the door body with respect to the main body, and the holding that can hold the opening detection of the door body by the door opening detection means even when the driving power from the power supply means is not supplied. And when the door opening detection means detects the opening of the door body when the drive power from the power supply means is not supplied, the holding means and the main calculation means are started up for a predetermined period, and the door Body release Drive up to the riser means when the drive means from the power supply means is not supplied and the door opening detection means detects the opening of the door body. A holding state of holding means for holding detection of opening of the door body when driving power is supplied to the main calculation means, the sub calculation means and the electrical device by the off-state operation means for supplying power and the power supply means And an output means for outputting a predetermined signal. In general, the main calculation means is provided in a space formed by the door body and the main body. Furthermore, the inside of the space formed by the door body and the main body indicates the back surface or the back surface side (including the back surface side of the main body) of the door body which cannot be touched by the hand when the door body is closed.
The gaming machine described in the technical idea 2 is the gaming machine described in the technical idea 1, wherein the main calculation means includes a startup process executed once when driving power is supplied from the power supply means, and a startup process thereof. A second predetermined signal is sent from the output means to the sub-calculation means according to a normal process that is executed after the raising process and repeatedly executes a plurality of arithmetic processes and a holding state of the holding means that holds the detection of opening of the door body. Output control processing to be output, the output control processing is executed in the start-up processing, and thereafter, the process proceeds to the normal processing.
The gaming machine described in the technical idea 3 is the gaming machine described in the technical idea 1 or 2, wherein the main calculation means is provided separately from the main calculation means and detects the operating status of the gaming machine When the door opening detection means detects the opening of the door body when the drive power from the power supply means is not supplied, the rising means holds the holding means. The third output means for outputting a third predetermined signal to the specific device is activated for a predetermined period in accordance with the holding state of the means. Note that the main arithmetic means and the specific device are electrically connected means that the main arithmetic means and the specific device are connected by a signal line, or an input / output port including a latch circuit or the like. The case where it connects via wireless communication and the case where it connects via wireless communication are also included.
The gaming machine described in the technical idea 4 is the gaming machine described in the technical idea 3, in which the main calculation unit is operated by the third output unit according to a holding state of the holding unit that holds the opening detection of the door body. A third output control process for outputting a third predetermined signal to the specific device is provided, the third output control process is executed in the start-up process, and then the process proceeds to the normal process.
<Effect>
According to the gaming machine described in the technical idea 1, even when the driving power is not supplied from the power source means to the main arithmetic means, the sub arithmetic means, and the electrical device, the door opening detection means detects the opening of the door body. Then, the rising means raises the holding means and the main arithmetic means for a predetermined time by the driving power supplied from the off-operation means, and causes the holding means to hold the door body open detection. When driving power is supplied from the power supply means to the main arithmetic means, the sub arithmetic means, and the electrical device, the output means outputs a predetermined signal according to the holding state of the holding means. Thus, for example, after closing a store where the drive power from the power supply means is not supplied in all gaming machines, even if the door body is opened by an unauthorized act by somebody, the opening of the door body is maintained and the power supply means When driving power is supplied, a predetermined signal can be output. Therefore, there is an effect that it is possible to grasp the opening of the door performed when the driving power by the power supply means is not supplied, that is, when the power of the gaming machine is turned off.
According to the gaming machine described in the technical idea 2, in addition to the effect produced by the gaming machine described in the technical idea 1, the output unit switches to the sub-calculation unit according to the holding state of the holding unit that holds the detection of the door body opening. The output control process for outputting the second predetermined signal is executed in the start-up process of the main calculation means that is executed once when the driving power is supplied from the power supply means. As described above, when the driving power is supplied by the power supply means, the output control process is immediately executed and the second predetermined signal is output to the sub-calculation means. Therefore, the operation is performed when the power of the gaming machine is turned off. There is an effect that the opening of the broken door can be immediately grasped by the sub-calculation means. In addition, when the 2nd predetermined signal is output to the sub calculating means, the sub calculating means performs an alert | report by controlling an electrical apparatus, for example. Further, since the output control process is executed within the startup process of the main arithmetic means, there is an effect that the output control process can be made non-executable in the normal process in which a plurality of arithmetic processes are repeatedly executed. .
According to the gaming machine described in the technical idea 3, in addition to the effect produced by the gaming machine described in the technical idea 1 or 2, the door opening detection means opens the door body when the driving power from the power supply means is not supplied. Is detected, the rising means starts up the third output means for a predetermined time. And a 3rd output means outputs a 3rd predetermined signal to a specific apparatus according to the holding | maintenance state of the holding means holding the opening detection of a door body. Therefore, when the drive power from the power supply means is not supplied, that is, when the opening of the door body is detected by the door opening detection means when the power of the gaming machine is turned off, at that time, The specific device has an effect that it can grasp the opening of the door body performed while the power of the gaming machine is turned off.
According to the gaming machine described in the technical idea 4, in addition to the effect produced by the gaming machine described in the technical idea 3, the specific device is used by the third output unit according to the holding state of the holding unit that holds the opening detection of the door body. The third output control process for outputting the third predetermined signal is executed in the start-up process of the main calculation means that is executed once when the driving power is supplied from the power supply means. As described above, when the driving power is supplied by the power supply means, the third output control process is immediately executed and the third predetermined signal is output to the specific device. Therefore, when the power of the gaming machine is turned off. There is an effect that the specific opening of the door body can be immediately grasped. Further, since the third output control process is executed within the startup process of the main arithmetic means, the third output control process can be made non-executable in the normal process in which a plurality of arithmetic processes are repeatedly executed. There is an effect.

10 Pachinko machines (game machines)
11 Outer frame (main body)
12 Inner frame (part of door)
14 Front frame (part of door)
110 Main controller (part of main calculation means)
113 voice lamp control equipment 115 power supply (part of the power supply means)
201 MPU (part of the main processing unit, a part of the output means)
203 RAM (part of holding means )
203a Off middle frame release flag (part of holding means)
205 I / O port (part of output means)
226 audio output equipment 227 lamp display equipment 260 frame opening detection circuit (rising section)
262 Hall computer (special equipment)
CD1 capacitor ( rising means)
S101 to S117, S227 to S229 Startup process S201 to S203, S207 to S224 Main process (normal process)
S201 to S212 main processing (repetition processing)
S228 Startup process (part of output control process)
S229 Startup process (part of third output control process)
SW1 switch (part of door opening detection means)
SW2 switch (part of door opening detection means)

Claims (1)

In a gaming machine comprising a main body, a door body that can be opened and closed with respect to the main body, main arithmetic means for executing arithmetic processing relating to game control, and power supply means for supplying driving power to the main arithmetic means,
Door opening detection means for detecting the opening of the door body;
Holding means capable of holding the detection of opening of the door body by the door opening detection means even when drive power from the power supply means is not supplied;
If the door opening detection means detects the opening of the door body when the drive power from the power supply means is not supplied, the holding means and the main calculation means are activated to supply power for a predetermined period. And a rising means for holding the opening detection of the door body in the holding means,
The main calculation means includes
It is electrically connected to a specific device provided separately from the main calculation means,
Repetitive processing for repeatedly executing a plurality of arithmetic processes at a predetermined execution interval;
When it is started up by the rising means, based on the fact that the detection of opening of the door body is held in the holding means, a pulse having a length shorter than the execution interval of the repetitive processing is given to the specific device. Output means for outputting ,
The output means starts executing the repetitive processing after the holding means and the main calculation means are started up by the rising means and the opening detection of the door body is held by the holding means. The game machine is characterized in that the pulse is output to the specific device once based on the fact that the holding means holds the detection of opening of the door before the holding means .

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