JP3955895B2 - Bullet ball machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention belongs to the technical field of ball game machines.
[0002]
[Prior art]
2. Description of the Related Art A bullet ball game machine, for example, a pachinko game machine, is configured to pay out a predetermined number of game balls as prize balls (sometimes referred to as prize balls) when the launched game balls win a prize opening. .
[0003]
In conventional pachinko gaming machines, the game balls (safe balls) that win the respective winning holes on the game board are temporarily stopped in the safe ball tank, and the stopped game balls are detected one by one by the sensor, After a predetermined number of prize balls are paid out to the player by the payout device, the detected game balls are discharged from the safe ball tank.
[0004]
In this conventional pachinko machine, the winning game ball is temporarily stopped in the safe ball tank, and after the payout of the prize ball is completed, it is discharged outside the machine, so even if an unexpected situation such as a power failure occurs, Can be paid out for a game ball that has been stopped after the power failure has been resolved, and the player is not disadvantaged. Was.
[0005]
The paid-out game balls are usually guided to the upper plate, and when the upper plate is full, they are guided to the lower plate and stored respectively. However, when the bottom plate is full, the game balls paid out from the payout device will fill the path from the payout device to the lower plate, and eventually the game balls will rise up to the prize ball payout device. There was a possibility that the ball dispensing device might break down.
[0006]
In order to prevent such problems, a switch that detects when the lower pan is full (usually called a full tank switch) is provided, and when the full tank switch is turned on, that is, when the lower pan is full, Dispensing was stopped and a warning was reported. By stopping the payout of the prize balls, it is possible to prevent a failure of the prize ball payout device and overflow of the game balls from the upper and lower plates caused by the raised game balls.
[0007]
However, if the payout of the winning ball is stopped, the safe ball is not discharged, so the safe ball fills the safe ball tank, and the variable winning device (for example, the attacker) is filled with the safe ball and cannot be closed. Therefore, in conjunction with the stoppage of the prize ball, the launch of the game ball was stopped to prevent the occurrence of a new prize.
[0008]
[Problems to be solved by the invention]
  However,Even when the award ball and launch are stopped by the full tank switch, the safe ball tank becomes full when the capacity of the safe ball tank is small or the safe ball is not discharged quickly because the award ball payout operation is slow. Thus, for example, a safe ball rises up to an attacker, and when it should be closed, it could not be closed, and there was a case where it exceeded the upper limit number (for example, 10) allowed during one opening.
[0009]
  In addition, if the player does not remove the ball from the lower plate, the fire is frequently stopped and a warning notification is made, so that the interest of the game is impaired. In particular, the suspension was unpopular.
[0010]
[Means and effects for solving the problems]
  The bullet ball game machine according to claim 1 is a game board, winning detection means for detecting a winning of a gaming ball, a winning ball payout device for paying out a gaming ball (prize ball) corresponding to the winning, and the prize The prize ball paid out from the ball dispensing device is preferentially guided to the upper plate, and is guided to the lower plate when the upper plate is filled with game balls.
A ball game machine comprising: a prize ball guiding path; a main control board to which the winning detection means is connected; and a discharge control board for driving and controlling the prize ball payout device.
  Prize ball data storage means for storing data related to a winning detected by the winning detection means;
  Payout control means for controlling the payout device based on the data stored in the prize ball data storage means;
  Memory holding means for storing and holding the data stored in the prize ball data storage means so as not to disappear during a power failure;
  A winning ball discharge path for discharging the winning game ball to the outside without stagnation;
  A full detection means arranged on the prize ball guide path for detecting a full state in which the lower plate side is filled with game balls from the arrangement position;
  A prize ball stop means for stopping the payout of the prize ball when the full state is detected by the full detection means;
  After the award ball stopping means stops paying out the prize ball, the full state is detected by the full detection means.The stop of payout of prize balls by the prize ball stop means is released,And when there is unpaid prize ball data in the prize ball data storage means, the payout control means executes the prize ball payout until the unpaid prize ball data becomes zero,
  Furthermore,
  The prize control data storage means, the payout control means and the memory holding means are provided on the discharge control board,
  One power supply board for supplying power to the main control board and the discharge control board;
  The main control board and the discharge control board are respectively provided with voltage monitoring circuits (60, 62) for monitoring the voltage of the same power supply (DC12V) generated and supplied from the one power supply board,
  The main control board and the discharge control board are each reset by the voltage monitoring circuit (60, 62),
  The power supply board generates and supplies backup power used for the memory holding means.And
  The main control board and the discharge control board are provided with a security check function executed when power is turned on,
  The security check time T1 of the main control board is not less than the security check time T2 of the discharge control board,
  When the security check operation for the main control board is completed after the power is turned on, the security check operation for the discharge control board is already completed.
It is characterized by that.
[0011]
  The winning ball stop meansWhen a full state is detected by the full detection meansSince the payout of prize balls is stopped, the game balls paid out from the prize ball payout deviceRoute from prize ball dispensing device to lower plateTherefore, there is no possibility that such a game ball rises and the prize ball payout device breaks down.
[0012]
  On the other hand, the winning ball data storage means stores data related to the winning detected by the winning detection means, and the payout control means controls the payout device based on the data stored in the winning ball data storage means. Further, the memory holding means stores and holds the data stored in the winning ball data storage means so as not to disappear at the time of a power failure. Therefore, it is not necessary to stop the winning game balls as so-called evidence balls, and even if the winning game balls are discharged out of the plane without stagnation through the winning ball discharge path, there is no problem in paying out the winning balls.
[0013]
  Since the winning game balls (safe balls) are quickly discharged out of the machine through the winning ball discharge path, the safe balls rise into the variable winning device (for example, attacker) due to the discharge delay of the safe balls. There is no risk of making it unclosable.
  When the lower plate becomes full, it suffices to stop paying out the winning ball, and it is not necessary to stop the game ball from firing in order to prevent a new winning. Therefore, it is not frequently stopped due to the full lower plate, and it is possible to avoid impairing the fun of the game.
[0014]
  In this ball game machine, the full state is detected by the full detection means after the payout of the prize balls is stopped by the prize ball stopping means.The stop of payout of prize balls by the lost prize ball stop means is released,If there is unpaid prize ball data in the prize ball data storage means, the payout control means executes the prize ball payout until the unpaid prize ball data becomes zero.
  The ball game machine further includes a main control board to which the winning detection means is connected and a discharge control board for driving and controlling the prize ball payout device. The prize ball data storage means, the payout control means, and the memory holding Means are provided on the discharge control board.
  Also, a voltage monitoring circuit (60, 62) that includes one power supply board that supplies power to the main control board and the discharge control board, and monitors the voltage of the same power supply (DC12V) generated and supplied from this one power supply board. Are respectively provided on the main control board and the discharge control board, the main control board and the discharge control board are reset by the voltage monitoring circuit (60, 62), and the power supply board generates and supplies a backup power source used for the memory holding means.
  The main control board and the discharge control board are provided with a security check function executed when the power is turned on, the security check time T1 of the main control board is equal to or longer than the security check time T2 of the discharge control board, and the power When the security check operation for the main control board is completed after being turned on, the security check operation for the discharge control board has already been completed.
  The winning detection means may be any means as long as it is means for detecting that a game ball has been won. For example, a switch whose position changes when a winning game ball is detected or a sensor whose signal level also changes can be adopted. . Further, the winning detection means may be configured to be individually provided in all the winning holes, or may be configured to collect and detect game balls that win in the same winning ball according to the difference in the number of winning balls. .
[0015]
  The winning ball data storage means is not limited in its configuration and form as long as it can store data related to winnings detected by the winning detection means. The contents to be stored are the number of payouts required for the number of winning balls (for example, 5 winning balls, 10 winning balls, and 15 winning balls) set in the winning opening, that is, the amount of payout incomplete Any content can be used as long as it can be specified.
[0016]
  Since the memory holding means only needs to be able to store and hold the data stored in the prize ball data storage means so as not to disappear in the event of a power failure, the configuration thereof corresponds to the configuration of the prize ball data storage means. If a memory that requires electric power for memory retention such as RAM is used as the prize ball data storage means, a backup battery that operates during a power failure is suitable for the memory retention means.
[0017]
  The bullet ball game machine according to claim 2 is the bullet ball game machine according to claim 1, wherein the same power supply (DC12V) generated and supplied by the one power supply board monitored by each of the voltage monitoring circuits (60, 62). ) Is provided with a backup voltage monitoring circuit (64) for monitoring the voltage of Before the reset by the voltage monitoring circuit (62) of the discharge control board, writing to the RAM of the discharge control board is prohibited by the backup voltage monitoring circuit (64).
[0018]
  3. The ball game machine according to claim 3, wherein the backup voltage monitoring circuit is configured to output the voltage of the same power source (DC12V) monitored by the voltage monitoring circuit (60, 62). The discharge control board is reset by comparing with the voltage of another power supply (DC5V) generated by the power supply board and supplied to the RAM, which is lower than the voltage of the power supply (DC12V). Access to the RAM is prohibited before being performed.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
Preferred embodiments of the present invention will be described below with reference to the drawings. The embodiments of the present invention are not limited to the following specific examples, and it goes without saying that various forms can be adopted as long as they belong to the technical scope of the present invention.
[0026]
As shown in FIG. 1, the pachinko machine 10 of this specific example includes a rectangular outer frame 11 and a front frame 12, and a known prepaid card unit 13 is provided on the left side of the outer frame 11. The front frame 12 is rotatably attached to the outer frame 11 by hinges 14 at the upper and lower left ends.
[0027]
An upper plate 15 is provided below the front frame 12, and a lending button 16, a settlement button 17 and a balance display unit 18 are provided on the upper plate 15. When a prepaid card is inserted into the card slot 19 of the prepaid card unit 13, the stored balance is displayed on the balance display unit 18, and when the lending button 16 is pressed, gaming balls are lent out, and the gaming balls are discharged from the dispensing outlet of the upper plate 15. Is discharged.
[0028]
A window-shaped metal frame 20 is attached to the front frame 12 so as to be openable with respect to the front frame 12. A plate glass 21 is double fitted in the metal frame 20. A game board 22 is stored behind the plate glass 21.
A lower plate 23 is provided at the lower part of the front frame 12 of the upper plate 15, and a firing handle 24 is attached to the right side of the lower plate 23. A dial portion 24 a is mounted on the outer periphery of the launch handle 24, and the game ball can be launched onto the game board 22 by rotating the dial portion 24 a clockwise. The firing handle 24 is provided with a firing switch 24b for stopping firing and a touch switch 24c for outputting a signal according to whether or not the player is in contact with the dial portion 24a (not shown in FIG. 1). (See FIG. 6).
[0029]
FIG. 2 is a back view of the pachinko machine 10 viewed from the back side. As shown in the drawing, a mechanism board 26 to which the above-described game board 22 is detachably attached is housed in the above-described outer frame 11. The mechanism board 26 is provided with a ball tank 27, a guide rod 28, and a discharge mechanism portion 29 from above, and a game ball guide path 70 is connected to the downstream side of the discharge mechanism portion 29.
[0030]
The structure of the discharge mechanism 29 is as shown in FIG. 3, and game balls from the guide basket 28 are divided into a prize ball basket 29a and a ball rental basket 29b. The winning ball bowl 29a is equipped with a prize ball breaking device 29c, and the rental ball bowl 29b is equipped with a ball rental breaking device 29d. Each of the prize ball breaker 29c and the ball lending breaker 29d is provided with a motor and a ball cutting screw, and can pass (that is, discharge) a game ball downstream by one by rotation of the screw. In addition, a prize ball passing sensor 29e for detecting a game ball discharged by the prize ball interrupting device 29c is attached to the prize ball cage 29a, and a rental ball for detecting the game ball discharged by the ball rental interrupting device 29d is detected. A ball passage sensor 29f is mounted on the ball rental basket 29b.
[0031]
In this specific example, the prize ball bowl 29a and the prize ball cutting device 29c constitute a prize ball payout means, and the prize ball passage sensor 29e corresponds to the prize ball detection means. Similarly, the ball rental basket 29b and the ball rental cutting device 29d constitute a ball rental discharge means, and the ball rental passage sensor 29f corresponds to the ball rental detection means.
[0032]
The game ball guide path 70 connected to the downstream side is provided with an upper plate guide rod 71 communicating with the upper plate 15, and the lower ends of the prize ball basket 29 a and the rental ball basket 29 b are both upper plate guides. It opens above the ridge 71. Further, a portion passing through the side of the upper plate guide rod 71 is a lower plate guide rod 72, and an end of the lower plate guide rod 72 communicates with the lower plate 23. And as shown in FIG.Is full switch73 is attached.
[0033]
With this configuration, when the prize ball disconnecting device 29c is operated, the game balls that have flowed from the ball tank 27 to the prize ball bowl 29a via the guidance bowl 28 are transferred from the prize ball bowl 29a to the upper plate guidance bowl 71. When the rental ball breaker 29d is operated, the game ball of the rental ball cage 29b can be discharged toward the upper plate guide rod 71.
[0034]
The game balls discharged from the winning ball basket 29a and the rental ball basket 29b are normally guided from the upper plate guide rod 71 to the upper plate 15. However, sometimes the upper plate 15 becomes full and the upper plate guide bar 71 is filled with game balls. Then, since the game balls discharged from the prize ball basket 29a and the ball rental basket 29b cannot flow into the upper plate guide rod 71, they are discharged to the lower plate 23 through the lower plate guide rod 72. When the lower pan 23 is full and the full ball switch 73 of the lower pan guide rod 72 is filled with the game ball, the full tank switch 73 changes its position (in this example, it changes from off to on). The full state of the lower plate 23 can be detected by monitoring the signal.
[0035]
In addition, the main control board 30 and the discharge control board 31 can be attached to and detached from the mechanism board 26, the game board 22 has a special symbol display device 32, and a launch device 33b having a launch motor 33a in the lower left part of the front frame and launch control. The external connection terminal board 50 is attached to the left side of the special symbol display device 32, respectively.
[0036]
Next, the game board 22 will be described with reference to FIG.
As shown in FIG. 4, the game board 22 has an LCD panel unit (hereinafter referred to as “LCD”) 32a constituting a special symbol display device 32 at the center, and a normal electric accessory serving as a first type starting port at the lower part thereof. 36, the normal symbol display device 37 on the upper part of the LCD 35, the normal winning opening 78 provided behind the normal symbol display device 37, and the normal symbols on the left and right of the LCD 35 used for starting the variation of the symbols displayed on the normal symbol display device 37. Actuating gates 38, 39, ordinary winning holes 74, 75 arranged below these gates 38, 39, and a large winning opening 40 and left and right ordinary winning holes 76, 77 arranged below the ordinary electric accessory 36. A large winning device 80, an out port 41 at the bottom of the board, other various winning ports, a windmill, a game nail (not shown) and the like are provided.
[0037]
With this configuration, when the above-described launch handle 24 is rotated, the launch motor 33a controlled by the launch control board 33 is driven, and the game ball supplied from the upper plate 15 to the launch device 33b is guided to the guide rail and played. Fired on board 22 If the launched game ball wins each winning hole, the game ball is taken into the back of the board as a safe ball, and if not won, it is taken into the back of the board through the out port 41 as well.
[0038]
As shown in FIG. 5, on the back of the game board 22, a ball port 79 and a normal winning port 74, 75, 76, 77, 78 of the ordinary electric accessory 36 are opened. A winning ball switch 79a, 74a, 75a, 76a, 77a, 78a for detecting a winning ball is attached.
[0039]
The regular winning opening 78 is provided with a bowl 78b, and the game ball dropped from the normal winning slot 78 passes through the winning ball switch 78a and then drops from the tip of the bowl 78b. The base 78b guides the winning ball to the winning ball switch 78a and prevents the winning ball from colliding with the special symbol display device 32.
[0040]
On the other hand, with respect to the normal winning holes 74, 75, 76, 77 and the ball opening 79, arched covers 74b, 75b, 76b, 77b covering the range from the upper side to the winning ball switches 74a, 75a, 76a, 77a, 79a. 79b. These covers 74b, 75b, 76b, 77b, and 79b guide the respective winning balls to the winning ball switches 74a, 75a, 76a, 77a, and 79a, and prevent mixing of game balls that have passed through other winning ports. To do. The cover 79b is provided with a bypass rod 79c for bypassing the big winning device, but the winning ball switches 74a, 75a, 76a, 77a are not provided with a cage below.
[0041]
The game balls that have flowed out to the back side of the game board 22 from the ball opening 79 and the normal winning openings 74, 75, 76, 77, 78 of the ordinary electric accessory 36 are guided to the basket or the cover, and the winning ball switches 79a, 74a, respectively. , 75a, 76a, 77a, 78a and fall along the back of the game board 22. In addition, the game ball that has won the big winning opening 40 is detected by either the continuation switch 40a or the count switch 40b and then falls in the same manner. The continuation switch 40a detects that the game ball that has won the grand prize opening 40 has passed through a special device operating area (hereinafter referred to as "special area"), and the count switch 40b is another game that has won the big prize opening 40. A sphere is detected.
[0042]
A back cover 81 including a peripheral frame 81a and a back plate 81b is attached to the back of the game board 22, and a back plate 81b (FIG. 5 shows a state seen through the back plate 81b) is a bag 78b. Covers the back of the covers 74b, 75b, 76b, 77b, 79b and the detour rod 79c. Therefore, game balls will not spill out from the bowl 78b, the covers 74b, 75b, 76b, 77b, 79b and the detour basket 79c. The lower end portion of the back cover 81 is not provided with a peripheral frame 81a but has an opening 81c, and has passed through any of the winning ball switches 79a, 74a, 75a, 76a, 77a, 78a, the continuation switch 40a, or the count switch 40b. All the game balls fall from the opening 81c.
[0043]
A winning ball discharge path 82 including a funnel-shaped ball collecting portion 82a having an upper end opening and a ball discharge bowl 82b is disposed below the opening 81c. The lower end of the throwing bowl 82b is open to the outside of the machine, and the winning ball is discharged from here (for example, a ball collecting path on the gaming machine installation island). The winning ball to be discharged is detected by a discharge ball detection switch 83 attached to the ball basket 82b. That is, winning balls are individually detected by the winning ball switches 79a, 74a, 75a, 76a, 77a, 78a, the continuation switch 40a, and the count switch 40b, and are also detected by the discharge ball detection switch 83. By comparing the number of winning balls detected by the switches 79a, 74a, 75a, 76a, 77a, 78a, the continuation switch 40a and the count switch 40b with the number of detections of the discharge ball detecting switch 83, for example, winning ball switches 79a, 74a, It is possible to find an illegal act that causes the malfunction of 75a, 76a, 77a, 78a, the continuation switch 40a, or the count switch 40b.
[0044]
Next, the electrical configuration of the pachinko machine 10 described above will be described with reference to the block diagram of FIG.
As shown in the figure, the electric circuit of the pachinko machine 10 includes the main control board 30, the discharge control board 31, the special symbol display device 32, the launch control board 33, the lamp control board 34, the sound control board 35, and the like. Yes. In this circuit diagram, a so-called relay board or the like is not shown in order to exchange signals.
[0045]
The main control board 30 is configured as a logic operation circuit centered on an 8-bit one-chip microcomputer incorporating a ROM that stores a game control program and a RAM that serves as a work area for operations and the like. An external input / output circuit for inputting / outputting with various actuators is also provided.
[0046]
On the input side of the main control board 30, a winning ball switch 79a, normal symbol operation switches 38a, 39a built in the normal symbol operation gates 38, 39, a continuation switch (V switch) 40a, a count switch 40b, a full switch 73, A replenishment switch 44 and winning ball switches 74a, 75a, 76a, 77a, 78a, etc. arranged in the ball tank 27 are connected.
[0047]
On the output side, a large winning opening solenoid 40c used for opening / closing the large winning opening 40, a V solenoid 40d used for opening / closing a special area in the large winning opening 40, and a normal electric accessory 36 are used. The normal-use solenoid 36b, the external connection terminal board 50, and the like to be connected are connected.
[0048]
The special symbol display device 32 includes the above-described LCD 32a, a symbol display device control board (hereinafter also simply referred to as “symbol control board”) 32b for driving and controlling the LCD 32a, and an accessory unit 32c such as a backlight and an inverter board. Has been. Similar to the main control board 30 described above, the symbol control board 32b is configured as a logic operation circuit centered on an 8-bit one-chip microcomputer.
[0049]
As with the main control board 30, the discharge control board 31 is configured as a logic operation circuit centered on an 8-bit one-chip microcomputer, and drives and controls the prize ball breaker 29c in accordance with a command command from the main control board 30. The game ball as a winning ball for the winning is paid out, and the ball lending / closing device 29d is driven and controlled according to the operation of the lending button 16 to discharge the game ball as a lending ball. The display of the balance display unit 18 of the CR adjustment display board 42 is also controlled. The prepaid card unit 13 is provided with the balance information of the prepaid card to the discharge control board 31, and the discharge control board 31 is transmitted to the prepaid card unit 13 with the rented discharge data and the payment signal from the payment button 17.
[0050]
A prize ball passage sensor 29e and a ball rental passage sensor 29f are connected to the input side of the discharge control board 31, and signals from these are input. The signals from the winning ball passage sensor 29e and the rental ball passage sensor 29f are also input to the main controller 30.
The launch control board 33 controls driving of the launch motor 33a according to the amount of rotation of the launch handle 24 (strictly speaking, the dial portion 24a) operated by the player, and the other player presses the launch stop switch 24b. When the touch switch 24c built in the firing handle 24 is on, the touch lamp 45 is turned on.
[0051]
The lamp control board 34 is mainly composed of driving elements such as transistors. Upon receiving a command from the main control board 30, the lamp control board 34 receives a normal symbol display device 37, lamps such as jackpot lamps and error lamps, and various lamps such as LEDs. It is intended to light up the display.
[0052]
The sound control board 35 includes a sound source IC, an amplifier, and the like, and is used to drive and control the speaker 46 in response to a command from the main control board 30.
Transmission to the special symbol display device 32, the discharge control board 31, the launch control board 33, the lamp control board 34, and the sound control board 35 described above is a one-way communication circuit so that transmission can be performed only from the main control board 30. It is configured. This one-way communication configuration can be implemented using an inverter circuit or a latch circuit.
[0053]
As shown in FIG. 7, various power sources are supplied to the main control board 30, the discharge control board 31, the design control board 32b, the launch control board 33, the lamp control board 34, the sound control board 35, and the like. ing.
The power supply board 55 is configured to generate a DC5V backup power supply from a 24V AC power supply using DC32V, DC12V, and a capacitor. And in each board | substrate, such as the main control board 30, the discharge control board 31, and the symbol control board 32b, DC5V for IC drive is produced | generated from the supplied DC12V power supply.
[0054]
Here, as shown in the figure, the DC 12 V power supplied from the power board 55 is connected to the reset (RES) terminal of the CPU 61 via the voltage monitoring circuit 60 of the main control board 30.
Similarly, the DC12V power supplied from the power supply board 55 is connected to the reset (XRES) terminal of the CPU 63 via the voltage monitoring circuit 62 of the discharge control board 31 and connected to the XNMI terminal of the CPU 63 via the backup voltage monitoring circuit 64. It is connected. The 5V backup power supply of the power supply circuit is connected to the backup terminal (VBB) of the CPU 63.
[0055]
Similarly, the DC12V power supplied from the power supply board 55 is connected to the reset (RES) terminal of the CPU 66 via the voltage monitoring circuit 65 of the symbol control board 32b.
As shown in FIG. 8, the voltage monitoring circuit 60 of the main control board 30 includes a voltage monitoring IC 11, resistors R17, R18 and R19, a bypass capacitor C10, and the like. The VSB terminal that is the input terminal of the voltage monitoring IC 11 is supplied with a DC12V power source divided by the resistors R17 and R18, and the RESET terminal that is the output terminal is pulled up to DC5V by the resistor R19. It is connected to the RES terminal which is an input terminal of the CPU 61.
[0056]
Although not shown, the voltage monitoring circuit 65 has the same configuration as the voltage monitoring circuit 60.
As shown in FIG. 9, the voltage monitoring circuit 62 of the discharge control board 31 includes a voltage monitoring IC 8, resistors R38, R39 and 40, bypass capacitors C22 and C23, and the like. The VS terminal that is the input terminal of the voltage monitoring IC 8 is supplied with a DC12V power source divided by the resistors R39 and R40, and the RESET terminal that is the output terminal is pulled up to DC5V by the resistor R38. The CPU 63 is connected to an XRES terminal that is an input terminal.
[0057]
The backup voltage monitoring circuit 64 includes a comparator IC1A, resistors R41 to R45, and the like. The negative input terminal of the comparator IC1A is supplied with a DC5V power source divided by resistors R43 and R44, and the positive input terminal is supplied with a DC12V power source divided by resistors R41 and R42 for output. The terminal is pulled up to DC5V by a resistor R45 and is connected to an XNMI terminal which is an input terminal of the CPU 63.
[0058]
With the above-described configuration, the operation start states of the CPUs of the main control board 30 when the power is supplied to the pachinko machine 10 and the sub-control boards other than the main control board such as the discharge control board 31 and the symbol control board 32b. A description will be given according to the timing chart shown in FIG.
[0059]
When the pachinko machine 10 is powered on, the power board 55 generates DC 32V, DC 12V, and DC 5V, which is a battery backup power source (VBB). The generated DC12V power is supplied to each control board as shown in FIG.
Here, as shown in FIG. 10, when the power is turned on (point P1), the voltage of the DC12V power supply gradually rises from 0V to 12V in a parabolic manner. When the voltage of the DC12V power supply that gradually rises to the reference value LV2, the outputs of the voltage monitoring circuit 62 of the discharge control board 31 and the voltage monitoring circuit 65 of the symbol control board 32b change from the low level to the high level, and the reset of the CPU 63 is released. The security check operation is started (point P2).
[0060]
When the power supply voltage of DC12V is the reference value LV2, the output of the voltage monitoring circuit 60 of the main control board 30 maintains a low level state.
When the power supply voltage of DC12V rises from the reference value LV2 to the reference value LV1, the output of the voltage monitoring circuit 60 changes from the low level to the high level, the reset of the CPU 61 is released, and the CPU 61 starts the security check operation (point P3).
[0061]
The security check time T1 of the CPU 61 of the main control board 30 is designed to be equal to or longer than the security check time T2 of each CPU of the sub control board such as the CPU 63 of the discharge control board 31 and the CPU 66 of the symbol control board 32b. ing.
[0062]
As is well known, security check is a one-chip microcomputer.CPUs 61, 63 and 66Is a function for checking whether or not the content of the ROM in which the game progress is written is normal.
The security check time T1 of the main control board 30 is equal to or longer than the security check time T2 of the sub-control board, and the security check operation of the CPU 61 of the main control board 30 is executed later than the security check operation of the sub-control board. Thus, when the CPU 61 of the main control board 30 starts executing the game control according to the program written in the ROM, each CPU of the sub-control board has already executed the game control. As a result, even if the CPU 61 of the main control board 30 transmits data to each sub-control board immediately after the power is turned on, each sub-control board is executing the original control, so that the data can be reliably received. .
[0063]
In this specific example, the security check time T1 is about 439 ms, and the time from when the CPU 61 of the main control board 30 executes power supply to the game control is about 529 ms to 549 ms. Further, the security check time T2 is about 200 ms, and the time from when the CPU 63 of the discharge control board 31 which is one of the sub-control boards is turned on to control the game is about 202 ms to 203 ms.
[0064]
Next, the operation when the power supply to the pachinko machine 10 is cut off will be described according to the timing chart shown in FIG.
When the power supply to the pachinko machine 10 is interrupted (point P6), the DC12V power supply voltage decreases substantially linearly after that, but then decreases substantially linearly and reaches 0V after a predetermined time. When the reference voltage LV1 is reached (point P7) in the course of gradually decreasing linearly (point P7), the output voltage of the voltage monitoring circuit 60 of the main control board 30 changes from high level to low level, and the CPU 61 is reset. Thereafter, as the time elapses, the power supply voltage of DC12V gradually decreases and reaches the reference voltage LV3 (point P8), and the output voltage of the backup voltage monitoring circuit 64 of the discharge control board 31 changes from the high level to the low level. As a result, the XNMI terminal of the CPU 63 of the discharge control board 31 becomes a low level, and a non-maskable interrupt is applied to the CPU 63.
[0065]
When the power supply voltage of DC12V further decreases from the reference voltage LV3 and reaches the reference voltage LV2 (point P9), the voltage of each sub control board such as the voltage monitoring circuit 62 of the discharge control board 31 and the voltage monitoring circuit 65 of the symbol control board 32b. The output voltage of the monitoring circuit changes from high level to low level. As a result, the CPU of each sub control board is brought into a reset state.
[0066]
Here, the RAM of the discharge control board 31 is backed up by a battery, and the data stored in the RAM is retained for a predetermined time (about 1 hour 20 minutes to about 3 hours 30 minutes in this specific example) even when the power is turned off. . Incidentally, as described above, the XNMI terminal is made valid before the CPU 63 of the discharge control board 31 is reset. As a result, the CPU 63 prohibits writing by prohibiting access to the RAM. Accordingly, the contents of the RAM in an unstable state that is in the reset state are not backed up by the battery, but the contents of the stable RAM before the reset can be backed up by the battery.
[0067]
As described above, when the power is turned off, the CPU 61 of the main control board 30 is first set to the reset state, and then each CPU of the sub control board is set to the reset state. Thereby, there is an effect that each sub control board receives the data transmitted before the CPU 61 of the main control board 30 is turned off.
[0068]
In this specific example, the reference voltage LV1 is 9.39V to 10.21V, the reference voltage LV3 is 8.00V to 9.23V, and the reference voltage LV2 is designed to be 7.20V to 7.75V. Has been.
The operation of this example having the above configuration will be described with reference to FIGS.
[0069]
When the process executed by the CPU 61 of the main control board 30 shifts to the “winning storage routine” shown in FIG. 12, it is first determined whether or not there is a winning (step S100). In this specific example, the ordinary electric accessory 36 serving as a starting port is configured as a winning port for five winning balls, the large winning port 40 is configured as 15 winning balls, and the other winning ports are configured as ten winning balls. The winning of the ordinary electric accessory 36 is detected by the winning ball switch 79a, the winning of the large winning opening 40 is detected by the continuation switch 40a and the count switch 40b, and the winning of the other winning holes is detected by the winning ball switches 74a to 78a. Is done.
[0070]
If an affirmative determination is made that there is a winning (step S100), the value of the unpaid winning number MMN is incremented (+1) (step S110), and then the winning order storing process is executed (step S120).
In the winning order storage process (step S120), as shown in the memory map of FIG. 13, the data for determining the number of winning balls using a 2-bit memory for a single winning on the 20-byte memory space is the data for winning a prize. Written in order. In this specific example, 01 (H) is awarded for a winning opening of five prize balls, 10 (H) is awarded for a winning opening of 10 prize balls, and 11 ( H) data is written. In this specific example, if 2 bits from the least significant bit are used in the order in which a winning is detected, data representing the number of winning balls for 4 winnings is written in 1 byte, and 1 byte memory is used. Are written in the memory of the next higher address. Which position in the memory space is to be written can be determined based on the incremented unpaid prize number MMN.
[0071]
When winning data is stored by the “winning storage routine”, a “winning transmission routine” shown in FIG. 14 is executed. The “winning storage routine” shown in FIG. 12 and the “winning transmission routine” shown in FIG. 14 are periodically executed by a hardware interrupt.
[0072]
In the “winning transmission routine” shown in FIG. 14, it is first determined whether or not the value of the unpaid winning number MMN is not zero (step S150). If the value of the unpaid prize MMM is not zero, a winning transmission process is executed (step S160). In this specific example, the 1-byte data at the address A000 (H) is transmitted as it is, that is, the data of the number of winning balls for four winnings is transmitted to the symbol control board 32b at a time. For example, even if the value of the unpaid prize MMM is 3 or less and 1 or more, 1-byte data is transmitted as it is.
[0073]
When the winning transmission process is executed, the value 4 is subtracted from the value of the unpaid prize number MMN (step S170), and it is determined whether or not the value of the unpaid prize number MMN subjected to the subtraction process is equal to or less than zero. (Step S180). If a negative determination is made that it is not less than zero, a storage update process is executed (step S190).
[0074]
The storage update process (step S190) is a process of repeatedly executing a process of copying 1-byte data with an address of 1 above to an address with an address of 1 up to an address where no data is written. Specifically, the data at address A001 (H) is at address A000 (H), the data at address A002 (H) is at address A001 (H), and the data at address A003 (H) is at address A002 (H). This is a process of copying one byte at a time, and repeatedly executing up to an address where data is not written.
[0075]
On the other hand, when an affirmative determination is made in step S180 that the value of the unpaid prize number MMN is zero or less, the value of the unpaid prize number MMN is cleared to zero (step S200), and addresses A000 (H) to A013. A process of clearing the memory up to (H) to zero (step S210) is executed.
[0076]
In this specific example, the winning transmission process (step S160) is configured to transmit 1-byte data by a single process, but the first and second bits which are the least significant bits of the address A000 (H). The 2-bit data may be transmitted by a single process. In the case of this configuration, the value of the unpaid prize MMM is decremented (−1) after the transmission process, and the storage update process shifts the data to the right by 2 bits, and the 7th bit and the most significant bit, 8 bits In the eye, the data of the first bit and the second bit which are one address higher are copied.
[0077]
When the CPU 63 of the discharge control board 31 determines that there is a transmission of winning data from the main control board 30 (step S250 (FIG. 15 “Received Data Storage Routine”)), a process of adding the unpaid winning number ZMN is executed. (Step S260).
In the addition process in step S260, if the transmitted 1-byte data is data representing the number of winnings for each of the four winnings, the number of unpaid winnings ZMN is +4, and the number of winnings for each of the three winnings is calculated. In the case of the data shown, the number of unpaid winnings ZMN is +3, and in the case of data representing the number of winnings for each of two winnings, the amount of unpaid winnings ZMN is +2, and the number of winnings for each winning is shown. In the case of data, this is a process of adding +1 to the unpaid prize number ZMN.
[0078]
When the unpaid prize amount ZMN is added (step S260), it is determined whether or not the unpaid prize number ZMN is memory over (step S270). In this specific example, the memory for storing the number of winnings is the same as the memory for storing the number of winnings of the main control board shown in FIG. Two bits of 01 (H), 10 (H) winning ball numbers and 11 (H) 15 winning ball winning balls are used. Therefore, each 20-byte memory can store the number of winning balls for each of 80 gaming balls.
[0079]
If it is determined that the memory is not over, a winning order storing process is executed (step S280). This process is a process of writing the number of winning balls corresponding to the winning in the memory, similar to the process of step S120 performed on the main control board 30, and is an unpaid value obtained by adding 1 to the unpaid winning number ZMN before being added. 01 (H), 10 (H), or 11 (H) data in the memory space corresponding to the unpaid winning number ZMN obtained by adding the winning numbers 1 to 4 transmitted from the memory space corresponding to the winning number ZMN. Is written. Whether the number of winnings is 1 to 4 based on the transmitted 1-byte data can be determined from 00 (H) from the most significant bit to which bit.
[0080]
If 1 to 4 winning numbers represented in the 1-byte data transmitted in step S250 correspond to memory over, the corresponding winning number is added to obtain a new over winning number OMN. Processing is executed (step S290).
[0081]
When the processing of step S280 and / or step S290 is executed, the addition processing of the number of prize balls M5D, MAD, and MED is executed (step S300). This process increments (+1) the number of winning balls M5D if there is 01 (H) data in the transmitted 1-byte data, and increments the number of winning balls MAD if there is 10 (H) data. , 11 (H), there is a process for incrementing the number of prize balls MED.
[0082]
By executing each process of the “reception data storage routine” shown in FIG. 15, the number of winning prizes for 15 prize balls to be paid out is the number of prize balls MED, the number of winning prize balls is the number of prize balls MAD, 5 The number of winning balls is stored as the number of winning balls M5D, and the order of winning for the 80 winning balls to be paid out is stored in the memories A000 to A013 (H).
[0083]
Here, in a case where 2-bit data, that is, data for one winning is transmitted by one transmission process, each process of the “reception data storage routine” shown in FIG. 16 (steps S310 to S390). ), The number of prizes for 15 prize balls to be paid out is memorized as the number of prize balls MED, the number of prizes for 10 prize balls is memorized as the number of prize balls MAD, and the number of prizes of 5 prize balls is memorized as the number of prize balls M5D. In addition, the winning order for the 80 winning balls to be paid out may be stored in the memory at addresses A000 (H) to A013 (H).
[0084]
Next, processing related to payout of prize balls will be described.
First, a process for determining whether or not to pay out a prize ball will be described.
In the pachinko machine 10 of this specific example, the payout stop process shown in FIG. 17 is periodically executed by a hardware interrupt by the CPU 61 of the main control board 30.
[0085]
In this process, the CPU 61 determines whether or not the full tank switch 73 is on (whether a full signal is inputted) (S710). If this is off, the rental ball passage sensor 29f is set for a set time (1 second in this embodiment). ) It is determined whether or not the game ball is continuously detected over the above (S720). If a negative determination is made in S720, a payout permission command command is transmitted to the discharge control board 31 (S730), and when the full switch 73 is ON or the rental ball passage sensor 29f continuously detects a game ball over a set time. If yes, a command command for disapproval of payout is transmitted to the discharge control board 31 (S740).
[0086]
Then, in the payout stop flag setting process shown in FIG. 18, when the discharge control board 31 receives a payout disapproval command command (S750), the discharge control board 31 sets the payout stop flag F1 to 1 (S760). When received (S770), the payout stop flag F1 is reset (S780). If neither command is received (S770: NO), the routine returns. That is, once a command command for disapproval of payout is received, the payout stop flag F1 = 1 is maintained until the next command command for permitting payout is received.
[0087]
Next, a process in which the CPU 63 of the discharge control board 31 drives and controls the prize ball cutting device 29c to pay out the prize ball will be described according to a “prize ball payout routine” shown in FIG.
In the winning ball payout routine, it is first determined whether or not the payout stop flag F1 = 1 (S400). If F = 1, the process returns from this routine without performing substantial processing.
[0088]
If F = 0, if the value of the unpaid winning number ZMN added by the processing of step S260 is not zero and the over-winning number OMN is zero (steps S410 to S420), the winning is not paid out yet. The number of winning balls is stored in the order of winning in the memories A000 (H) to A013 (H). In this case, the CPU 63 of the discharge control board 31 stores the data written in the first and second bits, which are the least significant bits of the address A000 (H), as 11 (H), 10 ( H) or 01 (H) is determined (step S430).
[0089]
If it is determined that the determination process is 11 (H), the prize ball breaker 29c is driven and controlled until it is detected by the prize ball passage sensor 29e that 15 game balls have been paid out (step S440). Thereafter, a process of decrementing (-1) the value of the prize ball number MED is executed (step S450). If it is determined as 10 (H) by the determination process, the prize ball disconnecting device 29c is driven and controlled until it is detected by the prize ball passing sensor 29e that ten game balls have been paid out (step S460). Thereafter, a process of decrementing (-1) the value of the prize ball number MAD is executed (step S470). If it is determined to be 01 (H) by the determination process, the prize ball passing device 29c is driven and controlled until it is detected by the prize ball passage sensor 29e that five game balls have been paid out (step S480). Thereafter, a process of decrementing (-1) the value of the number of prize balls M5D is executed (step S490).
[0090]
When the execution of the winning ball payout process is completed (steps S430 to S490), the winning order storage update is executed (step S500), and then the unpaid winning number ZMN is decremented (step S510). In the winning order storage update process (step S500), the 1-byte data at address A000 (H) is shifted to the right twice, that is, the written data is moved to the right by 2 bits. The data of the first bit and the second bit of address A001 (H) is moved to the eighth bit which is the most significant bit, and this process is repeated until an address where no data is written.
[0091]
On the other hand, when it is determined in step S420 that the over-winning number OMN is not zero, the number of winning ball data that has not been paid out has exceeded 80, and the winning ball for which the winning order is not stored. Is executed (step S520). This over winning ball payout processing will be described according to the “over winning ball payout processing” shown in FIG.
[0092]
In this process, the discharge control board 31CPU63First, whether the value of the prize ball number MED is zero (step S550), whether the value of the prize ball number MAD is zero (step S560), and whether the value of the prize ball number M5D is zero (step S570). ) Are successively executed.
[0093]
If the value of the number of prize balls MED is not zero (step S550), the value of the number of prize balls MED is decremented after paying out 15 game balls as prize balls (steps S580 to S590). If the value of the prize ball number MED is zero and the value of the prize ball number MAD is not zero (steps S550 to S560), the value of the prize ball number MAD is decremented after paying out 10 game balls as prize balls. (Steps S600 to S610). If the value of the prize ball number MED and the value of the prize ball number MAD are both zero and the value of the prize ball number M5D is not zero (steps S550 to S570), the prize is given after paying out five game balls as prize balls. The value of the number of balls M5D is decremented (steps S620 to S630).
[0094]
After executing any one of the steps S580 and S590, the steps S600 and S610, or the steps S620 and S630, the value of the over-winning number OMN is decremented (step S640), and the process returns to “return”. If it is determined in steps S550 to S570 that the values of the number of winning balls MED, MAD, and M5D are all zero, nothing is executed and the process returns to “return”.
[0095]
As described above, according to this specific example described in detail, the main control board 30 pays out when the full tank switch 73 is ON or the rental ball passage sensor 29f continuously detects a game ball over a set time. An unauthorized command command is transmitted to the discharge control board 31. Receiving this, the discharge control board 31 sets the payout stop flag F1 to 1, and keeps the payout stop flag F1 at 1 until receiving a payout permission command command. If the payout stop flag F1 = 1, no substantial processing is performed in the prize ball payout routine. That is, the payout of prize balls stops. That is, when the game balls are accumulated in the game ball guiding path 70 to the extent that the full tank switch 73 is turned on, the payout of the prize balls is stopped, so that the paid out game balls are placed in the game ball guiding path 70. There is no possibility of overfilling, and there is no possibility that such a game ball will rise and the prize ball interrupting device 29c or the ball lending device 29d will break down.
[0096]
Also, even when the ball lending sensor 29f continuously detects a game ball for a set time or longer, the payout of the award ball is stopped. Therefore, even if the full tank switch 73 is broken, for example, the award ball Can be prevented, and the failure of the prize ball breaker 29c and the ball rental breaker 29d can be prevented. Alternatively, when a ball is clogged in the vicinity of the upper plate guide rod 71 and a game ball cannot flow down to the lower plate guide rod 72 side, the payout of the prize ball is stopped, and the prize ball interrupting device 29c or the rental ball interrupting device. 29d failure can be prevented.
[0097]
The winning game balls (safe balls) are quickly discharged out of the machine without stopping in a tank or the like, so the safe balls are placed in the variable winning device (for example, the big prize opening 40) due to the delay in discharging the safe balls. There is no risk that it will rise to the point where it cannot be closed.
[0098]
When the lower plate 23 becomes full, it is only necessary to stop paying out the prize balls as described above, and it is not necessary to stop the launch of the game balls in order to prevent the occurrence of a new prize. It is no longer frequently stopped due to fullness, and it is also possible to avoid impairing the fun of the game.
[0099]
Further, the main control board 30 stores the number of winning balls in the order of winning, and transmits the stored winning data to the discharge control board 31. On the other hand, the discharge control board 31 stores the number of winning balls in the order of winning until the 20-byte memory is over, the winning balls cannot catch up or a lot of winnings occur at a time, and the 20-byte memory is stored. When over, only the number of winning balls is stored. Then, the winning balls are executed in order from the largest number of winning balls with respect to the memory over. As a result, in a normal state, the winning balls can be paid out in the order of winning, and during a transition in which the winning balls cannot catch up, the payout is executed with priority given to the winning balls having a large number of winning balls for the memory overrun. As a result, there is an excellent effect that the memory space for storing the winning order can be configured without increasing the size. In addition, since the battery backup function is installed in this specific example, even when the system recovers from a power failure, the prize balls can be paid out according to the stored data, and the prize balls can be paid out in the order of winning. It has the effect of being able to.
[0100]
Further, in this specific example, when the memory is over, a configuration is adopted in which the amount of memory over is paid out first and then paid out in accordance with the winning order. Even if the data is transmitted, it is only necessary to execute the writing process on the data after the winning ball process is performed, and there is an excellent effect that the storing process of the winning data is not complicated.
[0101]
In this specific example, since the winning data transmitted from the main control board 30 to the discharge control board 31 is configured to transmit 1-byte data at a time, transmission processing of the main control board 30 and reception of the discharge control board 31 are performed. There is also an excellent effect that the processing time can be shortened.
[0102]
In addition, in this specific example, in a state where the memory is not over, data indicating the number of winning balls is written in the winning order in the 20-byte memory space of addresses A000 (H) to A013 (H), and the number of winning balls Since the prize ball numbers M5D, MAD, and MED, which are data indicating the data, are incremented, some or all of the data written in the memory at addresses A000 (H) to A013 (H) for some reason disappears. Even so, the payout of prize balls can be effected according to the number of prize balls M5D, MAD, and MED, and there is an effect that no unexpected disadvantage is given to the player.
[0103]
When the memory is not over, the total number of prize balls indicated by the data written in the addresses A000 (H) to A013 (H) is compared with the total number of prize balls indicated by the prize ball numbers M5D, MAD, and MED. Therefore, it is possible to compare and determine whether or not there is an error in the total number of prize balls.
[0104]
In this specific example, a configuration is adopted in which data is transmitted in one direction from the main control board 30 to the discharge control board 31. However, when the power is turned on, the discharge control board 31CPU63 is earlier than the CPU 61 of the main control board 30. Since it is configured to stand up, even if there is a winning game ball immediately after returning from a power failure or the like, the data related to winning sent by the main control board 30 to the discharge control board 31 can be always received. Have.
[0105]
On the other hand, when the power is shut down due to a power failure or the like, the main control board 30 is stopped operating earlier than the discharge control board 31, so that the discharge control board 31 does not receive the data relating to the prize sent by the main control board 30. This has the effect of preventing the negative effect.
[0106]
In addition, the XNMI terminal becomes valid before the XRES terminal becomes valid and the CPU 63 of the discharge control board 31 stops its operation. At this time, the writing of data to the RAM can be prohibited, so that the power supply is unstable. This also has an extremely excellent effect that accurate winning data can be stored and retained in the event of a power failure without writing any data.
[0107]
In this specific example, the payout of the prize ball when the memory is over is configured to give priority to paying out a prize ball with a large number of prize balls. There is no problem.
Also, in this specific example, when returning from a power failure, it is configured to pay out the winning balls in the order of winning according to the stored data, but when returning from a power failure, priority is given to winning with a large number of winning balls, Alternatively, the payout may be made with priority given to winnings with a small number of prize balls.
[0108]
Further, in this specific example, until the memory is over, data indicating the number of winning balls is written in the memory in the order of winning, and the corresponding winning ball numbers M5D, MAD, and MED are incremented. There is no problem even if the winning ball numbers M5D, MAD, and MED are incremented only when the number is exceeded, and data indicating the number of winning balls is written in the memory in the order of winning when the memory is not over.
(Modification)
In the above example, the full tank switch 73 is installed near the downstream end of the lower plate guide rod 72, but this is almost the same level as the upper plate guide rod 71, that is, the level of the upper plate 15 as shown in FIG. If installed at almost the same level, the prize ball will not be stopped only when the lower plate 23 is full. Further, until the prize ball stops, a large amount of game balls can be accumulated on the upstream side of the lower plate 23, that is, until the lower plate guide rod 72 is filled, so that the player does not have to remove the ball from the lower plate 23 frequently. Well, you can concentrate on the game accordingly.
[0109]
Further, in the above example, since the rental ball passage sensor 29f is at a position lower than the prize ball passage sensor 29e (a position closer to the lower plate guide rod 72), the rental ball passage sensor 29f continuously detects the game ball. The payout of the prize ball is stopped when the game is in progress. However, when these levels are opposite or equivalent, the payout of the prize ball is stopped when the prize ball passing sensor 29e continuously detects the game ball. What is necessary is just to be the structure to do. Also by this, the same effect as the specific example can be obtained.
[0110]
Also in the arrangement of switches (sensors) for detecting a winning ball, as illustrated in FIG. 22, a plurality of winning holes having the same number of winning balls may be collectively detected by one switch 92, 93. In the example of FIG. 22, the winning ball is discharged out of the machine through the same route as the out ball flowing out from the out port 41 after being detected by the switches 40a, 40b, 91, 92, 93. This makes it possible to simplify the configuration of the bag etc.
[Brief description of the drawings]
FIG. 1 is an external perspective view showing a pachinko machine 10 employing the present invention.
FIG. 2 is a back view of the pachinko machine 10 as viewed from the back.
FIG. 3 is a cross-sectional view showing a structure of a discharge mechanism portion.
4 is a front view showing a configuration of a game board 22 of the pachinko machine 10. FIG.
FIG. 5 is an explanatory diagram of a mechanism related to detection and discharge of winning balls.
6 is a block diagram showing an electrical configuration of the pachinko machine 10. FIG.
7 is a block diagram showing a configuration for supplying power from a power supply board 55. FIG.
8 is a circuit diagram showing a configuration of a voltage monitoring circuit 60 of the main control board 30. FIG.
9 is a circuit diagram showing configurations of a voltage monitoring circuit 62 and a backup voltage monitoring circuit 64 of the discharge control board 31. FIG.
FIG. 10 is a timing chart showing the operating states of the CPU 61 of the main control board 30 and the CPUs of the sub control boards when power is turned on.
FIG. 11 is a timing chart showing operation states of the CPU 61 of the main control board 30 and the CPUs of the sub-control boards when power is turned off.
FIG. 12 is a flowchart showing processing of a “winning storage routine”.
FIG. 13 is a memory map showing a memory area for storing a winning order.
FIG. 14 is a flowchart showing processing of a “winning transmission routine”.
FIG. 15 is a flowchart showing processing of a “reception data storage routine”.
FIG. 16 is a flowchart showing processing of a “reception data storage routine”.
FIG. 17 is a flowchart of a “payout stop process”.
FIG. 18 is a flowchart of a “payout stop flag process”.
FIG. 19 is a flowchart showing processing of a “prize ball payout routine”.
FIG. 20 is a flowchart showing processing in “over prize ball payout processing”;
FIG. 21 is a cross-sectional view showing a structure of a discharge mechanism portion according to a modified example.
FIG. 22 is an explanatory diagram of a mechanism related to detection and discharge of winning balls according to a modified example.
[Explanation of symbols]
10 Pachinko machine (ball game machine)
15 Top plate
22 Game board
23 Lower plate
29 Discharge mechanism
29a Prize ball bowl (Prize ball dispensing device)
29b Ball rental basket (ball rental discharge device)
29c Prize ball breaker (prize ball dispensing device)
29e Prize ball passing sensor (prize ball detection means)
29f Ball rental sensor(Rental ball detection means)
29d Ball rental device (ball rental discharge device)
30 Main control board (prize ball stopping means)
31Emission control board
40a Continuation switch (winning detection means)
40b Count switch (winning detection means)
55Power supply board
62Voltage monitoring circuit
64Backup voltage monitoring circuit
70Game ball taxiway
71Top plate induction bowl
72Lower plate induction bowl
73Full switch
74a, 75a, 76a, 77a, 78a, 79a Winning ball switch (winning detection means)
82 winning ball discharge path

Claims (3)

A game board, a winning detection means for detecting a winning of a game ball, a prize ball payout device for paying out a game ball (prize ball) corresponding to the winning, and a prize ball paid out from the prize ball payout device Drive control of a prize ball guiding path that guides the player to the lower dish when the upper dish is filled with game balls, the main control board to which the winning detection means is connected, and the prize ball payout device. In a ball game machine comprising a discharge control board,
Prize ball data storage means for storing data related to a winning detected by the winning detection means;
Payout control means for controlling the payout device based on the data stored in the prize ball data storage means;
Memory holding means for storing and holding the data stored in the prize ball data storage means so as not to disappear during a power failure;
A winning ball discharge path for discharging the winning game ball to the outside without stagnation;
A full detection means arranged on the prize ball guide path to detect a full state in which the lower plate side is filled with game balls from the arrangement position;
Prize ball stopping means for stopping the payout of the prize ball when the full state is detected by the full detection means,
After the award ball stop means stops paying out the award ball, the full state detection means stops detecting the full state, the award ball stop means stops releasing the award ball , and the award ball data storage If there is unpaid prize ball data in the means, the payout control means executes award ball payout until the unpaid prize ball data becomes zero,
In addition,
The prize control data storage means, the payout control means and the memory holding means are provided on the discharge control board,
One power supply board for supplying power to the main control board and the discharge control board;
The main control board and the discharge control board are respectively provided with voltage monitoring circuits (60, 62) for monitoring the voltage of the same power supply (DC12V) generated and supplied from the one power supply board,
The main control board and the discharge control board are each reset by the voltage monitoring circuit (60, 62),
The power supply board generates and supplies the backup power used for the memory holding means ,
The main control board and the discharge control board are provided with a security check function executed when power is turned on,
The security check time T1 of the main control board is not less than the security check time T2 of the discharge control board,
The bullet ball game machine , wherein when the power is turned on and the security check operation of the main control board is finished, the security check operation of the discharge control board is already finished . In the bullet ball game machine according to claim 1,
The discharge control board includes a backup voltage monitoring circuit (64) for monitoring the voltage of the same power supply (DC12V) generated and supplied by the one power supply board monitored by each of the voltage monitoring circuits (60, 62).
Prohibiting the backup voltage monitoring circuit (64) from writing to the RAM of the discharge control board before being reset by the voltage monitoring circuit (62) of the discharge control board;
A ball game machine characterized by that. In the ball game machine according to claim 2,
The backup voltage monitoring circuit generates a voltage of the same power source (DC12V) monitored by the voltage monitoring circuit (60, 62) by a power source board having a voltage lower than the voltage of the power source (DC12V). Access to the RAM is prohibited before the discharge control board is reset by comparing with the voltage of another power source (DC5V) supplied to the RAM. .

Images