JP2004057295A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To accurately control the number of prize game media yet to be put out while reducing the cost of the game machines when a game control means and a put-out control means are installed separately while suspending games when normal prize game media fail to be put out. <P>SOLUTION: The put-out control means 371A comprises a communication abnormality detection means 371c for detecting the abnormalities pertaining to the communication of the signals between the game control means 56A and the put-out control means 371A and a shooting stop means 371d which performs a control to stop the operation of a shooting means 94A for shooting game balls when the communication abnormality detection means 371c detects any abnormality. A put-out command signal transmitting means 56d of the game control means 56A outputs the subsequent put-out command signal after the end of the processing of putting out the prize game media corresponding to the number thereof to be put out as designated by the put-out command signals when the number of the prize game media yet to be put out is stored into a number of prize game media memory means56b following the subtraction processing by a number of prize game media memory number subtraction means 56c. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention enables a player to play a predetermined game using a game medium, and pays out a prize game medium as a prize based on a payout condition established by the game, such as a pachinko game machine or a slot machine. Related to gaming machines.
[0002]
[Prior art]
As a gaming machine, a game medium such as a game ball is launched into a game area by a launching device, and when a game medium wins a winning area such as a winning opening provided in the game area, a predetermined number of prize balls are paid out to the player. There are things to be done. Further, a variable display unit whose display state can be changed is provided, and when a display result of the variable display unit is in a predetermined specific display mode, a predetermined game value is provided to the player. is there.
[0003]
In addition, the game value is a right to make the state of the variable prize ball device provided in the game area of the gaming machine advantageous for a player who is easy to win a hit ball, or to a state advantageous to the player. Or a condition that makes it easier to satisfy the conditions for paying out prize balls.
[0004]
In a pachinko gaming machine, when a display result of a variable display unit that displays a special symbol is a combination of predetermined specific display modes, it is generally referred to as a “big hit”. When a big hit occurs, for example, the big winning opening is opened a predetermined number of times, and the state shifts to a big hit game state in which a hit ball is easy to win.
[0005]
The game progress in the gaming machine is controlled by game control means such as a microcomputer. When the payout control means for controlling the prize ball payout is mounted on a payout control board different from the main board on which the game control means is mounted, the progress of the game is performed by the game control means mounted on the main board. Since it is controlled, the number of winning balls based on the winning is determined by the game control means, and a control signal indicating the number of winning balls is transmitted to the payout control board by one-way communication. Then, the payout control means performs a process of paying out a number of prize balls based on the winning based on a control signal from the game control means. On the other hand, the lending of the game medium is irrelevant to the progress of the game, and is generally controlled by the payout control means without passing through the game control means.
[0006]
[Problems to be solved by the invention]
When the communication of the control signal indicating the number of winning balls exchanged between the game control means and the payout control means is configured to be executed regardless of completion of the payout, the control indicating the number of winning balls is performed. Since the signal is transmitted to the payout control board by one-way communication, the payout control means may miss the signal or misrecognize the signal, and the payout ball may not be correctly paid out based on the winning. In the case where the RAMs of the game control means and the payout control means are respectively backed up with power, and information indicating the number of unpaid prize balls is stored in the RAM backed up even if the power supply to the gaming machine is stopped. May be configured to continue the process of paying out prize balls based on the information when the power supply is restored, but in such a case, the RAM in the game control means may be configured to continue. There is a possibility that the information indicating the number of unpaid prize balls stored and the information indicating the unpaid number of prize balls stored in the RAM of the payout control means may be different. Furthermore, since it is necessary to back up both the game control means and the payout control means, and to store information indicating the number of unpaid prize balls in both the game control means and the payout control means, There is also a problem that the cost of the gaming machine increases.
[0007]
If the information indicating the number of unpaid prize balls stored in the RAM in the game control means and the information indicating the unpaid number of prize balls stored in the RAM in the payout control means do not match, a normal prize is determined. Although it may not be possible to pay out the ball, it is difficult for the part that controls the emission of the game medium to recognize this. As a result, there is a problem that the game is continued even though the normal prize balls cannot be paid out.
[0008]
Therefore, the present invention can reliably manage the number of unpaid premium game media while reducing the cost of the gaming machine when the game control means and the payout control means are separately provided, An object of the present invention is to provide a gaming machine capable of interrupting a game when a normal premium game medium payout cannot be performed.
[0009]
[Means for Solving the Problems]
In the gaming machine according to the present invention, the player can play a predetermined game using the game medium fired in the game area, and the payout condition is satisfied by the game (for example, the game ball wins the winning area). A gaming machine for paying out a prize game medium as a prize based on the game machine; a game control means (for example, CPU 56 or the like) for controlling the progress of the game; and a firing means (for example, a firing motor) for firing the game medium toward a game area. 94, a payout means (for example, a ball payout device 97) for paying out premium game media, a payout control means (for example, a payout control CPU 371) for controlling the payout means, a game control means, and a payout control. Communication abnormality detection means for detecting an abnormality relating to signal communication with the means (for example, a part for detecting the turning off of the power supply confirmation signal in the payout control means or an incorrect timing A portion for detecting that the ball REQ signal has been turned off or on) and a firing stopping device for performing control for stopping the operation of the firing device when the communication error detecting device detects an error (for example, steps S512 and S518 in the payout control device) The game control means stores the premium game medium number data capable of specifying the total number of premium game media to be paid out based on the establishment of the payout condition, and the power supply to the gaming machine is controlled. Prize game medium number storage means (for example, a total prize ball number storage buffer in the RAM 55 backed up with a power supply) capable of storing the stored contents at least for a predetermined period when stopped, and payout control means based on the prize game medium number data A payout command signal (for example, a payout number signal) for designating the number of payouts of a predetermined number of premium game media to the payout Command signal transmitting means (for example, a portion of the game control means for executing the prize ball transmitting process in step S232) and a predetermined condition (for example, when the payout BUSY signal is turned on) after the payout command signal transmitting means transmits the payout command signal. That is, when the prize game medium data is subtracted from the prize game medium number data, the value corresponding to the payout number specified by the payout command signal is subtracted (for example, a prize ball waiting in step S233 in the game control means). The payout control means includes a volatile storage means (for example, a RAM) for storing data that fluctuates according to the control, and a prize designated by the payout command signal transmitting means in the game control means. The payout number of the game medium is stored in the volatile storage means, and the premium game medium of the payout number stored in the volatile storage means is paid out by the payout means. A prize game medium payout control means (for example, a part of the payout control means for executing the payout control processing of steps S546 and S756) for executing a payout processing for payout, and a payout command signal transmitting means in the game control means. When the prize game medium number data indicates that there is an unpaid prize game medium after the subtraction processing by the prize game medium number data subtracting means, the payout of the number of prize game media specified by the payout command signal is performed. After the processing is completed, the next payout command signal is output (for example, after executing the processing in step S265, it is confirmed in step S271 that the payout BUSY signal has been turned off, and then in step S247, the total number of winning balls is stored. The payout number signal is output in step S254 on condition that the content of the buffer is not 0). .
[0010]
Power supply monitoring means (for example, power supply monitoring) that monitors the state of a predetermined power supply used in the gaming machine and outputs a detection signal (for example, a power-off signal) when a detection condition relating to the stop of power supply to the gaming machine is satisfied Circuit 920), and the game control means shifts from a state in which the progress of the game is controlled to a state in which a power supply stop processing for saving the game state is executed in response to the input of the detection signal from the power supply monitoring means. (For example, the process proceeds from step S450 to step S452), and when the detection signal is turned off after executing the power supply stop process, the process returns to the state for controlling the progress of the game (for example, the process of steps S482 and S483). It may be constituted as follows.
[0011]
The power monitoring means is preferably mounted on a game control board (main board 31) provided with the game control means.
[0012]
The payout control means is a driving state monitoring means for monitoring the operation state of the payout means (for example, a part for executing the payout motor constant speed process of step S524 in the payout control means, in particular, the processing of the ball bite determination illustrated in FIG. 49). And a driving stop means for stopping the driving of the payout means when the drive state monitoring means detects a malfunction of the payout means (for example, a ball bite) (for example, a payout motor at the time of ball engagement in step S526 in the payout control means). (A part for executing a brake process).
[0013]
The payout control means includes payout detection means (for example, a payout count switch 301) for detecting a game medium paid out from the payout means and outputting a payout detection signal, and wherein the prize game medium payout control means outputs the payout detection signal from the payout detection means. Based on the payout detection signal, when it is detected that the number of prize game media paid out is less than the number of payouts stored in the volatile storage means despite the payout of the prize game media (for example, (Step S653), the payout means is allowed to execute the retry operation for paying out the prize game media for the shortage up to a predetermined number of times (for example, two times) (for example, the processing of steps S661 to S666). May be configured.
[0014]
One effect control means (for example, effect control CPU 101) for controlling a plurality of types of effect means (for example, the variable display device 9, the speaker 27, and the lamp / LED) provided in the gaming machine may be provided.
[0015]
The payout control means communicates with a recording medium processing device (for example, a card unit 50) for performing processing for converting a value specified by information recorded on a recording medium into a game use value that can be used for a game in a gaming machine. The payout control means and the recording medium processing device, wherein the payout control means is provided with a payout control board provided with a payout control means. Is preferably performed through a different relay board (for example, the interface board 66).
[0016]
The payout means has a function of paying out the lending game medium based on the lending request (for example, a function of executing the processing of steps S623 to S626 and the like), detecting the premium game medium paid out from the payout means, and detecting the lending game medium. The detection may be performed by the same payout detecting means (for example, the payout count switch 301).
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
First, the overall configuration of a pachinko gaming machine, which is an example of a gaming machine, will be described. FIG. 1 is a front view of the pachinko gaming machine as viewed from the front, and FIG. 2 is a front view showing the front of the gaming board. In the following embodiments, a pachinko gaming machine will be described as an example, but the gaming machine according to the present invention is not limited to a pachinko gaming machine, and can be applied to other gaming machines such as a slot machine.
[0018]
The pachinko gaming machine 1 includes an outer frame (not shown) formed in a vertically long rectangular shape, and a game frame attached to the inside of the outer frame so as to be openable and closable. Further, the pachinko gaming machine 1 has a glass door frame 2 formed in a frame shape and provided in a game frame so as to be openable and closable. The game frame includes a front frame (not shown) that can be freely opened and closed with respect to the outer frame, a mechanism plate to which mechanical components and the like are attached, and various components attached to them (excluding a game board described later). And a structure including:
[0019]
As shown in FIG. 1, the pachinko gaming machine 1 has a glass door frame 2 formed in a frame shape. On the lower surface of the glass door frame 2, there is a hit ball supply tray (upper tray) 3. A surplus ball receiving tray 4 for storing game balls that cannot be accommodated in the hit ball supply tray 3 and a hit ball operation handle (operation knob) 5 for firing game balls are provided below the hit ball supply tray 3. A game board 6 is detachably attached to the back of the glass door frame 2. The game board 6 is a structure that includes a plate-like body constituting the game board 6 and various components attached to the plate-like body. A game area 7 is formed on the front of the game board 6.
[0020]
In the vicinity of the center of the game area 7, a variable display device (special symbol display device) 9 including a plurality of variable display portions each of which variably displays a symbol as identification information is provided. The variable display device 9 has, for example, three variable display sections (symbol display areas) of “left”, “middle”, and “right”. Further, the variable display device 9 is provided with four special symbol start storage display areas (start storage display areas) 18 for displaying the number of effective winning balls in the start winning opening 14, that is, the number of start memories. Each time there is an effective start winning, the display color changes (for example, changes from blue display to red display) and the start storage display area is increased by one. Then, every time the variable display of the variable display device 9 is started, the start storage number display area in which the display color is changed is decreased by one (that is, the display color is returned to the original). In this example, since the symbol display area and the start storage display area are provided separately, it is possible to display the start storage number even during the variable display. The start storage display area may be provided in a part of the symbol display area. During the variable display, the display of the start storage number may be interrupted. In this example, the start storage display area is provided on the variable display device 9. However, a display (special symbol start storage display) for displaying the number of start storages may be provided separately from the variable display device 9. Good.
[0021]
Below the variable display device 9, a variable winning ball device 15 as a starting winning port 14 is provided. The winning ball that has entered the start winning port 14 is guided to the back of the game board 6, and is detected by the starting port switch 14a. In addition, a variable winning ball device 15 that performs opening and closing operations is provided below the starting winning port 14. The variable winning ball device 15 is opened by the solenoid 16.
[0022]
An opening / closing plate 20 that is opened by the solenoid 21 in a specific game state (big hit state) is provided below the variable winning ball device 15. The opening / closing plate 20 is a means for opening and closing the special winning opening. Of the prize balls guided from the open / close plate 20 to the back of the game board 6, one of the prize balls (V prize area: special area) that has entered is detected by the V prize switch 22, and the prize ball from the open / close plate 20 is a count switch. 23 is detected. On the back of the game board 6, there is also provided a solenoid 21A for switching the path inside the special winning opening.
[0023]
When a game ball is won at the gate 32 and detected by the gate switch 32a, variable display of the display of the ordinary symbol display 10 is started. In this embodiment, the variable display is performed by alternately lighting the left and right lamps (the symbols become visible when lit). For example, if the right lamp is lit at the end of the variable display, it is a hit. When the stop symbol on the ordinary symbol display 10 is a predetermined symbol (hit symbol), the variable winning ball device 15 is opened for a predetermined number of times and for a predetermined time. In the vicinity of the ordinary symbol display 10, an ordinary symbol start storage display 41 having a display unit of four LEDs for displaying the number of winning balls entering the gate 32 is provided. Each time there is a prize in the gate 32, the ordinary symbol start storage display 41 increases the number of lit LEDs by one. Then, every time the variable display of the ordinary symbol display 10 is started, the number of LEDs to be lit is reduced by one.
[0024]
The gaming board 6 is provided with a plurality of winning ports 29, 30, 33, 39, and winning of the gaming balls into the winning ports 29, 30, 33 is detected by the winning port switches 29a, 30a, 33a, 39a, respectively. You. Each of the winning ports 29, 30, 33, and 39 constitutes a winning area provided on the game board 6 as an area for accepting a game medium and allowing a winning. The start winning port 14 and the big winning port also constitute a winning area in which a game medium is accepted and a winning is allowed. At the left and right sides of the game area 7 are provided decorative lamps 25 which are displayed blinking during the game, and at the lower part there is an out port 26 for absorbing game balls which have not won. In addition, two speakers 27 that emit sound effects are provided at upper left and right sides of the game area 7. On the outer periphery of the game area 7, a top frame lamp 28a, a left frame lamp 28b, and a right frame lamp 28c are provided. Further, decorative LEDs are installed around each structure (such as a special winning opening) in the game area 7. The top frame lamp 28a, the left frame lamp 28b, the right frame lamp 28c, and the decorative LED are examples of a decorative illuminant provided in the gaming machine.
[0025]
In this example, a prize ball LED 51 is provided near the left frame lamp 28b, which is lit when there is a remaining prize ball, and near the top frame lamp 28a, the ball is lit when the supply ball runs out. An LED 52 is provided. As described above, the pachinko gaming machine 1 according to the present embodiment is provided with the lamps and the LEDs as light emitters at various places. Further, FIG. 1 also shows a prepaid card unit (hereinafter, referred to as a card unit) 50 which is installed adjacent to the pachinko gaming machine 1 and enables a lending of a ball by inserting a prepaid card.
[0026]
The card unit 50 has a usable indicator lamp 151 indicating whether or not the card unit 50 is in a usable state, a connecting stand direction indicator 153 indicating which side the pachinko gaming machine 1 corresponds to, and a card. A card insertion indicator lamp 154 for indicating that a card is inserted into the unit 50, a card insertion slot 155 for inserting a card as a recording medium, and a mechanism of a card reader / writer provided on the back surface of the card insertion slot 155. Is provided with a card unit lock 156 for releasing the card unit 50 when checking.
[0027]
A game ball fired from the hit ball firing device enters the game area 7 through the hit ball rail, and then descends from the game area 7. When the game ball enters the start winning opening 14 and is detected by the start opening switch 14a, the special display starts variable display (variation) on the variable display device 9 if the variable display of the symbol can be started. If it is not in a state where the variable display of the symbol can be started, the number of start storages is increased by one.
[0028]
The variable display of the special symbol on the variable display device 9 stops when a certain time has elapsed. If the combination of the special symbols at the time of stop is a big hit symbol (specific display result), the game shifts to the big hit gaming state. That is, the opening / closing plate 20 is opened until a predetermined time elapses or until a predetermined number (for example, 10) of game balls wins. When the game ball wins in the V winning area while the opening / closing plate 20 is open and is detected by the V winning switch 22, a continuation right is generated and the opening / closing plate 20 is opened again. Generation of the continuation right is permitted a predetermined number of times (for example, 15 rounds).
[0029]
If the combination of special symbols in the variable display device 9 at the time of stoppage is a combination of a big hit symbol (probably variable symbol) with a fluctuation in probability, the probability of the next big hit increases. That is, it is a more advantageous state for the player, which is a probable change state.
[0030]
When the game ball wins the gate 32, the ordinary symbol display device 10 enters a state where the ordinary symbol is variably displayed. When the stop symbol on the ordinary symbol display 10 is a predetermined symbol (hit symbol), the variable winning ball device 15 is opened for a predetermined time. Further, in the probable change state, the probability that the stop symbol in the ordinary symbol display 10 hits the symbol is increased, and the opening time and the number of times the variable winning ball device 15 is opened are increased. That is, the opening time and the number of times of opening of the variable winning ball device 15 are increased when the stop symbol of the ordinary symbol is a hit symbol, or when the stop symbol of the special symbol is a positive variation symbol, and the like, from the disadvantageous state for the player. Change to an advantageous state. It should be noted that increasing the number of times of opening is a concept including changing from a closed state to an open state.
[0031]
Next, the structure of the back surface of the pachinko gaming machine 1 will be described with reference to FIGS. FIG. 3 is a back view of the gaming machine viewed from the back. FIG. 4 is a rear view of the mechanism plate to which various members are attached as viewed from the rear side of the gaming machine.
[0032]
As shown in FIG. 3, on the back side of the gaming machine, a variable display control unit 49 including an effect control board 80 on which an effect control means for controlling the variable display device 9 is mounted, and a game on which a game control microcomputer and the like are mounted. A control board (main board) 31 is provided. A payout control board 37 on which a payout control microcomputer for performing ball payout control and the like are mounted. The effect control means includes a variable display device 9 provided on the game board 6, various decorative LEDs, a normal symbol start storage display 41, a decorative lamp 25, a top frame lamp 28a provided on the frame side, a left frame. The lighting control of the lamp 28b and the right frame lamp 28c and the generation of sound from the speaker 27 are controlled.
[0033]
The effect control means is realized by one effect control microcomputer mounted on the effect control board 80, but includes various decorative LEDs provided on the game board 6, a normal symbol start storage display 41, and a decorative lamp 25. A driving circuit for driving the top frame lamp 28a, the left frame lamp 28b, and the right frame lamp 28c provided on the frame side is mounted on a lamp driver board electrically connected to the effect control board 80. I have. A drive circuit for driving the speaker 27 and the like are mounted on a sound output board that is electrically connected to the effect control board 80.
[0034]
Further, a power supply board 910 and a touch sensor board 91 on which a power supply circuit for generating DC 30 V, DC 21 V, DC 12 V, and DC 5 V are provided. Most of the power supply substrate 910 overlaps with the main substrate 31, but there is an exposed portion that is visible from outside without overlapping with the main substrate 31. In this exposed portion, power supply to each electric component control board (main board 31, effect control board 80, payout control board 37) of the gaming machine 1 and each electric component provided in the gaming machine is executed or cut off. Switch 914 as a power supply permitting means for clearing backup data stored in a memory content holding means (for example, a backup RAM capable of holding the content even when power supply is stopped) included in the main board 31. Is provided with a clear switch 921 as an operation means.
[0035]
A terminal board 160 having terminals for outputting various information to the outside of the gaming machine is provided above the gaming machine on the rear side. The terminal board 160 has at least a ball-cutting terminal for introducing the output of the ball-cut detection switch 167 and externally outputting it, a prize-ball terminal for externally outputting prize-ball information (prize-ball count signal), and a ball. A ball lending terminal for externally outputting lending information (ball lending number signal) is provided. An information terminal board (information output board) 34 having terminals for outputting various information from the main board 31 to the outside of the gaming machine is provided near the center.
[0036]
The game balls stored in the storage tank 38 pass through the guide rail 39 and, as shown in FIG. 4, reach the ball payout device covered with the payout case 40A via the curve gutter 186. At the top of the ball payout device, a ball out switch 187 is provided as game medium out detecting means. When the ball-out switch 187 detects the ball-out, the payout operation of the ball payout device stops. The ball-out switch 187 is a switch for detecting the presence or absence of a game ball in the game ball passage. (A part close to). When the ball exhaustion detection switch 167 detects a shortage of game balls, the supply mechanism provided on the game machine installation island supplies the game machines with game balls.
[0037]
When a large number of game balls as a prize based on a prize or a game ball based on a ball lending request are paid out and the hit ball supply tray 3 becomes full, and finally, after the game ball reaches the contact port 45, another game ball is paid out. The game ball is guided to the surplus ball tray 4 via the surplus ball passage 46. Further, when the game balls are paid out, the sensing lever 47 presses the full tank switch 48 as the storage state detecting means, and the full tank switch 48 as the storage state detecting means is turned on. In this state, the rotation of the payout motor in the ball payout device stops, the operation of the ball payout device stops, and the driving of the hit ball firing device also stops.
[0038]
As shown in FIG. 4, on the side of the ball dispensing device, a ball removing passage 191 is formed from a curve gutter 186 to an outlet 192 at a lower portion of the gaming machine. A ball release lever 193 is provided at an upper portion of the ball release passage 191. When the ball release lever 193 is operated by a game clerk or the like, a game ball passage from the guide rail 39 to the ball release passage 191 is formed, and the storage tank 38 is provided. The game balls stored therein are discharged from the game machine through the discharge port 192.
[0039]
FIG. 5 is a front view (FIG. 5A) and a cross-sectional view (FIG. 5B) showing the ball dispensing device 97 covered with the dispensing case 40A. As shown in FIG. 4, the ball payout device 97 is fixed to a lower portion of a passage body 184 provided between the ball cutout switch 187 and the ball payout device 97. The passage body 184 has ball passages 188a and 188b through which two rows of game balls whose flow direction has been changed to the left and right directions by the curve gutter 186 flow down. A ball out switch 187 is provided upstream of the ball passages 188a and 188b. Note that, in practice, a ball out switch is provided in each of the ball passages 188a and 188b. The ball-out switch 187 detects the presence or absence of a game ball in the ball passages 188a and 188b. When the ball-out switch 187 stops detecting the game ball, a payout motor (shown in FIG. ) Is stopped and the payout of the game ball is immobilized.
[0040]
In addition, the ball cutout switch 187 is locked by a locking piece at a position where it can be detected that 27 to 28 game balls exist in the ball paths 188a and 188b.
[0041]
In the ball payout device 97, a payout motor (not shown) using a stepping motor pays out game balls based on a prize ball or a ball lending request one by one by rotating a cam, for example. In addition, below the ball payout device 97, a payout count switch 301 using, for example, a proximity switch is provided. Each time one game ball falls from the ball payout device 97, the payout count switch 301 is turned on. That is, the payout count switch 301 detects a game ball actually paid out from the ball payout device 97. Therefore, the payout control means can count the number of game balls actually paid out based on the detection signal of the payout count switch 301.
[0042]
FIG. 6 is an exploded perspective view showing a configuration example of the ball payout device 97. In this example, a ball payout device 97 is formed inside three cases 140, 141, and 142 as the payout case 40A. Holes 170 and 171 communicating with the ball passages 188a and 188b below the ball out switch 187 are provided in the upper portions of the cases 140 and 141, and the game balls flow into the ball payout device 97 from the holes 170 and 171.
[0043]
The ball payout device 97 includes a payout motor (for example, a stepping motor) 289 serving as a driving source. The rotational force of the payout motor 289 is transmitted to the gear 290 fitted on the rotation shaft of the payout motor 289, and further transmitted to the gear 291 that meshes with the gear 290. A cam 292 having a ball mounting portion is fitted on the central axis of the gear 291. The game balls flowing from the holes 170 and 171 are dropped one by one into the ball passage 293 below the cam 292 by the ball mounting portion of the cam 292.
[0044]
In the ball dispensing device 97, a dispensing motor position sensor 295 including a light emitting element (LED) and a light receiving element is provided. The payout motor position sensor 295 is a sensor for detecting the rotational position of the payout motor 289, and is used to detect that a game ball is clogged, that is, to detect a so-called ball bite.
[0045]
In this embodiment, the ball payout device 97 is configured to perform both the prize ball payout and the ball lending, but the ball payout device that performs the prize ball payout and the ball payout device that performs the ball lending are separate. May be provided. When provided separately, a payout means is constituted by a ball payout device for paying out a prize ball and a ball payout device for lending a ball. Further, for example, the rotation direction of the cam or sprocket may be changed to separate the winning ball payout and the ball lending, or the ball payout device 97 (the cam is rotated by a motor) exemplified in the present embodiment. The present invention can be applied to a ball dispensing device having any structure other than the configuration).
[0046]
FIG. 7 is a block diagram illustrating an example of a circuit configuration of the main board 31. FIG. 7 also shows a payout control board 37 and an effect control board 80. On the main board 31, a basic circuit 53 for controlling the pachinko gaming machine 1 according to a program, a gate switch 32a, a starting port switch 14a, a V winning switch 22, a count switch 23, winning port switches 29a, 30a, 33a, 39a, and Basically, a switch circuit 58 for giving a signal from the clear switch 921 to the basic circuit 53, a solenoid 16 for opening and closing the variable winning ball device 15, a solenoid 21 for opening and closing the opening and closing plate 20, and a solenoid 21A for switching a path in the special winning opening. A solenoid circuit 59 driven according to a command from the circuit 53 is mounted.
[0047]
The switches such as the gate switch 32a, the starting port switch 14a, the V winning switch 22, the count switch 23, the winning port switches 29a, 30a, 33a and 39a may be referred to as sensors. That is, any name can be used as long as it is a game medium detecting means (game ball detecting means in this example) capable of detecting a game ball. Each of the start port switch 14a, the count switch 23, and the prize port switches 29a, 30a, 33a, and 39a for detecting a prize is also a prize detecting means. The prize detecting means may be a means for detecting a plurality of game balls separately winning in a plurality of prize holes. In addition, even if it is a pass gate such as the gate switch 32a, as long as the payout of the prize ball is performed, the entry of the game ball to the pass gate becomes a prize, and the switch ( For example, the gate switch 32a) is a winning detecting means. Further, in this embodiment, the game ball that has won the V winning area is detected by the V winning switch 22 and also by the count switch 23, but may be detected only by the V winning switch 22. When the gaming balls that have won the V winning area are detected only by the V winning switch 22, the number of gaming balls that have won the large winning opening is the sum of the number detected by the V winning switch 22 and the number detected by the count switch 23. become.
[0048]
In addition, according to data provided from the basic circuit 53, jackpot information indicating occurrence of a jackpot, effective start information indicating the number of start winning balls used to start variable display of symbols on the variable display device 9, and occurrence of probability fluctuation. And an information output circuit 64 for outputting an information output signal such as probability change information indicating the above to an external device such as a hall computer.
[0049]
The basic circuit 53 includes a ROM 54 for storing a game control program and the like, a RAM 55 as storage means (variation data storage means for storing variation data) used as a work memory, a CPU 56 for performing a control operation according to the program, and an I / O. It includes a port section 57. In this embodiment, the ROM 54 and the RAM 55 are built in the CPU 56. That is, the CPU 56 is a one-chip microcomputer. The one-chip microcomputer only needs to have at least the RAM 55 therein, and the ROM 54 and the I / O port unit 57 may be external or internal. Since the CPU 56 executes control according to a program stored in the ROM 54, hereinafter, execution (or processing) by the CPU 56 means specifically that the CPU 56 executes control according to the program. is there. The same applies to the CPU mounted on a board other than the main board 31.
[0050]
The RAM (may be a CPU built-in RAM) 55 is a backup RAM partly or wholly backed up by a backup power supply created on the power supply board 910. That is, even if the power supply to the gaming machine is stopped, a part or all of the content of the RAM 55 is stored for a predetermined period. In particular, at least data corresponding to the game state, that is, the control state of the game control means, and data indicating the number of unpaid prize balls are stored in the backup RAM. Note that the data according to the control state of the game control means is data necessary for restoring the control state before the occurrence of a power failure or the like based on the data when the power is restored after a power failure or the like occurs. .
[0051]
The hitting ball firing device that hits and fires a game ball includes a firing motor 94 controlled by a circuit on the payout control board 37, and fires the game ball toward the game area 7 when the firing motor 94 rotates. A drive signal for driving the firing motor 94 is transmitted to the firing motor 94 via the touch sensor substrate 91. Then, the fact that the player is touching the operation knob (hitting handle) 5 is detected by the touch sensor, and a signal from the touch sensor is transmitted to the payout control board 37 via the touch sensor board 91. The circuit on the payout control board 37 stops driving the firing motor 94 when the signal from the touch sensor indicates the OFF state.
[0052]
In this embodiment, the effect control means mounted on the effect control board 80 controls the display of the ordinary symbol start storage display 41 and the decorative lamp 25 provided on the game board 6 and the frame side. The display control of the top frame lamp 28a, the left frame lamp 28b, and the right frame lamp 28c provided in the camera is performed. The effect control means mounted on the effect control board 80 also controls the display of the variable display device 9 for variably displaying special symbols and the ordinary symbol display 10 for variably displaying ordinary symbols.
[0053]
FIG. 8 is a block diagram showing components related to payout, such as the payout control board 37 and the ball payout device 97. As shown in FIG. 8, the payout control board 37 is equipped with a payout control CPU 371. In this embodiment, the payout control CPU 371 is a one-chip microcomputer, and has at least a built-in RAM. The RAM is not backed up, unlike the RAM 55 on the main board 31. The payout control CPU 371, the RAM, a ROM (not shown) storing the payout control program, an I / O port, and the like constitute payout control means.
[0054]
The detection signals from the full tank switch 48 and the payout count switch 301 are input to the I / O port 372f of the payout control board 37 via the relay board 72. Further, detection signals from the ball out switch 187 and the payout motor position sensor 295 are input to the I / O port 372 e of the payout control board 37 via the relay board 72. The payout control CPU 371 of the payout control board 37 executes the ball payout process when the detection signal from the ball out switch 187 indicates that the ball is out, or the detection signal from the full switch 48 indicates the full state. Stop. Further, if the detection signal from the full tank switch 48 indicates a full tank state, the ball firing from the hit ball firing device is stopped.
[0055]
When there is a prize, a prize ball REQ signal (prize ball request signal) for requesting a prize ball payout and a payout number signal indicating the number of prize balls to be paid out from the output circuit 67 of the main board 31 as a payout command signal. Is output. The number-of-payouts signal is composed of 4-bit data (binary 4-digit data) and is output by four signal lines. The number-of-payouts signal is input to the I / O port 372e via the input circuit 373A. When the payout control CPU 371 receives the prize ball REQ signal and the payout number signal via the I / O port 372e, it controls the ball payout device 97 to pay out the number of game balls indicated by the payout number signal. . The output circuit 67 of the main board 31 also outputs a power supply confirmation signal (connection confirmation signal) indicating that the main board 31 is connected. The prize ball REQ signal and the number-of-payouts signal correspond to a payout command signal that specifies the number of payouts.
[0056]
When the payout control means receives the payout command signal, the payout control means transmits a command reception signal to the main board 31. The command reception signal is transmitted to the main board 31 via the output port 372b of the payout control board 37 and the output circuit 373B. Then, on the main board 31, the data is input to the CPU 56 via the input circuit 68 and the I / O port 57. Further, when the payout control unit is executing the payout ball payout process, the payout control unit outputs the payout BUSY signal (prize ball payout signal) indicating that the payout process is being performed via the output port 372b and the output circuit 373B. ). In this embodiment, when the payout BUSY signal is turned on, the command reception signal is transmitted.
[0057]
The payout control CPU 371 transmits a prize ball information signal indicating the prize ball payout number and a ball lending number signal indicating the lending ball number to the terminal board (the frame external terminal board and the board external terminal board) via the output port 372b. (Included) 160. Although a driver circuit is provided outside the output port 372b, it is omitted in FIG. Further, door opening information switches 161A and 161B are connected to the terminal board 160 (frame external terminal board).
[0058]
In addition, the payout control CPU 371 outputs an error signal to the error display LED 374 using a 7-segment LED via the output port 372c. Further, a signal for instructing lighting / unlighting is output to the prize ball LED 51 and the ball out LED 52 via the output port 372b. Note that a detection signal from an error release switch 375 for releasing an error state is input to the input port 372f of the payout control board 37. The error release switch 375 is used to release an error state by software reset.
[0059]
Further, a drive signal from the payout control board 37 to the payout motor 289 is transmitted to the payout motor 289 in the payout mechanism of the ball payout device 97 via the output port 372a and the relay board 72. Note that a driver circuit (motor drive circuit) is provided outside the output port 372a, but is not shown in FIG. Further, a drive signal from the payout control board 37 to the firing motor 94 is transmitted to the firing motor 94 via the output port 372 a and the touch sensor board 91.
[0060]
The card unit 50 has a card unit control microcomputer mounted thereon. Further, the card unit 50 is provided with a usable indicator lamp 151, a connecting stand direction indicator 153, a card insertion indicator lamp 154, and a card insertion slot 155 (see FIG. 1). To the interface board (relay board) 66, a frequency display LED 60, a ball lending enable LED 61, a ball lending switch 62, and a return switch 63 provided near the hit ball supply tray 3 are connected.
[0061]
The card lending switch signal indicating that the ball lending switch 62 has been operated and the return switch signal indicating that the return switch 63 has been operated are given from the interface board 66 to the card unit 50 in accordance with the operation of the player. . Further, a card balance display signal indicating the balance of the prepaid card and a ball lending permission display signal are given from the card unit 50 to the interface board 66. Between the card unit 50 and the payout control board 37, a connection signal (VL signal), a unit operation signal (BRDY signal), a ball lending request signal (BRQ signal), a ball lending completion signal (EXS signal) and a pachinko machine operation signal ( PRDY signal) is transmitted and received via the input port 372f and the output port 372d. An interface board 66 is interposed between the card unit 50 and the payout control board 37. Therefore, signals such as a connection signal (VL signal) are transmitted and received between the card unit 50 and the payout control board 37 via the interface board 66 as shown in FIG.
[0062]
When the power of the pachinko gaming machine 1 is turned on, the payout control CPU 371 of the payout control board 37 outputs a PRDY signal to the card unit 50. When the power is turned on, the card unit control microcomputer outputs a VL signal. The payout control CPU 371 determines the connection state / non-connection state of the card unit 50 based on the input state of the VL signal. When the card is accepted in the card unit 50 and the ball lending switch is operated to input the ball lending switch signal, the microcomputer for controlling the card unit outputs a BRDY signal to the payout control board 37. When a predetermined delay time has elapsed from this point, the microcomputer for controlling the card unit outputs a BRQ signal to the payout control board 37.
[0063]
Then, the payout control CPU 371 of the payout control board 37 starts up the EXS signal to the card unit 50 and, when detecting the fall of the BRQ signal from the card unit 50, drives the payout motor 289 to dispense a predetermined number of loaned balls. Pay out to players. When the payout is completed, the payout control CPU 371 causes the EXS signal to the card unit 50 to fall. Thereafter, under the condition that the BRDY signal from the card unit 50 is not in the ON state, when a payout command signal is received from the game control means, prize ball payout control is executed. The power supply voltage AC24V used in the card unit 50 is supplied from the payout control board 37.
[0064]
The power supply from the power supply board 910 to the card unit 50 is performed via the payout control board 37 and the interface board 66. In this example, a fuse for protecting the card unit 50 is provided on a power supply line of 24 V AC for the card unit 50 provided in the interface board 66, and a voltage higher than a predetermined voltage is supplied to the card unit 50. Is prevented.
[0065]
In this embodiment, a case where the card unit 50 is installed separately from the gaming machine and adjacent to the gaming machine is described as an example, but the card unit 50 may be integrated with the gaming machine. . Also, the present invention can be applied to a case where a game ball corresponding to the amount of money is lent out in response to coin insertion.
[0066]
FIG. 9 is a block diagram illustrating a circuit configuration example of the effect control board 80, the lamp driver board 35, and the audio output board 70. In the effect control board 80, the effect control CPU 101 operates according to a program stored in a ROM (not shown), and according to a strobe signal (effect control INT signal) from the main board 31, an input driver 102 and an input port. An effect control command is received via 103. Further, the effect control CPU 101 controls the display of the variable display device 9 using the LCD via the output port 104 and the LCD drive circuit 106 based on the effect control command, and controls the output port 104 and the lamp drive circuit 107. The display control of the ordinary symbol display 10 is performed via the display.
[0067]
Furthermore, effect control CPU 101 outputs sound number data to audio output board 70 via output port 104 and output driver 110. Further, a bus (including an address bus, a data bus, and control signal lines such as write / read signals) for inputting and outputting to the effect control CPU 101 is extended to the lamp driver board 35 via the bus driver 105.
[0068]
In the lamp driver board 35, a bus that inputs and outputs to the effect control CPU 101 is connected to an output port 352 and an expansion port 353 via a bus receiver 351. The signal for driving each lamp output from the output port 352 is amplified by the lamp driver 354 and supplied to each lamp. The signal for driving each LED output from the output port 352 is amplified by the LED drive circuit 355 and supplied to each LED. The signal for driving the effect driving means 61 is amplified by the drive circuit 356 and supplied to each lamp.
[0069]
In this embodiment, the lamps / LEDs and the effect driving means provided in the gaming machine are controlled by effect control means including the effect CPU 101 mounted on the effect control board 80. Further, data for controlling the variable display device 9, the ordinary symbol display device 10, the lamp / LED, and the like are stored in the ROM. The effect CPU 101 controls the variable display device 9, the ordinary symbol display device 10, the lamp / LED, and the like based on the data stored in the ROM. Then, the lamp / LED and the effect driving means are driven via the output port 352 mounted on the lamp driver board 35 and each driving circuit. Therefore, when changing the model, if the effect control board 80 is replaced with a new model, the model change can be realized without replacing the lamp driver board 35.
[0070]
The effect control board 80, the lamp driver board 35, and the audio output board 70 are independent boards, and they are installed in a single box on the back of the gaming machine, for example. Further, the extension port 353 is installed in consideration of a case where the number of lamps, LEDs, and the like increases when the model is changed, but may not be installed. The drive circuit 356 may not be provided when there is no movable member for production. However, when the model is changed, the movable member for production is considered in consideration of the case where the movable member for production is installed. It is preferable that the member is provided even when no member or the like is present.
[0071]
In the sound output board 70, the sound number data from the effect control board 80 is input via the input driver 702 to a sound synthesis IC 703 using, for example, a digital signal processor. The voice synthesis IC 703 reads data corresponding to the sound number data from the voice data ROM 704, generates a voice or sound effect corresponding to the read data, and outputs the generated voice or sound effect to the amplifier circuit 705. The amplification circuit 705 outputs to the speaker 27 an audio signal obtained by amplifying the output level of the audio synthesis IC 703 to a level corresponding to the volume set by the volume 706.
[0072]
The data corresponding to the sound number data stored in the sound data ROM 704 is a collection of data indicating a sound effect or a sound output mode in a time series in a predetermined period (for example, a special symbol fluctuation period). Upon input of the sound number data, the voice synthesis IC 703 controls the sound output according to the corresponding data in the voice data ROM 704. The sound output control according to the corresponding data is continued until the next sound number data is input. Then, when the next sound number data is input, the voice synthesis IC 703 performs sound output control according to the data in the voice data ROM 704 corresponding to the newly input sound number data.
[0073]
In this embodiment, the sound and sound effect output from the speaker 27 are controlled by the effect control means including the effect control CPU 101. The effect control means outputs the sound number data to the sound output board 70. . In the sound output board 70, the sound data ROM 704 stores a large number of data for realizing sounds and sound effects that can appear as the game progresses, and these data are associated with sound number data. . Therefore, the effect control means can realize the sound output control only by outputting the sound number data. Note that the sound number data is, for example, 1-byte data, and is transferred to the sound output board 70 by a serial signal line or a parallel signal line.
[0074]
Next, the configuration of the power supply board 910 will be described with reference to the block diagrams of FIGS. FIG. 10 is a block diagram showing a DC voltage generation portion of power supply board 910. The power supply board 910 is provided with a power switch 914 for executing or interrupting power supply to each electric component control board and mechanical components in the gaming machine. Note that the power switch 914 may be provided outside the power board 910 in the gaming machine. When the power switch 914 is in the closed state (on state), AC power (24 VAC) is applied to the input side (primary side) of the transformer 911. The transformer 911 is to electrically insulate an AC power supply (AC 24 V) from the inside of the power supply board 910, and its output voltage is also AC 24V. A varistor 918 as an overvoltage protection circuit is provided on the input side of the transformer 911.
[0075]
The power supply board 910 is installed independently of the electric component control board (the main board 31, the payout control board 37, and the effect control board 80), and generates a voltage used by each electric component control board and mechanical components in the gaming machine. In this example, 24 V AC, VSL (DC + 30 V), VLP (DC + 24 V), VDD (DC + 12 V), and VCC (DC + 5 V) are generated. In addition, a capacitor 916 serving as a backup power supply (VBB), that is, a storage holding unit for holding the stored contents in the backup RAM, is charged from a line of DC + 5V (VCC), that is, a power supply for driving an IC or the like on each substrate. Further, a diode 917 for preventing backflow is inserted between the + 5V line and the backup + 5V (VBB) line. Note that VSL is generated by rectifying and boosting AC24V by a rectifying element in the rectifying / smoothing circuit 914. VSL serves as a solenoid drive power supply. VLP is a lamp lighting voltage, and is generated by rectifying 24 V AC by a rectifier in the rectifier circuit 912.
[0076]
The DC-DC converter 913 as power supply voltage generation means has one or a plurality of regulator ICs (two regulator ICs 924A and 924B are shown in FIG. 10), and generates VDD and VCC based on VSL. Relatively large capacitors 923A and 923B are connected to the input side of the regulator ICs (switching regulators) 924A and 924B. Therefore, when the supply of power to the gaming machine from the outside is stopped, the DC voltages such as VSL, VDD, and VCC decrease relatively slowly.
[0077]
As shown in FIG. 11, AC 24V output from the transformer 911 is supplied to the connector 922A as it is. Further, the VLP is supplied to the connector 922B via a fuse F01 as an overcurrent prevention unit for preventing supply of an overcurrent. A series body of an LED (LD01) and a resistor (R01) is connected between the connector 922B side of the fuse F01 and the ground (ground potential).
[0078]
VSL is supplied to the connector 922A via the fuse F02. A series body of the LED (LD02) and the resistor (R02) is connected between the connector 922A side of the fuse F02 and the ground. VSL is supplied to the connector 922B via the fuse F03. A series body of an LED (LD03) and a resistor (R03) is connected between the connector 922B side of the fuse F03 and the ground. Further, VSL is supplied to the connector 922C via the fuse F04. A series body of the LED (LD04) and the resistor (R04) is connected between the connector 922C side of the fuse F04 and the ground.
[0079]
VDD is supplied to the connector 922A via the fuse F05. A series body of the LED (LD05) and the resistor (R05) is connected between the connector 922A side of the fuse F05 and the ground. In addition, VDD is supplied to the connector 922B via the fuse F06. A series body of the LED (LD06) and the resistor (R06) is connected between the connector 922B side of the fuse F06 and the ground. Further, VDD is supplied to the connector 922C via the fuse F07. A series body of the LED (LD07) and the resistor (R07) is connected between the connector 922C side of the fuse F07 and the ground.
[0080]
VCC is supplied to the connector 922A via the fuse F08. A series body of the LED (LD08) and the resistor (R08) is connected between the connector 922A side of the fuse F08 and the ground. VCC is supplied to the connector 922B via the fuse F09. A series body of an LED (LD09) and a resistor (R09) is connected between the connector 922B side of the fuse F09 and the ground. Further, VCC is supplied to the connector 922C via the fuse F10. A series body of the LED (LD10) and the resistor (R10) is connected between the connector 922C side of the fuse F10 and the ground.
[0081]
The cable connected to the connector 922A is connected to the payout control board 37. The cable connected to the connector 922B is connected to the effect control board 80. Then, the cable connected to the connector 922C is connected to the main board 31. Therefore, VBB is also supplied to the connector 922C.
[0082]
Further, a clear switch 921 having a push button structure is mounted on the power supply board 910. When the clear switch 921 is pressed, a low level (on state) clear switch signal is output and transmitted to the main board 31 via the connector 922C. If the clear switch 921 is not pressed, a high-level (off state) signal is output. The clear switch 921 may have a configuration other than the push button structure. Further, the clear switch 921 may be provided in a gaming machine other than the power supply board 910.
[0083]
Further, the fuses F01 to F10 are not of a removable (replaceable) type but of a type fixed to the power supply board 910. That is, it is irreplaceably installed on the board (the power board 910 in this example). When the fuses F01 to F10 are of a replaceable type, the fuse is replaced when a failure such as a short-circuit failure occurs in the power supply board 910 or the electric component control board, and the true cause of the failure is unknown. There is a possibility that the gaming machine may be returned to the operating state without any change. In that case, the failure is expected to recur immediately. However, if the fuses F01 to F10 are of a non-replaceable type, when a failure occurs in the power supply board 910, an action to search for the true cause of the failure is induced.
[0084]
In the case where the LEDs (LD01 to LD10) as shown in FIG. 11 are provided on the power supply board 910, if no trouble such as a short-circuit failure occurs in the power supply board 910 and each electric component control board, Each LED (LD01 to LD10) is in a lighting state. In other words, when the LEDs (LD01 to LD10) are in the lighting state, it can be understood that no trouble such as a short-circuit failure has occurred in the power supply board 910 and each electric component control board.
[0085]
FIG. 12 is a block diagram showing the CPU 56, the reset circuit, and the power supply monitoring circuit on the main board 31. As shown in FIG. 12, a power-off signal from a power supply monitoring circuit (power supply monitoring means) 920, that is, a detection signal from the power supply monitoring means, is input to the CPU 56 via an inversion circuit 943 and an input port 572. Therefore, the CPU 56 can confirm the occurrence of the stop of the power supply to the gaming machine by monitoring the input signal of the input port 572.
[0086]
Since the power supply monitoring circuit 920 is mounted on the main board 31, the power supply monitoring means can be installed near the CPU 56 to which the power supply cutoff signal is input, so that the game control means can reliably recognize the stop of the power supply. Will be able to
[0087]
The power supply monitoring circuit 920 includes a power supply monitoring IC 902. The power supply monitoring IC 902 detects the occurrence of a power supply stop to the gaming machine by introducing the VSL voltage and monitoring the VSL voltage. Specifically, when the VSL voltage becomes equal to or lower than a predetermined value (+22 V in this example), a power-off signal is output on the assumption that power supply is stopped. The power supply voltage to be monitored is preferably higher than the power supply voltage (+5 V in this example) of the circuit element mounted on each electric component control board. In this example, VSL, which is a voltage immediately after conversion from AC to DC, is used.
[0088]
The predetermined value for the power supply monitoring IC 902 to detect the stop of the power supply is lower than the normal voltage, but is a voltage at which the CPU 56 can operate for a while. In addition, since the power supply monitoring IC 902 is higher than the voltage (+5 V in this example) for driving the circuit elements such as the CPU 56, the monitoring range can be expanded with respect to the voltage required by the CPU. Therefore, more precise monitoring can be performed. Further, when VSL (+30 V) is used as the monitoring voltage, since the voltage supplied to various switches of the gaming machine is +12 V, prevention of erroneous switch-on detection at the moment of a power interruption can be expected. That is, if the voltage of the +30 V power supply is monitored, it is possible to detect a decrease in the voltage of +12 V at a stage before +12 V generated after the generation of +30 V starts to fall.
[0089]
When the voltage of the + 12V power supply drops, the switch output becomes ON. However, if the + 30V power supply voltage which drops earlier than + 12V is monitored and the stop of the power supply is recognized and the switch output becomes ON, the switch output becomes ON. It is possible to enter a state of waiting for supply recovery and enter a state where the switch output is not detected.
[0090]
The reset circuit 65 includes a reset IC 651. The reset IC 651 sets the output to a low level for a predetermined time determined by the capacity of an external capacitor when the power is turned on, and sets the output to a high level after a predetermined time has elapsed. That is, the reset signal (system reset signal) is raised to a high level to put the CPU 56 into an operable state. Note that the reset signal is input to the reset terminal of the CPU 56 via the inverting circuits 942 and 941.
[0091]
In addition, the reset IC 651 monitors the power supply voltage of VSL, which is the same power supply voltage as the power supply voltage monitored by the power supply monitoring circuit 920, and determines that the voltage value is a predetermined value (below the power supply voltage value at which the power supply monitoring circuit outputs the power-off signal) When the value is lower than (low value), the output is set to low level. Therefore, the CPU 56 performs a predetermined power supply stop processing in response to the power-off signal from the power supply monitoring circuit 920, and then performs a system reset. That is, the operation is completely stopped. Therefore, the reset circuit 65 corresponds to a second power supply monitoring unit that outputs a detection signal at a timing later than the timing at which the power supply monitoring unit outputs the detection signal. In this example, the state in which the second power supply monitoring unit outputs the detection signal is a state in which the reset signal is set to low level.
[0092]
The CPU 56 used in this embodiment includes a non-maskable interrupt terminal (NMI terminal) used to generate a non-maskable interrupt (NMI), and an interrupt from outside the CPU 56 (external interrupt; mask). And an interrupt terminal (INT terminal) used to generate a possible interrupt. When the signal input to the NMI terminal falls to a low level, a non-maskable interrupt occurs. That is, the program counter of the CPU 56 is changed to the start address of the non-maskable interrupt processing, and the CPU 56 enters a state of executing the instruction set at the start address of the non-maskable interrupt processing.
[0093]
When the signal input to the INT terminal falls to a low level, an external interrupt occurs. That is, the program counter of the CPU 56 is changed to the start address of the external interrupt processing, and the CPU 56 enters a state of executing the instruction set at the start address of the external interrupt processing.
[0094]
In this embodiment, non-maskable interrupts and external interrupts are not used. Therefore, the NMI terminal and the INT terminal are pulled up to Vcc (+5 V) via a resistor. Therefore, the input levels of the NMI terminal and the INT terminal are always at the high level, and there is a possibility that the input levels of the NMI terminal and the INT terminal fall due to noise or the like and an interrupt occurs in comparison with the case where the terminal is in the open state. Reduce.
[0095]
FIG. 13 and FIG. 14 are explanatory diagrams showing examples of output port assignment in the game control means. As shown in FIG. 13, the output port 0 is an output port for a payout control signal transmitted to the payout control board 37 and a performance control INT signal (strobe signal) for a performance control command transmitted to the performance control board 80. . The 8-bit data of the effect control command transmitted to the effect control board 80 is output from the output port 1. The effect control INT signal is a signal for instructing the effect control means to take in the 8-bit data of the effect control command.
[0096]
A solenoid (large winning opening door solenoid) 21 for opening and closing the open / close plate 2 of the special winning opening, a solenoid (a large winning opening induction plate solenoid) 21A for switching a path in the special winning opening, and a variable from the output port 2. A drive signal for a solenoid (ordinary electric accessory solenoid) 16 for opening and closing the winning ball device 15 is output. The output port 3 outputs various information output signals to the information terminal board 34 and the terminal board 160 via the information output circuit 64, that is, output data of information related to control.
[0097]
FIG. 15 is an explanatory diagram showing an example of bit assignment of input ports in the game control means. As shown in FIG. 15, in bits 0 to 7 of the input port 0, the detection of the winning opening switches 33a, 24a, 29a, 30a, the starting opening switch 14a, the count switch 23, the V winning switch 22, and the gate switch 32a, respectively. A signal is input. In addition, the power off signal from the power supply monitoring circuit 920, the payout BUSY signal from the payout control board 37, and the detection signal of the clear switch 921 from the power supply board 910 are input to bits 0 to 2 of the input port 1, respectively. . The detection signal from each switch is logically inverted in the switch circuit 58.
[0098]
Next, the operation of the gaming machine will be described. FIG. 16 is a flowchart showing a main process executed by the game control means (the CPU 56 and peripheral circuits such as the ROM and the RAM) on the main board 31. When the power is turned on to the gaming machine and the input level of the reset terminal becomes high level, the CPU 56 executes a security check process for confirming whether or not the contents of the program are valid, and then executes step S1. Subsequent main processing is started. In the main processing, the CPU 56 first performs necessary initial settings.
[0099]
In the initial setting process, the CPU 56 first sets interrupt prohibition (step S1). Next, the interrupt mode is set to the interrupt mode 2 (step S2), and the stack pointer designated address is set to the stack pointer (step S3). Then, the internal device registers are initialized (step S4). After initializing a built-in device (built-in peripheral circuit) CTC (counter / timer) and PIO (parallel input / output port) (step S5), the RAM is set to an accessible state (step S6).
[0100]
The CPU 56 used in this embodiment also has an I / O port (PIO) and a timer / counter circuit (CTC). The CTC has two external clock / timer trigger inputs CLK / TRG2,3 and two timer outputs ZC / TO0,1.
[0101]
The CPU 56 used in this embodiment has the following three types of modes as maskable interrupt modes. When an interrupt that can be masked occurs, the CPU 56 automatically sets an interrupt disabled state and saves the contents of the program counter on the stack.
[0102]
Interrupt mode 0: The built-in device that has issued the interrupt request sends an RST instruction (1 byte) or a CALL instruction (3 bytes) onto the internal data bus of the CPU. Therefore, the CPU 56 executes the instruction at the address corresponding to the RST instruction or the address specified by the CALL instruction. Upon reset, the CPU 56 automatically enters the interrupt mode 0. Therefore, when it is desired to set the interrupt mode 1 or the interrupt mode 2, it is necessary to perform a process for setting the interrupt mode 1 or the interrupt mode 2 in the initial setting process.
[0103]
Interrupt mode 1: In this mode, when an interrupt is accepted, the operation always jumps to address 0038 (h).
[0104]
Interrupt mode 2: A mode in which the address synthesized from the value (1 byte) of the specific register (I register) of the CPU 56 and the interrupt vector (1 byte: least significant bit 0) output from the built-in device indicates an interrupt address. It is. That is, the interrupt address is an address indicated by 2 bytes in which the upper address is the value of the specific register and the lower address is the interrupt vector. Therefore, an interrupt process can be set at an arbitrary (although discrete) even address. Each built-in device has a function of transmitting an interrupt vector when making an interrupt request.
[0105]
Therefore, when the interrupt mode 2 is set, it is possible to easily process an interrupt request from each built-in device, and to set an interrupt process at an arbitrary position in a program. . Further, unlike the interrupt mode 1, it is easy to prepare an interrupt process for each interrupt occurrence factor. As described above, in this embodiment, the CPU 56 is set to the interrupt mode 2 in step S2 of the initial setting process.
[0106]
Next, the CPU 56 checks the state of the output signal of the clear switch 921 input via the input port 1 only once (step S7). When ON is detected in the confirmation, the CPU 56 executes a normal initialization process (steps S11 to S15). When the clear switch 921 is on (when pressed), a low-level clear switch signal is output. In the input port 1, the ON state of the clear switch signal is at a high level. In addition, for example, the game clerk can easily execute the initialization process by starting power supply to the game machine (for example, turning on the power switch 914) while turning on the clear switch 921. That is, the RAM can be cleared.
[0107]
If the clear switch 921 is not on, whether or not data protection processing of the backup RAM area (for example, processing for stopping power supply such as addition of parity data) has been performed when power supply to the gaming machine has been stopped. Confirm (step S8). In this embodiment, when the power supply is stopped, a process for protecting the data in the backup RAM area is performed. When confirming that such a protection process has been performed, the CPU 56 determines that there is a backup. When it is confirmed that such a protection process is not performed, the CPU 56 executes an initialization process.
[0108]
Whether or not there is backup data in the backup RAM area is confirmed by the state of the backup flag set in the backup RAM area in the power supply stop processing. For example, if "55H" is set in the backup flag area, it means that there is a backup (on state), and if a value other than "55H" is set, it means that there is no backup (off state).
[0109]
If it is determined that there is a backup, the CPU 56 checks the data in the backup RAM area (parity check in this example) (step S9). In this embodiment, clear data (00) is set in a checksum data area, and a checksum calculation start address is set in a pointer. Also, the number of checksum calculations corresponding to the number of data to be checked is set. Then, an exclusive OR of the contents of the checksum data area and the contents of the RAM area pointed to by the pointer is calculated. The calculation result is stored in the checksum data area, the value of the pointer is increased by one, and the value of the number of checksum calculations is decremented by one. The above process is repeated until the value of the number of checksum calculations becomes zero. When the value of the number of times of checksum calculation becomes 0, the CPU 56 inverts the value of each bit of the contents of the checksum data area, and uses the inverted data as a checksum.
[0110]
In the power supply stop processing, the checksum is calculated by the same processing as the above processing, and the checksum is stored in the backup RAM area. In step S9, the calculated checksum is compared with the stored checksum. If the power is restored after an unexpected power outage or other power supply interruption, the data in the backup RAM area should have been saved, and the check result (comparison result) becomes normal (match). If the check result is not normal, it means that the data in the backup RAM area is different from the data when the power supply is stopped. In such a case, since the internal state cannot be returned to the state at the time of stopping the power supply, the initialization processing (the processing of steps S10 to S15) executed when the power is turned on and not at the time of recovery from the stop of the power supply is performed. Execute.
[0111]
If the check result is normal, the CPU 56 performs a game state restoring process for returning the internal state of the game control means and the control state of the electric component control means such as the display control means to the state at the time of stopping the power supply. Specifically, the start address of the backup setting table stored in the ROM 54 is set as a pointer (step S81), and the contents of the backup setting table are sequentially set in a work area (an area in the RAM 55) (step S82). ). The work area is backed up by a backup power supply. In the backup setting table, initialization data is set for an area of the work area that may be initialized. As a result of the processing in steps S81 and S82, the saved contents of the work area that must not be initialized remain. The part that should not be initialized is, for example, a part in which data indicating a game state before the power supply is stopped (a special symbol process flag or the like) and data indicating the number of unpaid prize balls are set.
[0112]
The CPU 56 sets the start address of the backup command transmission table stored in the ROM 54 as a pointer (step S83), and supplies power to the sub-boards (payout control board 37 and effect control board 80) according to the contents. Control is performed so that a control command indicating that the recovery has been performed is transmitted (step S84). Then, control goes to a step S15.
[0113]
In the initialization process, the CPU 56 first performs a RAM clear process (step S11). It is to be noted that predetermined data (for example, data of a count value of a counter for generating a big hit random number) may be left as it is without initializing the entire area of the RAM. For example, when the data of the count value of the counter for generating the big hit determination random number is left as it is, the big hit determination random number is generated even if the initialization process is executed by an unauthorized means. It is difficult to aim for a timing at which the count value of the counter for the match is equal to the jackpot determination value. The start address of the initialization setting table stored in the ROM 54 is set as a pointer (step S11), and the contents of the initialization setting table are sequentially set in a work area (step S12). By the processes of steps S11 and S12, for example, a random number counter for normal symbol determination, a buffer for normal symbol determination, a special symbol left middle right symbol buffer, a total prize ball storage buffer, a special symbol process flag, a prize ball in-flight flag, a ball out of ball An initial value is set to a flag, such as a flag or a payout stop flag, for selectively performing a process according to the control state.
[0114]
The CPU 56 sets the pointer to the start address of the command transmission table at the time of initialization stored in the ROM 54 (step S13), and sends an initialization command for initializing the sub-board in accordance with the contents thereof to the sub-board. (Step S14). Examples of the initialization command include a command indicating an initial symbol displayed on the variable display device 9 and the like.
[0115]
Then, in step S15, the CPU 56 sets a register of the CTC built in the CPU 56 so that a timer interrupt is periodically performed, for example, every 2 ms. That is, a value corresponding to, for example, 2 ms is set in a predetermined register (time constant register) as an initial value. In this embodiment, it is assumed that a timer interrupt is periodically performed every 2 ms.
[0116]
When the execution of the initialization process (Steps S10 to S15) is completed, the display random number update process (Step S17) and the initial value random number update process (Step S18) are repeatedly executed in the main process. The CPU 56 disables the interrupt when the display random number update process and the initial value random number update process are executed (step S16), and interrupts the display random number update process and the initial value random number update process when the execution is completed. A permission state is set (step S19). The display random number is a random number for determining a symbol to be displayed on the variable display device 9. The display random number updating process is a process of updating the count value of a counter for generating a display random number. It is. The initial value random number updating process is a process of updating the count value of the counter for generating the initial value random number. The initial value random number is a random number for determining an initial value of a count value of a counter for generating a random number for determining whether or not to make a big hit (a big hit determining random number generation counter). In a game control process described later, when the count value of the big hit determination random number generation counter makes one round, an initial value is set in the counter.
[0117]
When the display random number update process and the initial value random number update process are executed, the interrupt prohibition state is set because the display random number update process and the initial value random number update process are also performed in a timer interrupt process described later. This is to avoid conflict with the processing in the timer interrupt processing because the processing is executed. That is, if a timer interrupt occurs during the processing of steps S17 and S18 and the count value of the counter for generating the display random number or the initial value random number is updated during the timer interrupt processing, The continuity of values may be lost. However, such an inconvenience does not occur if the interrupt is prohibited during the processing in steps S17 and S18.
[0118]
When a timer interrupt occurs, the CPU 56 executes a game control process of steps S20 to S33 shown in FIG. In the game control process, first, the CPU 56 executes a power-off detection process for detecting whether or not the power-off signal has been output (whether or not the power-on signal has been turned on) (step S20). Next, detection signals of switches such as the gate switch 32a, the starting port switch 14a, the count switch 23, and the winning port switches 29a, 30a, 33a, and 39a are input through the switch circuit 58, and their states are determined (switches). Processing: Step S21). Specifically, if the state of the input port for inputting the detection signal of each switch is the ON state, the value of the switch timer provided for each switch is incremented by one.
[0119]
Next, a process of updating the count value of each counter for generating each determination random number such as a big hit determination random number used for game control is performed (step S22). The CPU 56 further performs a process of updating the count value of the counter for generating the display random number and the initial value random number (steps S23 and S24).
[0120]
Further, the CPU 56 performs a special symbol process (step S25). In the special symbol process control, a corresponding process is selected and executed according to a special symbol process flag for controlling the pachinko gaming machine 1 in a predetermined order according to a gaming state. Then, the value of the special symbol process flag is updated during each processing according to the gaming state. Also, a normal symbol process is performed (step S26). In the normal symbol process process, a corresponding process is selected and executed according to a normal symbol process flag for controlling the display state of the normal symbol display 10 in a predetermined order. Then, the value of the normal symbol process flag is updated during each processing according to the gaming state.
[0121]
Next, the CPU 56 performs a process of setting an effect control command relating to the special symbol in a predetermined area of the RAM 55 and transmitting the effect control command (special symbol command control process: step S27). Further, a process of transmitting an effect control command by setting an effect control command relating to an ordinary symbol in a predetermined area of the RAM 55 is performed (ordinary symbol command control process: step S28).
[0122]
Further, the CPU 56 performs an information output process of outputting data such as big hit information, start information, and probability variation information supplied to the hall management computer (step S29).
[0123]
Further, the CPU 56 executes a prize ball process for setting the number of prize balls based on the detection signals of the winning opening switches 29a, 30a, 33a, 39a (step S30). More specifically, a payout control signal such as a payout number signal indicating the number of prize balls is output to the payout control board 37 in response to a winning detection based on the turning on of the winning opening switches 29a, 30a, 33a, 39a. The payout control CPU 371 mounted on the payout control board 37 drives the ball payout device 97 according to a payout control signal such as a payout number signal indicating the number of winning balls.
[0124]
Then, the CPU 56 executes a storage process for checking an increase or decrease in the number of stored start winnings (step S31). Further, a test terminal process for outputting a test signal for enabling the control state of the gaming machine to be confirmed outside the gaming machine is executed (step S32). Further, a RAM area (output port buffer) corresponding to the output state of the output port is provided, and the CPU 56 outputs the contents of the RAM area to the output port (step S33: output processing). Note that the contents of the output port buffer are updated by the processing of steps S25 to S30 and S31. Thereafter, an interrupt permission state is set (step S34), and the process ends.
[0125]
According to the above control, in this embodiment, the game control process is started periodically (for example, every 2 ms). In this embodiment, the game control process is executed in the timer interrupt process. However, in the timer interrupt process, for example, only a flag indicating that an interrupt has occurred is set. May be executed.
[0126]
FIGS. 18 and 19 are flowcharts illustrating an example of the power-off detection process in step S20. In the power-off detection process, the CPU 56 first confirms whether or not a power-off signal has been output (whether the power-off signal has been turned on) (step S450). If it is in the ON state, the power supply stop processing after step S452 is executed. That is, the state shifts from the state in which the progress of the game is controlled to the state in which the power supply stop process for storing the game state is executed.
[0127]
In the power supply stop processing, the CPU 56 stores the designated value with backup ("55H" in this example) in the backup flag (step S452). The backup flag is formed in the backup RAM area. Next, parity data is created (steps S453 to S461). That is, first, the clear data (00) is set in the checksum data area (step S453), and the checksum calculation start address is set in the pointer (step S454). Further, the number of checksum calculations is set (step S455).
[0128]
Next, the exclusive OR of the contents of the checksum data area and the contents of the RAM area pointed to by the pointer is calculated (step S456). The calculation result is stored in the checksum data area (step S457), the value of the pointer is increased by 1 (step S458), and the value of the number of checksum calculations is decremented by 1 (step S459). Then, the processing of steps S456 to S459 is repeated until the value of the number of checksum calculations becomes 0 (step S460).
[0129]
When the value of the number of times of checksum calculation becomes 0, the CPU 56 inverts the value of each bit of the contents of the checksum data area (step S461). Then, the inverted data is stored in the checksum data area (step S462). This data is the parity data that is checked when the power is turned on. Next, an access prohibition value is set in the RAM access register (step S471). Thereafter, the internal RAM 55 cannot be accessed.
[0130]
Further, the CPU 56 sets the head address of the port clear setting table stored in the ROM 54 as a pointer (step S472). In the port clear setting table, the number of processes (the number of output ports to be cleared) is set in the head address, and then the output port address and output value data (clear data: the value of each bit of the output port in the OFF state) Are sequentially set for output ports for the number of processes.
[0131]
The CPU 56 loads the data at the address indicated by the pointer (that is, the number of processes) (step S473). Further, the value of the pointer is incremented by 1 (step S474), and data at the address pointed to by the pointer (that is, the address of the output port) is loaded (step S475). Further, the value of the pointer is incremented by 1 (step S476), and data of the address pointed to by the pointer (that is, output value data) is loaded (step S477). Then, the output value data is output to the output port (step S478). Thereafter, the number of processes is reduced by 1 (step S479), and if the number of processes is not 0, the process returns to step S474. If the number of processes is 0, that is, if all output ports to be cleared are cleared, the timer interrupt is stopped (step S481), and a loop process is started.
[0132]
In the loop processing, it is monitored whether or not the power-off signal has been turned off (step S482). When the power-off signal is turned off, the power-on execution address (the address in step S1) is set as the return address, and the return instruction is executed (step S483).
[0133]
When the power supply is stopped by the above processing, the power supply stop processing of steps S452 to S481 is executed, and the data indicating that the power supply has been executed (the backup specified value and the checksum) are backed up. Stored in the RAM, the RAM access is disabled, the output port is cleared, and the timer interrupt for executing the game control process is set to the disabled state.
[0134]
If the power-off signal is turned off, the process returns to step S1. In this case, since the data indicating that the power supply has been executed is set, the game state restoring process of steps S81 to S84 is executed. Therefore, when the detection signal from the power supply monitoring unit is turned off after executing the power supply stop processing, the process returns to the state of controlling the progress of the game. Therefore, even if an instantaneous power interruption occurs, the game control process does not stop, and the game control process is automatically continued.
[0135]
Note that the power supply confirmation signal transmitted to the payout control board 37 is set to the off state by the process of clearing the output port. In the setting of the work area in steps 82 and S12, the content of the output port buffer corresponding to the power supply confirmation signal is set to a value corresponding to the ON state of the power supply confirmation signal. Then, when the output processing in step S33 is executed, the contents of the output port buffer are output to the output port, so that the power supply confirmation signal to the payout control board 37 is turned on. Therefore, the power supply confirmation signal is output (turned on) when the main board 31 rises. It should be noted that a power supply confirmation signal is also output when returning from an instantaneous power interruption or the like.
[0136]
Next, a specific example of the switch processing (step S21) in the main processing will be described. In this embodiment, when the ON state of the detection signal of each switch continues for a predetermined time, it is determined that the switch has been turned on, and the processing corresponding to the switch-on is started. A switch timer is used to measure a predetermined time. The switch timer is a 1-byte counter formed in the backup RAM area, and is incremented by 1 every 2 ms when the detection signal indicates the ON state. As shown in FIG. 20, switch timers are provided by the number n of detection signals. In the RAM 55, the addresses of the switch timers are arranged in the same order as the bit arrangement of the input ports.
[0137]
FIG. 21 is a flowchart showing a processing example of the switch processing in step S21 in the game control processing. In the switch processing, the CPU 56 first inputs data input to the input port 0 (step S101). Next, "8" is set as the number of processes (step S102), and the address of the switch timer for the winning opening switch 33a is set in the pointer (step S103). Then, a switch check processing subroutine is called (step S104).
[0138]
FIG. 22 is a flowchart showing a switch check processing subroutine. In the switch check processing subroutine, the CPU 56 sets the port input data, in this case, the input data from the input port 0 as a “comparison value” (step S121). Further, clear data (00) is set (step S122). Then, the switch timer indicated by the pointer (the address of the switch timer is set) is loaded (step S123), and the comparison value is shifted right (from the upper bit to the lower bit) (step S124). The data of the input port 0 is set as the comparison value. In this case, the detection signal of the winning opening switch 33a is pushed out by the carry flag.
[0139]
If the value of the carry flag is "1" (step S125), that is, if the detection signal of the winning opening switch 33a is on, the value of the switch timer is incremented by 1 (step S127). If the value after the addition is not 0, the added value is returned to the switch timer (steps S128 and S129). When the value after the addition becomes 0, the added value is not returned to the switch timer. That is, if the value of the switch timer has already reached the maximum value (255), the value is not increased further.
[0140]
If the value of the carry flag is "0", that is, if the detection signal of the winning opening switch 33a is in the OFF state, clear data is set in the switch timer (step S126). That is, if the switch is off, the value of the switch timer returns to 0.
[0141]
Thereafter, the CPU 56 increments the pointer (address of the switch timer) by 1 (step S130) and decrements the number of processes by 1 (step S131). If the number of processes has not become zero, the process returns to step S122. Then, the processing of steps S122 to S132 is repeated.
[0142]
The processes of steps S122 to S132 are repeated for the number of processes, that is, eight times. In the meantime, the process of checking whether the switch detection signal input to the 8 bits of the input port 0 is on or off is sequentially performed. If the operation is in the ON state, the value of the corresponding switch timer is increased by one.
[0143]
In this embodiment, since the game control process is started every 2 ms, the switch process is also executed once every 2 ms. Therefore, the switch timer is incremented by 1 every 2 ms.
[0144]
Next, a payout control signal transmitted and received between the main board 31 and the payout control board 37 will be described. FIG. 23 is an explanatory diagram showing an example of the contents of a control signal output from the game control means to the payout control means and a payout control signal input from the payout control means to the game control means. In this embodiment, a plurality of types of control signals are exchanged between the main board 31 and the payout control board 37 in order to perform various controls related to payout control and the like. As shown in FIG. 23, the power supply confirmation signal is output when the main board 31 rises, and is a signal for notifying the payout control board 37 that the main board 31 has risen (connection confirmation signal of the main board 31). It is. Further, as described above, the power supply confirmation signal is turned off when the power supply is detected, and is also used as a signal for notifying the payout control board 37 that the power supply is detected by the main board 31.
[0145]
The prize ball REQ signal goes to a low level (output state = on state) when a prize ball is paid out, and goes to a high level (stop state = off state) at the end of the payout request (that is, a trigger signal for a prize ball payout request). ). The prize ball REQ signal becomes high level (stop state) when forcibly stopping the prize ball payout, and is also used as a forced stop stop signal for instructing a prize ball payout forcible stop. The payout number signal is a signal output for designating the number (1 to 15) of game balls for which a payout request is made.
[0146]
The payout BUSY signal (prize ball payout signal) is a signal used for confirming the operation state of the main board 31 on the payout control board 37. It should be noted that each control signal only needs to be configured so that the output state or the ON state and the stop state or the OFF state can be distinguished, and the sign of the above logic may be reversed.
[0147]
FIG. 24 is a block diagram showing signal lines and the like used for transmission and reception of each control signal shown in FIG. As shown in FIG. 24, the power supply confirmation signal, the prize ball REQ signal, and the number-of-payouts signal are output by the CPU 56 via the output circuit 67 and input to the payout control CPU 371 via the input circuit 373A. The payout BUSY signal is output by the payout control CPU 371 via the output circuit 373B, and is input to the CPU 56 via the input circuit 68. The power supply confirmation signal, the prize ball REQ signal, and the payout BUSY signal are each 1-bit data, and are transmitted by one signal line. Since the number-of-payouts signal designates one to fifteen, the number-of-payouts signal is constituted by 4-bit data and transmitted by four signal lines.
[0148]
FIG. 25 is a flowchart showing an example of the prize ball processing in step S30. In the winning ball processing, the COU 56 executes a winning ball number adding process (step S201) and a winning ball control process (step S202).
[0149]
In the prize ball number addition processing, a prize ball number table shown in FIG. 26 is used. The prize ball number table is set in the ROM 54. The number of processes ("6" in this example) is set in the head address of the winning ball number table, and thereafter, a switch timer for each switch of the winning opening that pays out winning balls by winning (see FIG. 20). The lower address and the number of award balls are sequentially set in pairs.
[0150]
FIG. 27 is a flowchart showing the prize ball number adding process. In the prize ball number adding process, the CPU 56 sets the head address of the prize ball number table in the pointer (step S211). Then, data of the address pointed to by the pointer (the number of processes in this case) is loaded (step S212). Next, the upper address (8 bits) of the switch timer is set in the check pointer (step S213). The upper addresses of all the switch timers are the same.
[0151]
Then, the value of the pointer is incremented by 1 (step S214), and the address of the switch timer is obtained based on the data set in the check pointer and the data of the address pointed to by the pointer (lower address of the switch timer). The value of the switch timer is loaded (Step S215). The value loaded first is the value of the switch timer corresponding to the winning opening switch 33a (see FIG. 26). Here, the value of the pointer is incremented by 1 (step S216).
[0152]
Next, the CPU 56 compares the value of the loaded switch timer with the ON determination value (for example, “2”) (step S217). If the values match, the process proceeds to step S218, and if not, the process proceeds to step S222. Transition. The value of the switch timer is incremented by +1 when it is confirmed that the switch is turned on in the switch processing in step S21. Since the switch process is started every 2 ms, if the switch is continuously turned on for 4 ms, the value of the switch timer becomes “2”. That is, when the ON determination value is “2”, the value of the switch timer matches the ON determination value if the switch is ON continuously for 4 ms.
[0153]
In step S218, the data at the address pointed to by the pointer (in this case, the number of winning balls) is loaded, and the loaded value is set as the winning ball addition value. Further, the prize ball addition value is added to the content of the total prize ball storage buffer, which is a 16-bit RAM area (step S219). The buffer for storing the total number of prize balls is formed in the backup RAM. If a carry has occurred as a result of the addition, the content of the total prize balls storage buffer is set to 65535 (= FFFF (H)) (steps S220, S221).
[0154]
In step S221, the number of processes is reduced by 1. If the number of processes is 0, the process is terminated. If the number of processes is not 0, the process returns to step S214 (step S223).
[0155]
FIG. 28 is a flowchart showing the prize ball control processing in step S201. In the award ball control process, the CPU 56 executes any one of steps S231 to S234 according to the value of the award ball process code.
[0156]
FIG. 29 is a flowchart showing winning ball waiting processing 1 (step S231) executed when the value of the winning ball process code is 0. The CPU 56 checks whether or not the payout BUSY signal is in the ON state in the winning ball waiting process 1 (step S241). At this stage, the payout BUSY signal should not be in the ON state. If the payout BUSY signal is in the ON state, the abnormal state code is output and the process is terminated. The abnormal state code is an internal flag formed in the RAM 55.
[0157]
If the payout BUSY signal is off, the award ball REQ signal is turned off and the output of the payout number signal is cleared to 0 (steps S243 and S244). The process of step S243 is a process for turning off the prize ball REQ signal after the execution of the prize ball process 3 of step S234 is completed and the previous payout process is completed. Further, it is confirmed whether or not the award ball timer is 0 (step S245). If the prize ball timer is not 0, the value of the prize ball timer is reduced by 1 (step S246), and the process ends. The prize ball timer is a timer for measuring the time required in the prize ball processing. At this stage, the fact that the value of the prize ball timer is not 0 means that after the previous payout processing is completed, The waiting time until the REQ signal is turned on (time for providing an interval between the on-periods of a plurality of prize ball REQ signals when the prize ball payout is executed continuously) has not ended. Means
[0158]
If the value of the prize ball timer is 0, the CPU 56 checks the contents of the total prize ball storage buffer (step S247). If the value is 0, the process ends. If the value is not 0, the value of the winning ball process code is set to 1 (step S248), and the process ends.
[0159]
FIG. 30 is a flowchart showing a winning ball transmission process (step S232) executed when the value of the winning ball process code is 1. In the award ball transmission processing, the CPU 56 checks whether or not the content of the total award ball number storage buffer is smaller than the award ball command maximum value (“15” in this example) (step S251). If the content of the total winning ball count storage buffer is equal to or greater than the winning ball command maximum value, the winning ball command maximum value is set in the winning ball number buffer (step S252). If the content of the total prize ball storage buffer is smaller than the maximum prize ball command value, the content of the total prize ball storage buffer is set in the prize ball number buffer (step S253).
[0160]
Thereafter, a payout number signal designating the number of payouts set in the award ball number buffer is output (step S254), the award ball REQ is turned on (step S255), and the value of the award ball process code is set to 2. (Step S256), the process ends.
[0161]
In this embodiment, the maximum prize ball command value is “15”. Therefore, the payout number signal designating the payout number of “15” at the maximum is transmitted to the payout control board 37.
[0162]
FIG. 31 is a flowchart showing winning ball waiting processing 2 (step S233) executed when the value of the winning ball process code is 2. In the prize ball waiting process 2, the CPU 56 checks whether or not the payout BUSY signal output (turned on) by the payout control means in response to the prize ball REQ being turned on is turned on (step). S261). If not, the BUSY start determination time value is set in the award ball timer (step S262). The BUSY start determination time value is a value for the game control means to confirm that the payout BUSY signal has been output (turned on) when the payout BUSY signal has been on for the time indicated by the value.
[0163]
Therefore, when the payout BUSY signal is turned on, the CPU 56 checks the value of the prize ball timer (step S263). If the value is not 0, the CPU 56 reduces the value of the prize ball timer by 1 (step S264), and executes the process. finish. When the value of the prize ball timer becomes 0, it is determined that the payout BUSY signal is turned on, and the contents of the prize ball number buffer (the number of prize balls paid out to the payout control means) are determined from the contents of the total prize ball number storage buffer. Subtraction is performed (step S265). Then, the value of the prize ball process code is set to 3 (step S266), and the process ends.
[0164]
FIG. 32 is a flowchart showing winning ball waiting process 3 (step S234) executed when the value of the winning ball process code is 3. The CPU 56 checks whether or not the payout BUSY signal has been turned off in the prize ball waiting process 4 (step S271). If not, the BUSY end determination time value is set in the award ball timer (step S272). The BUSY end determination time value is a value for the game control means to confirm that the payout BUSY signal is no longer output (turned off) if the payout BUSY signal is kept off for the time indicated by the value. .
[0165]
Therefore, when the payout BUSY signal is turned off, the CPU 56 checks the value of the prize ball timer (step S273). If the value is not 0, the CPU 56 reduces the value of the prize ball timer by 1 (step S274). finish. When the value of the prize ball timer becomes 0, it is determined that the payout BUSY signal is turned off, and the prize ball REQ waiting time is set in the prize ball timer (step S275). Then, the value of the prize ball process code is set to 0 (step S276), and the process ends. As described above, the prize ball REQ waiting time is the waiting time until the next prize ball REQ signal is turned on (when the prize ball payout is executed continuously, the on period of a plurality of prize ball REQ signals). Time for providing an interval between the two).
[0166]
Through the above processing, the game control means stores the total number of game balls as prize balls to be paid out based on the establishment of the payout condition in the total prize ball number storage buffer so as to be identifiable. The total prize ball number storage buffer corresponds to a prize game medium number storage means for storing the storage contents at least for a predetermined period by a backup power supply as a variable data storage means when power supply to the gaming machine is stopped. Further, the game control means transmits a payout command signal for designating the number of payouts of a predetermined number of prize balls to the payout control means based on the number of prize balls stored in the total prize ball number storage buffer. Here, the predetermined number is 15 if the number of prize balls stored in the total prize ball number storage buffer is 15 or more, and if the number is less than 15, it is stored in the total prize ball number storage buffer. The number of award balls. Then, when the predetermined condition is satisfied, a subtraction process of subtracting the number of payouts specified by the payout command signal from the number of prize balls stored in the total prize ball storage buffer is performed.
[0167]
In this embodiment, the predetermined condition for executing the subtraction process is when a command reception signal is received from the payout control means, specifically, when the payout BUSY signal is turned on. When the payout BUSY signal is turned on, the payout control means has not yet paid out the prize balls of the number instructed by the payout command signal. If it is configured to perform the subtraction processing of the total prize ball storage buffer when the prize ball payout is completed, an improper act of illegally stopping the power supply of the gaming machine during the prize ball payout and then restoring the power supply. As a result, many prize balls are paid out illegally. For example, when the payout command signal instructs 15 payout balls to be paid out, when the 10 payout balls are paid out, if the power supply of the gaming machine is illegally stopped and then the power supply is restored, Since the content of the total prize ball storage buffer has not been subtracted at all, it is assumed that although ten prize balls have been actually paid out, the ten prize balls have not been paid out and the prize balls are not paid out. Control continues.
[0168]
However, in this embodiment, when the payout BUSY signal is turned on, that is, when the payout control means receives the payout command signal and transmits the command accepting signal, the subtraction processing of the total prize ball storage buffer is executed. Therefore, the above-mentioned misconduct can be prevented.
[0169]
In this embodiment, a prize game number storage buffer for storing the total number of prize game media as the prize game medium number storage means for storing the total number of prize game media to be paid out based on establishment of the payout condition is exemplified. However, the prize game medium number storage means, which stores the total number of prize game media so as to be identifiable, stores the number of prizes in each prize area or the number of prizes in each prize area having the same prize ball number (for example, 6 The winning number 14, which corresponds to the number of prize balls, the winning number 33, 39, 29, 30, which corresponds to the number of prize balls, and the number of winnings to the grand prize hole corresponding to the number of 15 prize balls, (The number of winnings for which the prize ball payout has not yet been completed) may be stored.
[0170]
FIG. 33 is a timing chart showing an example of the output state of the payout control signal. Here, 15 switches are detected by the switches for detecting the winning (for example, the switches 33a, 39a, 29a, 30a, the opening switch 14a, and the count switch 23) after 6 switches are detected. The case will be described. As described above, when a prize is detected, the number of prize balls according to the prize is added to the total prize ball storage buffer in the prize ball number adding process.
[0171]
As shown in FIG. 33, when six winnings are detected, the CPU 56 outputs a prize ball REQ signal based on the fact that the content of the total prize ball storage buffer is not 0 (on state: low). Level) and output the payout number signal indicating six (see steps S254 and S255). Upon receiving the prize ball REQ signal, the payout control CPU 371 turns on the payout BUSY signal indicating that the prize ball is being paid out, and drives the payout motor 289 to display the five payout number signals indicated by the payout number signal. The prize ball payout process is executed. When the payout processing of the six prize balls is completed, the payout control CPU 371 turns off the payout BUSY signal. The change of the payout BUSY signal from the on state to the off state also indicates that the payout completion signal has been turned on. Upon confirming that six prize balls have been paid out based on the payout completion signal, the CPU 56 sets the prize ball REQ signal to a stop state (off state: high level) and stops outputting the payout number signal. State (see steps S271, S243, S244).
[0172]
When the payout process based on the six winnings is completed, the CPU 56 sets the winning ball REQ signal to an output state based on the fact that the content of the total winning ball number storage buffer is not 0, and outputs a payout number signal indicating 15 balls. Set to output state. Upon receiving the prize ball REQ signal, the payout control CPU 371 turns on the payout BUSY signal indicating that the prize ball is being paid out, drives the payout motor 289, and outputs the 15 payout number signals indicated by the payout number signal. The prize ball payout process is executed. When the payout processing of the 15 prize balls is completed, the payout control CPU 371 turns off the payout BUSY signal. When confirming that 15 prize balls have been paid out based on the payout completion signal, the CPU 56 stops the prize ball REQ signal and stops outputting the payout number signal.
[0173]
In this embodiment, as shown in FIG. 33, the payout processing based on the 15 winnings generated later is waited until the payout processing based on the 6 winnings is completed. That is, when a plurality of winnings occur consecutively, the CPU 56 sends out the request for paying out the prize ball based on the subsequent winning until the payout of the winning ball based on the previous winning is confirmed by the payout completion signal. wait. In other words, the payout command signal transmitting means in the game control means, after the subtraction processing by the prize game medium number storage number subtraction means, the prize not paid out to the prize game medium number storage means (in this example, the total prize ball number storage buffer). When the number of game media is stored, the next payout command signal is output after the payout processing of the premium game media of the payout number specified by the payout command signal is completed.
[0174]
Next, the operation of the payout control means (payout control CPU 371 and peripheral circuits such as ROM and RAM) will be described. FIG. 34 is an explanatory diagram showing an example of output port assignment in the payout control means. As shown in FIG. 34, the output port 0 is an output port for outputting a signal of each phase supplied to the firing motor 94 by the stepping motor and a signal of each phase supplied to the payout motor 289 by the stepping motor. It is. The output port 1 is an output port for outputting the ball out LED 52, the prize ball LED 51, and the payout BUSY signal, and prize ball information, ball lending information, and a game machine error signal that are output to the outside of the gaming machine.
[0175]
The output port 2 is an output port for each segment output of the error display LED 374 using a 7-segment LED. The output port 3 is an output port for outputting an EXS signal and a PRDY signal to the card unit 50.
[0176]
FIG. 35 is an explanatory diagram showing an example of bit assignment of input ports in the payout control means. As shown in FIG. 35, a 4-bit payout number signal is input to bits 0 to 3 of input port 0, and a power supply confirmation signal (power cutoff signal) from power supply monitoring circuit 920 is input to bits 4 to 7, respectively. ), A prize ball REQ signal from the main board 31, a detection signal of the ball out switch 187, and a detection signal of the payout motor position sensor 295 are input. In addition, bits 0 to 4 of the input port 1 include a detection signal of the payout count switch 301, an operation signal from the error release switch 375, a signal from the single fire switch, a touch sensor signal from the touch sensor, and a full switch, respectively. Forty-eight detection signals are input. The VL signal, BRDY signal, and BRQ signal from the card unit 50 are input to bits 5 to 7 of the input port 1, respectively.
[0177]
FIG. 36 is a timing chart for explaining communication between the payout control means of the gaming machine and the card unit 50. The payout control means turns on the PRDY signal when the power supply to the gaming machine is started and the payout operation is possible. When power supply is started, the card unit 50 turns on a VL signal as a connection signal. When the card is accepted in the card unit 50 and the ball lending switch is operated to input the ball lending switch signal, the card unit 50 outputs a BRDY signal to the payout control means. That is, the BRDY signal is turned on. When a predetermined delay time has elapsed from this point, the card unit 50 outputs a BRQ signal to the payout control means. That is, the BRQ signal is turned on.
[0178]
Then, the payout control unit turns on the EXS signal to the card unit 50 and, when detecting the falling (OFF) of the BRQ signal from the card unit 50, drives the payout motor 289 and outputs a predetermined number (for example, 25). Pay out the rental ball to the player. When the payout is completed, the payout control means lowers the EXS signal to the card unit 50. That is, the EXS signal is turned off.
[0179]
Next, the operation of the payout control means will be described. FIG. 37 is a flowchart showing the main processing executed by the payout control means. In the main process, the payout control CPU 371 first performs necessary initial settings. That is, the payout control CPU 371 first sets interrupt prohibition (step S701). Next, the interrupt mode is set to the interrupt mode 2 (step S702), and the stack pointer designated address is set to the stack pointer (step S703). Further, the payout control CPU 371 initializes the built-in device register (step S704), initializes the CTC and PIO (step S705), and then sets the RAM in an accessible state (step S706).
[0180]
In this embodiment, one channel of the built-in CTC is used in the timer mode. Therefore, in the setting processing of the internal device register in step S704 and the processing in step S705, the register setting for setting the channel to be used to the timer mode, the register setting for permitting the interrupt generation, and the setting of the interrupt vector are set. Is set. Then, the interruption by the channel is used as a timer interruption. When a timer interrupt is to be generated every 2 ms, for example, a value corresponding to 2 ms is set in a predetermined register (time constant register) as an initial value.
[0181]
The interrupt vector set for the channel set in the timer mode (channel 3 in this embodiment) corresponds to the start address of the timer interrupt processing. Specifically, the start address of the timer interrupt processing is specified by the value set in the I register and the interrupt vector. In the timer interrupt process, a payout control process is executed.
[0182]
In this embodiment, the interrupt mode 2 is also set in the payout control CPU 371. Therefore, it is possible to use the interrupt processing based on the count-up of the built-in CTC. Further, it is possible to set an interrupt processing start address according to the interrupt vector transmitted by the CTC.
[0183]
The interrupt based on the count-up of the channel 3 (CH3) of the CTC is an interrupt that occurs when the internal clock (system clock) of the CPU is counted down and the register value becomes “0”, and is used as a timer interrupt. . Specifically, a clock obtained by dividing the operation clock of the CPU 371 is supplied to the CTC, the value of the register is subtracted by the input of the clock, and when the value of the register becomes 0, a timer interrupt occurs. For example, the register value of CH3 is subtracted in 1/256 cycle of the system clock. Since the subtraction is performed based on the divided clock, the initial value of the register does not increase.
[0184]
Next, the payout control CPU 371 executes a normal initialization process (steps S711 to S713). In the initialization process, the payout control CPU 371 first performs a RAM clear process (step S711). Further, an initial value is set in a flag, a counter, and the like in the RAM area. Then, the register of the CTC provided in the payout control CPU 371 is set so that the timer interrupt is periodically performed (step S712). That is, a value corresponding to the timer interrupt occurrence interval is set in a predetermined register (time constant register) as an initial value. Since the interrupt is prohibited in step S701 of the initial setting process, the interrupt is permitted before the initialization process is completed (step S713). Thereafter, a loop process is started.
[0185]
As described above, in this embodiment, the built-in CTC of the payout control CPU 371 is set to repeatedly generate a timer interrupt. When a timer interrupt occurs, a payout control process (steps S750 to S760) is executed in the timer interrupt process.
[0186]
In the payout control process, the payout control CPU 371 first performs an excitation pattern output process for the firing motor 94 (outputs the patterns of the firing motors φ1 to φ4 to the output port 0) (step S750). In the firing motor control process in step S752, the excitation pattern is stored in the excitation pattern buffer, which is a RAM area. In step S750, the payout control CPU 371 outputs the contents of the excitation pattern buffer to the lower 4 bits of the output port 0. Is performed.
[0187]
Next, the payout control CPU 371 executes a switch process (step S751). The switch processing is the same processing as the switch processing in the game control means. If the state of the input port for inputting the detection signal of each switch is on, the value of the switch timer provided corresponding to each switch is set. Is incremented by 1.
[0188]
Next, the payout control CPU 371 executes a firing motor control process (step S752). In the firing motor control process, the patterns of the firing motors φ1 to φ4 are stored in the excitation pattern buffer. When the firing motor 94 is to be deactivated, the patterns of the firing motors φ1 to φ4 that do not rotate the firing motor 94 are stored in the excitation pattern buffer. Further, the payout control CPU 371 executes a payout motor control process (step S753). In the payout motor control processing, when the payout motor 289 is to be driven, processing for outputting the pattern of the payout motors φ1 to φ4 to the output port 0 is performed. Then, a prepaid card unit control process for communicating with the card unit 50 is executed (step S754).
[0189]
Next, the payout control CPU 371 executes a main control communication process for communicating with the game control means of the main board 31 (step S755). Further, a payout control process is performed to control the payout of the lent balls in response to the ball lending request from the card unit 50, and to control the payout of the number of prize balls indicated by the number signal of the payout from the main board ( Step S756).
[0190]
Then, the payout control CPU 371 executes an error process for detecting various errors (step S757). Further, an information output process for outputting prize ball information and ball lending information output to the outside of the gaming machine is executed (step S758). In addition, a predetermined display is performed on the error display LED 374 according to the result of the error processing, and a display control process for turning on the prize ball LED 51 and the ball out LED 52 is executed (step S759). Note that the payout control CPU 371 performs control for turning on the prize ball LED 51 in the display control process when the prize ball REQ signal is on. Further, when the award ball REQ signal is turned off, control for turning off the award ball LED 51 is performed.
[0191]
As in the case of the game control means, a RAM area (output port buffer) corresponding to the output state of the output port is provided, and the payout control CPU 371 outputs the contents of the output port buffer to the output port. (Step S760: output processing). However, since the lower 4 bits of the output port 0 (the firing motors φ1 to φ4) have been executed in step S750, the lower 4 bits of the output port 0 are not output in the output processing. The output port buffer is updated in the payout motor control process (step S753), the prepaid card control process (step S754), the main control communication process (step S755), the information output process (step S758), and the display control process (step S759). You.
[0192]
FIG. 39 is a flowchart showing the firing motor control processing in step S752. In the firing motor control process, the payout control CPU 371 determines that the VL signal from the card unit 50 is off (the prepaid card is not connected) or that the power confirmation signal from the main board 31 is off (the main board is not connected). If the full switch 48 is ON (lower plate full), the process proceeds to step S518 (steps S511, S512, and S513). If the prepaid card is not connected, the main board is not connected, and the lower plate is not full, the flow shifts to step S514. In step S514, the payout control CPU 371 checks whether the touch sensor signal is in the ON state. If it is on, the process moves to step S515, and if it is not on, the process moves to step S518.
[0193]
In step S515, the payout control CPU 371 increments the firing motor excitation pattern counter by one. Then, data corresponding to the value of the excitation pattern counter is read from the firing motor excitation pattern table stored in the ROM (step S516). Further, the read data is set in the firing motor excitation pattern buffer (step S517). As described above, the contents of the firing motor excitation pattern buffer are output to the output port in step S750. In the firing motor excitation pattern table, data of the excitation patterns (the firing motors φ1 to φ4) of each step for rotating the firing motor 94 are sequentially set.
[0194]
In step S518, the non-rotated data (excitation pattern for preventing the firing motor 94 from rotating) is set in the firing motor excitation pattern buffer.
[0195]
As described above, when the communication error of the main board non-connection error occurs, the firing motor 94 is deactivated, so that the game does not proceed despite the occurrence of the communication error. In this embodiment, when a communication error of a main board non-connection error occurs, the firing motor 94 is deactivated and the game ball cannot be fired in the game area 7, but at an incorrect timing. The firing motor 94 may be deactivated even when an award ball REQ signal error occurs in which the award ball REQ signal is turned on or off.
[0196]
FIG. 40 is a flowchart showing the payout motor control processing in step S753. In the payout motor control process, the payout control CPU 371 executes any one of steps S521 to S526 according to the value of the payout motor control code.
[0197]
In the payout motor normal processing (step S521) executed when the value of the payout motor control code is 0, the payout control CPU 371 sets the pointer to the head address of the table stored in the ROM. The payout motor normal processing setting table stores a payout motor excitation pattern table in which data of excitation patterns (payout motors φ1 to φ4) for each step for rotating the payout motor 289 at the time of ball payout is sequentially set. I have.
[0198]
In the payout motor start preparation processing (step S522) executed when the value of the payout motor control code is 1, the payout control CPU 371 excites bits 4 to 7 of the output port buffer corresponding to the output state of the output port 0. Processing such as setting an initial value of the pattern is performed.
[0199]
In the payout motor slow-up process (step S523) executed when the value of the payout motor control code is 2, the payout control CPU 371 starts the rotation of the payout motor 289 more smoothly than in the case of the constant speed process. At a long interval and at a time interval gradually approaching the time interval in the case of the constant speed processing, the contents of the payout motor excitation pattern table are read out, and bits 4 to 4 of the output port buffer corresponding to the output state of the output port 0 are read. Set to 7. At the time of reading, the contents of the payout motor excitation pattern table at the address indicated by the pointer are read, and the value of the pointer is incremented by one.
[0200]
In the payout motor constant speed process (step S524) executed when the value of the payout motor control code is 3, the payout control CPU 371 periodically reads the contents of the payout motor excitation pattern table and outputs the output state of the output port 0. Are set in bits 4 to 7 of the output port buffer corresponding to.
[0201]
In the payout motor brake process (step S525) executed when the value of the payout motor control code is 4, the payout control CPU 371 makes the payoff motor 289 stop at a longer interval than in the case of the constant speed process in order to smoothly stop the payout motor 289. The contents of the payout motor excitation pattern table are read out at time intervals gradually moving away from the time interval in the case of the constant speed processing, and are read out to bits 4 to 7 of the output port buffer corresponding to the output state of the output port 0. Set.
[0202]
In the ball-meshing payout motor brake process (step S526) executed when the value of the payout motor control code is 5, the payout control CPU 371 smoothly controls the payout motor 289 in the case of rotation for releasing ball catching. At a longer interval than the rotation of the payout motor 289 for releasing the ball bite, and at a time interval gradually moving away from the time interval in the case of the constant speed processing. The contents of the table are read out and set in bits 4 to 7 of the output port buffer corresponding to the output state of output port 0.
[0203]
FIG. 41 is a flowchart showing the main control communication processing in step S755. In the main control communication process, the payout control CPU 371 executes any one of steps S531 to S533 according to the value of the main control communication control code.
[0204]
FIG. 42 is a flowchart showing main control communication normal processing (step S531) executed when the value of the main control communication control code is 0. In the main control communication normal process, when the error bit is on, the payout control CPU 371 ends the process without executing the subsequent processes (step S541). An error bit is a bit in an error flag that is set when it is detected that various errors have occurred. In step S541, if at least one bit in the error flag has been set, it is determined that the error bit has been set.
[0205]
If the BRDY signal is in the ON state, the payout control CPU 371 ends the process without executing the subsequent processes (step S542). The fact that the BRDY signal is in the ON state means that a ball lending request has been issued from the card unit 50. That is, when a ball lending request is issued, communication with the game control means of the main board 31 (communication related to award ball payout) does not proceed. Further, when the ball payout operation is being performed, that is, when the ball lending operation flag described later is set, the process is terminated without executing the subsequent processes (step S543). Therefore, even during the ball payout operation, communication with the game control means of the main board 31 (communication related to winning ball payout) does not proceed. If the power supply confirmation signal from the main board 31 is in the off state, the process ends without executing the subsequent processes (step S544).
[0206]
If the conditions of steps S541 to S543 are not satisfied and the power supply confirmation signal is on, the payout control CPU 371 checks whether the prize ball REQ signal is on (step S545). If the payout number signal is on, the number of prize balls indicated by the payout number signal is set in the unpaid number counter (step S546), and processing for turning the payout BUSY signal on is performed (step S547). Specifically, a bit corresponding to the payout BUSY signal in the output port buffer corresponding to the output state of the output port 1 is set to the ON state. Then, the value of the main control communication control code is set to 1 (step S548), and the process ends. The unpaid number counter is formed in a volatile (power supply is not backed up) RAM area.
[0207]
FIG. 43 is a flowchart showing main control communication processing (step S532) executed when the value of the main control communication control code is 1. In the processing during main control communication, the payout control CPU 371 sets the prize ball REQ signal error bit in the error flag when the prize ball REQ signal is in the off state (step S551) (step S552). This is because it is strange that the award ball REQ signal is immediately turned off at this stage.
[0208]
Next, the payout control CPU 371 performs a process for turning off the payout BUSY signal (step S547). Specifically, the bit corresponding to the payout BUSY signal in the output port buffer corresponding to the output state of the output port 1 is set to the off state. Also, the award ball REQ signal off monitoring time is set in the main control communication control timer (step S554). The main control communication control timer is a timer used for monitoring a time related to communication with the game control means of the main board 31. At this stage, the prize for monitoring the prize ball REQ signal is turned off. The ball REQ signal off monitoring time is set. Then, the value of the main control communication control code is set to 2 (step S555), and the process ends.
[0209]
FIG. 44 is a flowchart showing main control communication end processing (step S533) executed when the value of the main control communication control code is 2. In the main control communication processing, the payout control CPU 371 checks whether or not the prize ball REQ signal has been turned off (step S561). If it is turned off, the process moves to step S565. If not turned off, the value of the main control communication control timer is decremented by one (step S562). If the value of the main control communication control timer is 0 (step S563), it is determined that the award ball REQ signal has not been turned off, and the award ball REQ signal error bit of the error flag is set (step S564). The process moves to S565.
[0210]
In step S565, the value of the main control communication control code is set to 0 (step S565), and the process ends.
[0211]
FIG. 45 is a flowchart showing the payout control processing in step S756. In the payout control process, when the payout control CPU 371 confirms that the detection signal of the payout count switch 301 has been turned on, it decreases the value of the unpaid number counter by one. Thereafter, any one of steps S610 to S612 is executed according to the value of the payout control code.
[0212]
FIG. 46 is a flowchart showing a payout start waiting process (step S610) executed when the payout control code is 0. In the payout start waiting process, if the error bit is set, the payout control CPU 371 does not execute the subsequent processes (step S621). If the BRDY signal is not in the ON state, the process for paying out the winning ball from step S631 is executed. If the BRDY signal is on and the BRQ signal, which is the ball lending request signal, is on, the ball lending operation flag is set (steps S623 and S624). Then, "25" is set in the unpaid number counter (step S625), and "25" is set in the unpaid number counter in the payout motor rotation number buffer (step S626).
[0213]
The payout motor rotation frequency buffer is referred to in the payout motor control processing (step S723). That is, in the payout motor control process, control is performed to rotate the payout motor 289 by the number of rotations corresponding to the value set in the payout motor rotation frequency buffer.
[0214]
Thereafter, the payout control CPU 371 sets the value (specifically, “1”) corresponding to the payout motor activation preparation process (step S522) in the payout motor control code for selecting the process to be executed in the payout motor control process. It is set (step S634), the value of the payout control code is set to 1 (step S635), and the process ends.
[0215]
In step S631, the payout control CPU 371 checks whether or not the value of the unpaid number counter is 0 (step S631). If it is 0, the process ends. A non-zero value (the number indicated by the number-of-payouts signal) is set in the unpaid-number counter in step S546 in the main control communication normal process, that is, when the prize ball REQ signal is received from the game control means of the main board 31. Have been. Therefore, when the value of the unpaid number counter is not 0, the winning ball operation flag is set (step S632), and the value of the unpaid number counter is set in the payout motor rotation number buffer (step S633). Then, control goes to a step S634.
[0216]
FIG. 47 is a flowchart showing the payout motor stop waiting process (step S611) executed when the payout control code is 1. In the payout motor stop waiting process, the payout control CPU 371 checks whether or not the payout operation has been completed (step S641). For example, the payout control CPU 371 sets a flag to that effect when the payout motor brake process (step S525) in the payout motor control process ends, and confirms the flag in step S641 to determine whether the payout operation has ended. Can be confirmed.
[0219]
When the payout operation is completed, the payout control CPU 371 sets the payout passage monitoring time to the payout control monitoring timer (step S642). The payout passage monitoring time is a time period from when the last payout ball is paid out by the payout motor 289 to when it passes through the payout count switch 301. Then, the value of the payout control code is set to 2 (step S643), and the process ends.
[0218]
FIG. 48 is a flowchart showing a payout passage waiting process (step S612) executed when the value of the payout control code is 2. In the payout passage waiting process, the payout control CPU 371 first decrements the value of the payout control timer by one (step S651). Then, the value of the payout control timer is checked, and if the value is not 0, that is, if the payout control timer has not timed out, the process is terminated.
[0219]
If the payout control timer has timed out, the value of the unpaid number counter is checked (step S653). If the payout operation is executed normally, all the game balls paid out by the payout motor 289 pass through the payout count switch 301 before the payout control timer times out, and the unpaid number counter is processed by the processing of steps S601 and S602. Is 0. When the value of the unpaid number counter indicates a positive value, it means that the number of game balls actually paid out is smaller than the expected payout number (payout shortage). If the value of the unpaid number counter indicates a negative value, it means that the number of game balls actually paid out is larger than the expected payout number (excessive payout).
[0220]
When the value of the number-of-payout counter is not a positive value (when the payout is not insufficient), the payout control CPU 371 changes the internal state indicating that the payout process is being performed to a state other than that. Specifically, when the ball lending operation is being executed, that is, when the ball lending operation flag is set, the ball lending operation flag is reset (steps S654 and S655). If the award ball operation is being executed, that is, if the award ball operation flag is set, the award ball operation flag is reset (steps S654 and S656). Thereafter, the re-payout operation counter is cleared (step S667), the value of the payout control code is set to 0 (step S658), and the process ends. Note that if the payout operation is normally executed, the process of step S657 is unnecessary, but after the corrected payout process described later is executed, the process of step S657 is required. Further, in this embodiment, it is considered that the payout process has been completed normally even in the case of overpayment. However, in the case of overpayment, it may be notified that an error has occurred and that the payout process has ended.
[0221]
When it is confirmed in step S653 that the value of the unpaid number counter is a positive value, the payout control CPU 371 performs control for the corrected payout process in steps S661 to S666. Here, a maximum of two re-payout operations are performed until the required number of game balls are paid out. If the number of game balls to be paid out is not paid out even after performing the re-payout operation twice, an error bit is set.
[0222]
The payout control CPU 371 checks whether or not the value of the re-payout operation counter is 2 in step S661. If it is not 2, the value of the unpaid number counter is set in the payout motor rotation number buffer (step S662), and a value ("1") corresponding to the payout motor start preparation processing is set in the payout motor control code (step S662). Step S663). Further, the value of the re-payout operation counter is incremented by 1 (step S664), the value of the payout control code is set to 1 (step S665), and the process ends. The processing of steps S662, S663, and S665 is the same as the processing of steps S633 to S635 in the payout start wait processing, although the value set in the payout motor rotation count buffer is different.
[0223]
In step S661, if it is confirmed that the value of the re-payout operation counter is 2, the payout control CPU 371 sets the payout count switch non-passing error bit (payout case error bit) among the error flags ( Step S666), the process ends.
[0224]
Therefore, in this embodiment, the prize game medium payout control means in the payout control means, based on the detection signal from the payout count switch 301 as the payout detection means, volatile storage means (unpaid number counter in this example). When it is detected that payout of the prize game media less than the payout number stored in the payout means has been performed, the prize game is insufficiently provided to the payout means up to a predetermined number of times (two times in this example) determined in advance. Have the media paid out.
[0225]
FIG. 49 is a timing chart for explaining the ball bite detection process executed in the payout motor control process (step S753). In the payout motor constant speed process (step S524) in the payout motor control process, the payout control CPU 371 monitors the detection signal of the payout motor position sensor 295. The detection signal of the payout motor position sensor 295 is turned on twice, for example, every time the cam 292 makes one rotation. In order for the detection signal to be output twice each time the cam 292 makes one rotation, two positions (symmetrical with respect to the axis) of the cam 292 in the portion of the payout motor position sensor 295 that receives light from the light emitting unit. Position) is provided with a reflector. Then, the output of the light receiving section of the payout motor position sensor 295 is used as a detection signal.
[0226]
Therefore, even if the payout control CPU 371 does not turn on the detection signal of the payout motor position sensor 295 even though the payout motor 289 is given an excitation pattern of a step number of １ ／ or more rotations, In actuality, the payout motor 289 does not rotate due to foreign matter such as dust adhering to the cam 292 and the game ball is clogged (ball biting has occurred). As a result, the cam 292 rotates. It can be determined that it has not been done.
[0227]
In this embodiment, the payout motor 289 makes one rotation when receiving the excitation pattern for 16 steps. The payout control CPU 371 checks the detection signal of the payout motor position sensor 295 every time the payout motor 289 gives an excitation pattern for eight steps to the payout motor 289, as shown in FIG. 49, for example. Then, it is determined whether or not the payout motor 289 is rotating. If the detection signal of the payout motor position sensor 295 is in the same state for five consecutive times (the OFF state is five consecutive times or the ON state is five consecutive times), it is determined that a ball bite has occurred and the payout motor control processing is performed. A ball bite release process is executed.
[0228]
The payout control CPU 371 repeats a process of rotating the payout motor 289 at a high speed and a process of rotating the payout motor 289 at a predetermined number of times (for example, nine times) in the ball bite canceling process, as shown in FIG. Then, every time an excitation pattern for eight steps is given to the payout motor 289, the detection signal of the payout motor position sensor 295 is checked to determine whether or not the payout motor 289 is rotating. If it is determined from the detection signal that the rotation of the payout motor 289 has been restored, the ball bite release process is terminated, and the process returns to the normal ball payout process.
[0229]
If no change occurs in the detection signal of the payout motor position sensor 295 after performing the high-speed rotation process and the low-speed rotation process a predetermined number of times, the ball biting error bit (payout case error bit) of the error flags Is set. When the payout case error bit is set, the payout control CPU 371 does not drive the payout motor 289.
[0230]
As described above, the payout control unit includes the drive state monitoring unit that monitors the operation state of the payout unit, and the drive stop unit that stops driving the payout unit when the drive state monitoring unit detects an operation failure of the payout unit. Including.
[0231]
Next, error processing will be described. FIG. 51 is an explanatory diagram showing the relationship between the type of error and the display of the error display LED 374, and the like. As shown in FIG. 51, when the power supply confirmation signal from the main board 31 is turned off, the payout control CPU 371 controls the error display LED 374 to display “1” as a main board non-connection error. I do. When the payout count switch 301 is disconnected or the ball is clogged at the payout count switch 301, control is performed to display “2” on the error display LED 374 as the payout switch abnormality detection error 1. Note that the disconnection of the payout count switch 301 or the occurrence of ball clogging at the payout count switch 301 is determined by the detection signal of the payout count switch 301 not being turned off.
[0232]
When the detection signal of the payout count switch 301 is turned on even though the game ball is not being paid out, control is performed to display “3” on the error display LED 374 as the payout switch abnormality detection error 2. . When the detection signal of the payout count switch 301 is not turned on even though the rotation of the payout motor 289 is abnormal or the game ball is paid out, “4” is displayed on the error display LED 374 as a payout case error. Perform control. If the award ball REQ signal is turned on at an incorrect timing, or if the award ball REQ signal is turned off at an incorrect timing, a "5" is displayed on the error display LED 374 as an award ball REQ signal error. Is displayed.
[0233]
When the lower plate is full, that is, when the full switch 48 is turned on, a control is performed to display “6” on the error display LED 374 as a full error. When the shortage of replenishment balls, that is, when the out-of-ball switch 187 is turned on, a control to display “7” on the error display LED 374 is performed as an out-of-ball error.
[0234]
Further, when the VL signal from the card unit 50 is turned off, control is performed to display “8” on the error display LED 374 as a prepaid card unit unconnection error. If communication with the card unit 50 is performed at an improper timing, control is performed to display “9” on the error display LED 374 as a prepaid card unit communication error. The prepaid card unit communication error is detected in the prepaid card unit control processing (step S754).
[0235]
After the payout switch abnormality detection error 2, the payout case error, or the prize ball REQ signal error occurs among the above errors, the error release switch 375 is operated, and the operation signal is output from the error release switch 375 (turned on). Then, the payout control means returns to the state before the error occurred.
[0236]
FIG. 52 is a flowchart showing the error processing in step S757. In the error processing, the payout control CPU 371 checks the error flags, and if the set bits are only the payout switch abnormality detection error 2, the payout case error, and the award ball REQ signal error (any one of the three) It is checked whether or not only the bits, only two of the three bits, or only those three bits) (step S671). If only these bits are set, it is checked whether or not the operation signal has been turned on from the error release switch 375 (step S672). When the operation signal is turned on, the error recovery time is set in the pre-error recovery timer (step S673). The error recovery time is a time from when the error release switch 375 is operated to when the error state is actually returned to the normal state.
[0237]
If the operation signal is not on from the error release switch 375, the value of the pre-error recovery timer is checked (step S674). If the value of the pre-error recovery timer is 0, that is, if the pre-error recovery timer has not been set, the process moves to step S678. If the pre-error recovery timer is set, the value of the pre-error recovery timer is decremented by 1 (step S675). If the value of the pre-error recovery timer becomes 0 (step S676), the payout switch of the error flag is set. The bits of the abnormality detection error 2, the payout case error, and the award ball REQ signal error are reset (step S677).
[0238]
In this manner, the error state (the dispensing prohibited state as shown in step S621 in FIG. 46) is released based on the operation of the error release switch 375, so that the dispensing prohibited state is immediately released and the dispensing is performed. Processing can be activated.
[0239]
In step S678, the payout control CPU 371 checks the detection signal of the full tank switch 48. If the detection signal of the full tank switch 48 has been output (if it is in the ON state), a full tank error bit of the error flag is set (step S679). If the detection signal of the full tank switch 48 is off, the full tank error bit is reset (step S680).
[0240]
The payout control CPU 371 checks the detection signal of the ball out switch 187 (step S681). If the detection signal of the out-of-ball switch 187 is output (if it is in the ON state), the out-of-ball error bit of the error flag is set (step S682). If the detection signal of the ball out switch 187 is off, the ball out error bit is reset (step S683). When the out-of-ball error bit is set, the bit corresponding to the out-of-ball LED 52 in the output port buffer is set to a value corresponding to the lighting state in the display control process of step S759.
[0241]
Further, the payout control CPU 371 checks the state of the power supply confirmation signal from the main board 31 (step S685). If the power supply confirmation signal is not output (if it is off), the main board non-connection error bit is set. It is set (step S686). If the power supply confirmation signal has been output (if it is in the ON state), the main board non-connection error bit is reset (step S687).
[0242]
Also, the payout control CPU 371 checks the value of the switch timer corresponding to the payout count switch 301 among the switch timers in which the state of the detection signal of each switch is set, and determines the value as the maximum switch-on time (for example, “240 )) (Step S688), the payout switch abnormality detection error 1 bit of the error flag is set (step S689). If the value of the switch timer corresponding to the payout count switch 301 is equal to or less than the maximum switch-on time, the payout switch abnormality detection error 1 bit is reset (step S690). Note that the value of each switch timer is incremented by 1 in the switch processing of step S751 if the state of the input port for inputting the detection signal of each switch is in the switch-on state, and is cleared to 0 in the off state. Accordingly, the fact that the value of the switch timer corresponding to the payout count switch 301 has exceeded the maximum switch-on time means that the payout count switch 301 has been on for more than the maximum switch-on time, and It is determined that the game ball is clogged at the disconnection of the count switch 301 or the payout count switch 301.
[0243]
When the value of the switch timer corresponding to the payout count switch 301 becomes the switch-on determination value (for example, “2”), the payout control CPU 371 resets both the ball lending operation flag and the prize ball operation flag. If so, it is determined that the game ball has passed the payout count switch 301 while the payout operation is not being performed, and the payout switch abnormality detection error 2 bit of the error flag is set (step S693). If the ball lending operation flag or the prize ball operation flag is set, the payout switch abnormality detection error 2 bit is reset (step S694).
[0244]
Further, the payout control CPU 371 checks the input state of the VL signal from the card unit 50 (step S695). If the VL signal is not input (if it is off), the error flag indicates that the prepaid card unit is not included. A connection error bit is set (step S696). If the VL signal has been input (if it is in the ON state), the prepaid card unit non-connection error bit is reset (step S697).
[0245]
In the display control process of step S759, a notification (numerical display) corresponding to the error bit in the error flag is performed by the error display LED 374. In this embodiment, the game control means mounted on the main board 31 and the payout control means mounted on the payout control board 37 perform two-way communication regarding prize ball payout. Can be informed. In addition, as a communication error, a main board non-connection error due to the power supply confirmation signal from the main board 31 being turned off and a prize ball REQ signal error in which the prize ball REQ signal is turned on or off at an incorrect timing (steps S561 to S564 and (See steps S551 and S552), but if a communication error of a main board non-connection error occurs, the firing motor 94 is deactivated. That is, a state in which the game ball cannot be launched into the game area 7 is set. Therefore, the game does not proceed despite the occurrence of the communication error of the main board non-connection error.
[0246]
Further, since the communication error is detected on the payout control means side, even if the game control means and the payout control means perform bidirectional communication regarding the prize ball payout, the communication without increasing the load on the game control means. Errors can be detected.
[0247]
In this embodiment, the main board non-connection error is automatically cleared when the power supply confirmation signal is turned on (see steps S685 and S687). You may make it cancel.
[0248]
Further, in this embodiment, a communication error is notified to a communication error with the card unit 50 (a prepaid card unit non-connection error and a prepaid card unit communication error) and other errors (see FIG. 51). . Therefore, a communication error between the game control means and the payout control means is easily specified.
[0249]
FIG. 54 is a block diagram illustrating an example of an output of a test signal from the payout control board 37. FIG. 54 also shows a test terminal board 200 and a test apparatus 210. As shown in FIG. 54, in the payout control board 37, the detection signal from the payout count switch 301 and the payout BUSY signal output to the main board 31 are respectively branched, and the respective branched signals are ANDed (AND). Circuit) 376. Therefore, when the payout count switch 301 detects the payout of the game ball during the output of the payout BUSY signal, the AND circuit 376 can output the prize ball count signal indicating that the payout of the prize ball has been detected.
[0250]
In the payout control board 37, the prize ball count signal is output to a connector 377 provided on the payout control board 37. The connector 377 also outputs a test signal other than the prize ball count signal. The connector 377 is mounted only on a gaming machine used for a test. That is, a gaming machine that is not used for a test has a path for outputting a test signal such as a wiring pattern or a through hole, but does not have the connector 377. Therefore, it is not necessary to provide the connectors 377 on all the payout control boards 37, and the cost spent for testing the gaming machine is reduced. Further, since it is not necessary to attach the connectors to all the payout control boards 37 by soldering or the like, the work efficiency for performing the test of the gaming machine is improved. Further, since the test signal output wiring patterns and through holes are provided in all the game machines, the connector 377 is attached and the test terminal board 200 is connected when the inspection is performed after being installed in the game store. It is easy to do.
[0251]
The test terminal board 200 includes a connector 202 for inputting a test signal from a connector 377 mounted on the payout control board 37, a test signal output circuit 203, and a connector 204 for connecting to a test device 210. ing. The test signal output circuit 203 includes an IC and a buffer circuit for selecting a test terminal used for signal output from a plurality of test terminals provided on the connector 204.
[0252]
The test apparatus 210 collects various test signals. At the time of testing, a personal computer or the like is connected to the test apparatus 210, for example. Therefore, data based on various test signals input to the test apparatus 210 is collected by a personal computer, and information for use in a test such as the number of paid out prize balls is displayed on a display unit of the personal computer. , Etc. can be performed.
[0253]
The ball payout device 97 is configured to perform both the prize ball payout and the loan ball payout, and the payout count switch 301 detects both the game ball by the prize ball payout and the game ball by the loan ball payout. As shown at 54, by providing an AND circuit 376 that allows the detection signal of the payout count switch 301 to pass when the payout BUSY signal output during the prize ball operation is on, the payout control CPU 371 A prize ball count signal as a test signal can be created without involvement.
[0254]
FIG. 55 is a conceptual diagram showing an outline of the present invention. The game control means mounted on the main board 31 controls the progress of the game and stores the game state in the variation data storage means 56a. The payout control means 371A mounted on the payout control board 37 controls the payout means 97A for paying out prize game media. Further, when power supply to the gaming machine is stopped, a fluctuation data storage unit 916A for storing at least a game state stored in the fluctuation data storage unit 56a for at least a predetermined period is provided. The game control means 56A stores the total number of premium game media to be paid out based on the establishment of the payout condition so as to be specified, and when the power supply to the gaming machine is stopped, the variable data storage means 916A causes at least a predetermined content to be stored. The number of premium game media to be paid out is designated to the payout control means 371A based on the number of premium game media stored in the number of premium game media stored in the period storage medium and the number of premium game media stored in the number of premium game media storage means 56b. A payout command signal transmitting means 56d for transmitting a payout command signal; and a subtraction processing for subtracting the payout number designated by the payout command signal from the number of prize game media stored in the prize game medium number storage means 56b when a predetermined condition is satisfied. The payout control means 371A includes a payout control means 371A for performing a payout control in the game control means 56A. The payout number of the prize game medium designated from the signal transmitting means 56d is stored in the volatile storage means 371b, and the prize game medium having the payout number stored in the volatile storage means 371b is controlled and paid out by the payout means 97A. The payout command signal transmitting means 56d of the game control means 56A includes a prize game medium payout control means 371a for executing a payout processing to be performed. When the number of unpaid prize game media is stored in, the payout command signal is output after the payout processing of the prize game media of the payout number specified by the payout command signal is completed. Further, the payout control means 371A, the communication abnormality detection means 371c for detecting an abnormality related to the communication of the signal between the game control means 56A and the payout control means 371A, and, when the communication abnormality detection means 371c detects the abnormality, the game ball And a firing stop means 371d for performing control for stopping the operation of the firing means 94A for firing.
[0255]
In the above-described embodiment, a gaming machine having the following configuration is disclosed.
[0256]
(1) Payout control means (for example, a ball payout device 97) for controlling a main board 31 on which game control means (for example, a CPU 56 or the like) for controlling the progress of a game and payout means (for example, a ball payout device 97) for paying out prize game media. A payout control board 37 on which a payout control CPU 371 and the like are mounted, and the game control means controls the payout for instructing the number of prize game media based on establishment of a predetermined payout condition (for example, winning of a game ball into a winning area). A command signal is transmitted to the payout control means, and the payout control means causes the payout means to pay out the commanded number of prize game media based on the reception of the payout command signal, and outputs the commanded number of prize game media. A gaming machine that transmits a payout completion signal to game control means when the payout is completed. According to such a configuration, the game control means can recognize that the payout of the premium game medium has been completed. In addition, the next payout command signal can be transmitted after receiving the payout completion signal, and the payout management of the number of premium game media can be ensured.
[0257]
(2) A payout control means (for example, a ball payout device 97) for controlling a main board 31 on which a game control means (for example, a CPU 56 or the like) for controlling the progress of a game and a payout means (for example, a ball payout device 97) for paying out prize game media. A payout control board 37 on which a payout control CPU 371 and the like are mounted; and a launching means (for example, a hitting ball launching device including a launching motor 94) for launching the game medium toward the game area, wherein the payout control means is a game control means. Communication abnormality detecting means for detecting an abnormality in communication of a signal relating to the payout of the game medium between the payout control means and the payout control means (for example, a portion of the payout control means for detecting a power supply confirmation signal being turned off, or a prize ball REQ signal being generated at an incorrect timing A portion for detecting that the device has been turned off or on), and a firing stop means for performing control for stopping the operation of the firing device when the communication error detecting device detects an error. (E.g. portions for performing the steps S512, S518 in the payout control means) gaming machine and a. According to such a configuration, the operation of the launching unit can be stopped when a situation occurs in which the payout of the game medium cannot be performed.
[0258]
(3) A main board 31 on which game control means (for example, CPU 56 or the like) for controlling the progress of the game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). A payout control board 37 on which a payout control CPU 371 and the like are mounted; and a launching means (for example, a hitting ball launching device including a launching motor 94) for launching the game medium toward the game area, wherein the payout control means is a game control means. Is in a controllable state (for example, a power confirmation signal is turned on), and a game controllable state detecting means (for example, a part of step S512 in the payout control means) is controlled by the game control means. When the game controllable state detecting means detects that the state has become possible, the firing control means (for example, the payout control means Performing step S515~S517 portion) and a game machine including. According to such a configuration, when it is desired to deactivate the firing means, the game control means deactivates the firing means only by turning off the information for the payout control means indicating that the control is possible. be able to.
[0259]
(4) Main board 31 on which game control means (for example, CPU 56 or the like) for controlling the progress of the game is mounted, and payout control means (for example, ball payout device 97) for paying out prize game media (for example, ball payout device 97). A payout control board 37 on which a payout control CPU 371 or the like is mounted, and wherein the game control means stores the total number of premium game media to be paid out based on establishment of the payout condition so that the total number of the premium game media can be specified. A payout command signal (for example, a payout command signal that specifies the number of payouts of a predetermined number of prize game media to the payout control means based on the total number of prize game media stored in the prize game medium number storage means and the prize game medium number storage means). A payout command signal transmitting means (for example, a part for executing the prize ball transmitting process of step S232 in the game control means) for transmitting the payout number signal). Executes a command reception signal transmitting means (for example, the main control communication normal process of step S531 in the payout control means) for transmitting a command reception signal (for example, turning on a payout BUSY signal) indicating that the payout command signal has been received to the game control means. The game control means further subtracts the payout number designated by the payout command signal from the number of prize game media stored in the prize game medium number storage means when the command reception signal is received. A gaming machine including a prize game medium number storage number subtracting means for executing a subtraction process (for example, a part of the game control means for executing steps S261, S263, S264, and S265). According to such a configuration, it is possible to prevent a large number of prize balls from being illegally paid out due to a fraudulent act of restoring the power supply after illegally stopping the power supply to the gaming machine during the prize ball payout. it can.
[0260]
(5) A main board 31 on which a game control means (for example, CPU 56 or the like) for controlling the progress of the game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). A payout control board 37 on which a payout control CPU 371 and the like are mounted; and a payout detecting means (for example, a payout count switch 301) for detecting payout of premium game media and payout of rental game media by the payout means. A payout processing in-progress signal output means (for example, step S531 in the payout control means) for outputting a prize game medium payout processing signal (for example, a payout BUSY signal) to the game control means indicating that the prize game medium is being paid out. (A portion for executing the main control communication normal processing and the main control communication processing) in S532). A prize game medium payout signal (for example, a prize ball count signal) for enabling the number of prize game medium payouts to be specified on condition that a detection signal is input from the payout detection means during output of the medium payout processing signal. ), And a signal output path (for example, a wiring pattern for outputting the output of the AND circuit 376 to the outside) for outputting the premium game medium payout signal to the outside of the gaming machine. A gaming machine provided with. According to such a configuration, even when the payout detecting means detects both the payout of the premium game medium and the payout of the rental game medium, it is possible to easily create the premium game medium payout signal without software. it can.
[0261]
(6) A main board 31 on which game control means (for example, CPU 56 or the like) for controlling the progress of a game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). When the supply of power to the payout control board 37 mounted with the payout control CPU 371 and the gaming machine is stopped, at least the game state stored in the fluctuation data storage means (for example, RAM) is stored for at least a predetermined period. Data storage means (for example, a backup RAM) for storing the total number of prize game media to be paid out based on establishment of the payout condition, and the power supply to the gaming machine is stopped. A prize game medium number storage means for storing the storage content by the variable data storage means for at least a predetermined period when the Forms a loan request from a gaming device (for example, a card unit 50) communicably connected to a gaming machine and the number of premium game media to be paid out specified by a game control unit in a volatile storage unit (for example, a RAM area). Prize game medium payout control means (for example, payout) for executing payout processing for controlling the payout means to pay out the prize game medium of the payout number stored in the volatile storage means while storing the prize game medium in the volatile storage means. A gaming machine including a portion that executes the payout control process of step S756 in the control means). According to such a configuration, since the power supply is backed up only by the game control means, it is possible to prevent the player from being disadvantaged due to a power failure or the like.
[0262]
(7) A payout control means (for example, a ball payout device 97) for controlling a main board 31 on which a game control means (for example, CPU 56 or the like) for controlling the progress of a game and a payout means (for example, a ball payout device 97) for paying out prize game media. A payout control board 37 on which a payout control CPU 371 or the like is mounted, wherein the game control means stores prize game medium number storage means for identifiably storing the total number of prize game media to be paid out based on establishment of a payout condition; A payout command for transmitting a payout command signal designating the payout number of a predetermined number (for example, up to 15) of premium game media to the payout control means based on the number of premium game media stored in the premium game medium number storage means. Signal transmission means, wherein the payout control means forms the number of payouts of the prize game medium designated by the payout command signal from the game control means in a volatile storage means (for example, in a RAM area). Prize game medium payout control means (e.g., payout) for executing payout processing for controlling the payout means to pay out the prize game medium of the payout number stored in the volatile storage means while storing the prize game medium in the volatile storage means. A gaming machine including a portion that executes the payout control process of step S756 in the control means). That is, the payout control means stores only the number of game media to be paid out in one prize ball payout. According to such a configuration, it is possible to reduce the storage capacity for storing the number of payouts of the premium game media in the entire gaming machine.
[0263]
(8) A main board 31 on which game control means (for example, CPU 56 or the like) for controlling the progress of a game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). A payout control board 37 equipped with a payout control CPU 371 and the like and a state of a predetermined power supply used in the gaming machine are monitored, and a detection signal (when a detection condition relating to stopping supply of power to the gaming machine is satisfied) is established. For example, a power supply monitoring unit (for example, a power supply monitoring circuit 920) that outputs a power-off signal, and at least the game state stored in the fluctuation data storage unit (for example, RAM) when power supply to the gaming machine is stopped. A fluctuation data storage unit (for example, a backup RAM) for storing at least a predetermined period, and a detection signal from the power supply monitoring unit is supplied to an input port of the game control unit. The game control means is periodically input to check the input state of the input port by the power supply confirmation processing arranged at a predetermined position in the control processing (for example, power-off detection processing in step S20). Power supply stop processing means for executing power supply stop processing which is processing for storing information necessary for restoring the control state in the variable data storage means in response to the detection signal input from (For example, a part of the game control means for executing steps S452 to S481). According to such a configuration, an act of illegally aiming for a big hit can be effectively prevented.
[0264]
(9) The game control means is configured as in (8), and further, the game control means stops the power supply for saving the game state from the state of controlling the progress of the game in response to the input of the detection signal from the power monitoring means. When the detection signal is turned off after the power supply stop process is performed, the process returns to the state in which the progress of the game is controlled (for example, the processes in steps S482 and S483). A configured gaming machine. According to such a configuration, even if an instantaneous power interruption occurs, control of the progress of the game can be continued, and disadvantages can not be given to the player.
[0265]
(10) A gaming machine configured as in (8) or (9), further comprising a power supply monitoring means mounted on the main board. According to such a configuration, the game control means can quickly recognize the stop of the power supply.
[0266]
(11) A main board 31 on which a game control means (for example, CPU 56 or the like) for controlling the progress of a game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). A payout control board 37 on which a payout control CPU 371 or the like is mounted, wherein the payout control means detects an error relating to the payout of the game medium (for example, steps S551, S563, S653, S661, among payout control means). S691 and S692 are executed) and an error release signal (for example, an operation signal corresponding to the operation) from the error release switch means (for example, the error release switch 375) is monitored, and the error is detected after the error detection means detects the error. Error canceling means for canceling the error state when an input is detected in the canceling signal (for example, the payout control means Gaming machine including a portion) and executing the step S671～S677. According to such a configuration, the error is released by the payout control means recognizing the error release signal, so that the stored contents of the payout control means can be prevented from being cleared, and as a result, It is possible to prevent the player from being disadvantaged by the switch operation.
[0267]
(12) A main board 31 on which game control means (for example, CPU 56 or the like) for controlling the progress of the game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). A payout control board 37 equipped with a payout control CPU 371 and the like, and launching means (for example, a hit ball launching device including a launching motor 94) for launching the game medium toward the game area, wherein the payout control means drives the launching means A gaming machine that performs control. According to such a configuration, it is possible to reduce the cost related to the launch control of the game medium.
[0268]
(13) A main board 31 on which game control means (for example, CPU 56 or the like) for controlling the progress of the game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). A payout control board 37 on which a payout control CPU 371 and the like are mounted, wherein the payout control means executes a payout motor constant speed process of step S524 in the payout control means for monitoring an operation state of the payout means. And, in particular, a portion for executing the ball bite determination process illustrated in FIG. 49) and stopping the driving of the payout portion when the drive state monitoring device detects an operation failure (for example, ball bite) of the payout portion. A game machine including a drive stopping means (for example, a part for executing a payout motor braking process at the time of ball engagement in step S526 in the payout control means). According to such a configuration, it is possible to prevent the payout unit from being driven even when the payout unit cannot pay out the game medium.
[0269]
(14) A main board 31 on which a game control means (for example, CPU 56 or the like) for controlling the progress of the game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). A payout control board 37 on which a payout control CPU 371 and the like are mounted, and payout detecting means (for example, a payout count switch 301) for detecting a game medium paid out from the payout means and outputting a payout detection signal. When the means detects that payout of the prize game media less than the number of payouts has been performed based on the payout detection signal from the payout detection means (for example, the process of step S653), a predetermined number of times (step S653). (For example, twice) as a limit, causing the payout means to pay out the prize game media for the shortage (for example, the processing of steps S661 to S666). Gaming machines that are configured. According to such a configuration, it is possible to automatically recover a recoverable error regarding the payout control and continue the game.
[0270]
(15) A main board 31 on which a game control means (for example, CPU 56 or the like) for controlling the progress of the game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). A payout control board 37 on which a payout control CPU 371 and the like are mounted, and an effect control board 80 on which an effect control means (for example, an effect control CPU 101 and the like) mounted on a gaming machine for controlling electric components for effects are mounted. A game machine, wherein the effect control means is configured to control a plurality of types of electric components for effect (for example, the variable display device 9, the speaker 27, and the lamp / LED). According to such a configuration, the cost of the gaming machine can be reduced as compared with the case where a plurality of effect control means for controlling each effect means are provided.
[0271]
(16) A main board 31 on which a game control means (for example, CPU 56 or the like) for controlling the progress of a game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). A payout control board 37 mounted with a payout control CPU 371), and the payout control means converts a value specified by information recorded on a recording medium into a game use value that can be used for a game in a gaming machine. Media processing device (e.g., card unit 50) for performing a process for performing the same, has a function of paying out a lending game medium based on a game use value to a payout unit, and a payout control unit and a recording medium processing device. Is configured to be performed via a relay board (for example, an interface board 66) different from the payout control board provided with the payout control means. Gaming machine. According to such a configuration, it is possible to prevent an abnormality occurring in the recording medium processing device from being transmitted to the payout control board.
[0272]
(17) A main board 31 on which game control means (for example, CPU 56 or the like) for controlling the progress of a game is mounted, and a payout control means (for example, a ball payout device 97) for paying out prize game media (for example, a ball payout device 97). And a payout control board 37 mounted with a payout control CPU 371). The payout means has a function of paying out a lending game medium based on a lending request, and detects and lends a prize game medium paid out from the payout means. A gaming machine configured so that detection of a game medium is performed by the same payout detecting means. According to such a configuration, the number of parts is reduced, and the cost of the gaming machine is reduced.
[0273]
Further, even if the above-described configurations (1) to (17) are arbitrarily combined, a gaming machine exhibiting an effect based on each configuration can be configured.
[0274]
It should be noted that the game control means performs a subtraction process of the number of unpaid premium game media (step S261 in FIG. 31) in connection with the transmission of the payout command signal (specifically, turning on the payout BUSY signal in response to the transmission of the payout command signal). , S263, and S265), it is possible to minimize the disadvantage given to the player even if an unexpected power supply stop occurs due to a power failure or the like, and it is possible to effectively prevent illegal acts. In other words, since the total prize ball number storage buffer in which the number of unpaid premium game media is set is formed in the backup RAM in the game control means, even if the power supply to the gaming machine is stopped, a predetermined period (the backup power supply The game control means can restart the prize ball processing based on the stored content of the total prize ball storage buffer when the power supply is restored. That is, if the stored content of the total prize ball storage buffer is not 0, a payout command signal can be output to the payout control means.
[0275]
For example, if the process of subtracting the number of unpaid prize game media is executed based on the reception of the payout completion signal, the payout control means starts the prize ball payout based on the payout command signal, and then transmits the illegal payment completion signal. In the event that the power supply is stopped and the power supply is restored after the power supply is stopped, or the game control means is illegally reset once, the number of unpaid prize game media not subjected to the subtraction processing is calculated. Based on this, prize balls are paid out twice. However, if the process of subtracting the number of unpaid prize game media is performed based on the reception of the payout completion signal, the prize ball payout will not be performed twice even if such fraudulent acts are performed.
[0276]
Further, in the above embodiment, the output of the payout count switch 301 is input only to the payout control board 37. Therefore, the circuit configuration is simplified and the cost can be reduced as compared with the case where the output of the payout count switch 301 is supplied to both the main board 31 and the payout control board 37.
[0277]
In the above embodiment, the payout control means is configured to output a control signal (payout BUSY signal) indicating that the payout processing based on the prize ball REQ signal is being executed to the game control means. Therefore, it is possible to make the game control means recognize that the payout process is being executed.
[0278]
Also, the payout control means outputs to the game control means a payout completion signal as a control signal indicating that the payout processing of the number of prize balls indicated by the payout number signal has been completed. Since the BUSY signal is turned off, the game control means can recognize that the payout processing of the payout control means has been completed.
[0279]
Further, the game control means can output a control signal (power supply confirmation signal) as a supply stop detection signal indicating that the power supply has been cut off in response to the input of the power cutoff signal from the power supply monitoring circuit 920, It is possible to cause the payout control means to recognize that the power supply has been cut off. Note that, specifically, by turning off the power supply confirmation signal, the supply stop detection signal is output.
[0280]
Further, the game control means is configured to output a control signal (power confirmation signal) indicating that power supply to the gaming machine has started to the payout control means at the time of starting the power supply. The payout control means can recognize that the supply has started and the control operation of the game control means has started.
[0281]
In the above embodiment, the RAM provided on the payout control board 37 is not backed up by a power supply, but a part or all of the RAM may be backed up by a power supply as in the case of the main board 31.
[0282]
In the above embodiment, the payout request is made by the prize ball REQ signal and the payout number is specified by the payout number signal. However, the payout request and the payout number may be specified by the payout number signal. Good. In this case, when the payout number signal is output, the payout control means may determine that the payout request has been made at the same time. According to such a configuration, it is not necessary to use the award ball REQ signal.
[0283]
In the above-described embodiment, the payout BUSY signal is output during the payout processing of the prize ball. However, the payout BUSY signal may be output during the payout processing of the rental ball. With such a configuration, it is possible to recognize that the game control means is in the ball lending process. Therefore, when the game control unit recognizes that the ball lending process has been continuously performed for a predetermined period or more based on the ON state of the payout BUSY signal, it can determine that an error has occurred.
[0284]
In the above-described embodiment, the payout control unit determines that the payout ball payout is completed when detecting that the payout motor 289 has rotated by the planned payout number. When it has reached, it may be determined that the award ball payout is finished. That is, the payout control means is configured to determine whether the payout is completed by detecting the operation amount of the payout means (in this example, the rotation amount of the payout motor 289 or the number of detections by the payout motor position sensor). It may be.
[0285]
Furthermore, in the above-described embodiment, the payout control unit has confirmed whether or not the payout has been completed based on the detection signal of the payout count switch 301. However, the payout has been completed based on the output signal of the payout motor position sensor. It may be confirmed whether or not this is the case.
[0286]
Further, the payout control means detects the amount of operation of a drive unit (for example, a payout motor 289, a cam, etc.) of the payout means, and determines whether an abnormality related to payout (a payout unit error) has occurred based on the detection. May be configured. With such a configuration, it is possible to reliably detect an abnormality related to payout.
[0287]
Further, in the above-described embodiment, the ball payout device 97 is configured to be able to perform both ball lending and prize ball payout. The invention can be applied.
[0288]
Further, in the above-described embodiment, the dispensing is prohibited when the ball is out of the ball or when the lower plate is full, but also when it is not preferable to perform another dispensing or when the dispensing cannot be performed. The dispensing may be set to be prohibited. For example, the dispensing prohibition state may be set when the glass door frame 2 is opened and a detection signal is output from the door open switches 161A and 161B.
[0289]
In each of the above-described embodiments, the recording medium used in the recording medium processing device (card unit 50) is a magnetic card (prepaid card). However, the recording medium is not limited to a magnetic card, and may be a non-contact type or a contact type. It may be an IC card. Further, when the recording medium processing device is configured to be able to specify the recording information based on the identification code, the recording medium can at least read the information such as the identification code capable of specifying the recording information by the recording medium processing device. May be one that can be recorded in Further, the recording medium may be a medium on which a predetermined information recording symbol such as a barcode is printed so as to be readable. Further, the shape of the recording medium is not limited to a card shape, and may be any shape such as a disk shape, a spherical shape, or a chip shape.
[0290]
The pachinko gaming machine of each of the above embodiments mainly provides a predetermined game value to a player when a stop symbol of a special symbol variably displayed on the variable display portion 9 based on a winning start is a combination of a predetermined symbol. Although the first-type pachinko gaming machine has become available, a second-type pachinko game in which a predetermined gaming value can be given to a player when a predetermined area of the electric accessory which is opened based on a winning start is awarded. A third type of pachinko game in which a predetermined right is generated or continued when there is a prize for a predetermined electric auditory product which is opened when a stop symbol of a symbol variably displayed based on a winning prize is a predetermined combination of symbols. The present invention can be applied to a machine.
[0291]
Further, the present invention is not limited to a pachinko gaming machine in which a game medium is a game ball, and the present invention can be applied to a slot machine or the like when an electric component for paying out the game medium is provided.
[0292]
【The invention's effect】
As described above, according to the first aspect of the present invention, the game machine is provided with a communication abnormality detecting means for detecting an abnormality relating to the communication of signals between the game control means and the payout control means, and a communication abnormality detecting means. And a launch stop means for performing control for stopping the operation of the launch means when detecting the number of prize game media capable of specifying the total number of prize game media to be paid out based on establishment of the payout condition. A prize game medium number storage means capable of storing data and at least a predetermined period of time when the power supply to the gaming machine is stopped, and a payout control means based on the prize game medium number data. A payout command signal transmitting means for transmitting a payout command signal designating a payout number of a predetermined number of premium game media, and a predetermined condition is satisfied after the payout command signal transmitting means transmits the payout command signal. Prize game medium number data subtracting means for performing a subtraction process of subtracting a value corresponding to the payout number specified by the payout command signal from the prize game medium number data, wherein the payout control means outputs a payout command signal in the game control means. A payout process of storing the number of payouts of the prize game media designated by the transmitting means in the volatile storage means and controlling the payout means to pay out the prize game media of the number of payouts stored in the volatile storage means is executed. And a payout command signal transmitting means in the game control means indicates that there is a prize game medium whose prize game medium number data has not been paid out after the subtraction processing by the prize game medium number data subtracting means. When the payout command signal has been paid, the next payout command signal is output after the payout processing of the premium game media of the payout number specified by the payout command signal is completed. , It is possible to centrally manage the game control means unpaid coin number of prize game media, the effect of a non-payout can be reliably managed. As a result, the configuration of the payout control means is simplified, and the cost of the gaming machine is reduced. Further, when normal prize game medium payout cannot be performed, the game can be interrupted by the firing stop means, so that unexpected disadvantage is not given to the player.
[0293]
According to the second aspect of the present invention, a state in which the game control means executes the power supply stop processing for saving the game state from the state of controlling the progress of the game in response to the input of the detection signal from the power supply monitoring means And when the detection signal is turned off after executing the power supply stop processing, the game returns to the state in which the progress of the game is controlled. Can be continued, and no disadvantage is given to the player.
[0294]
According to the third aspect of the present invention, since the power supply monitoring means is mounted on the game control board provided with the game control means, the game control means can quickly recognize the stop of the power supply.
[0295]
According to the fourth aspect of the present invention, the payout control means monitors the operating state of the payout means, and the drive state monitoring means stops driving the payout means when the drive state monitoring means detects a malfunction of the payout means. Since the configuration includes the stopping unit, the driving of the payout unit is prevented even when the payout unit cannot pay out the game medium.
[0296]
In the invention described in claim 5, the payout control means includes payout detection means for detecting a game medium paid out from the payout means and outputting a payout detection signal, and wherein the prize game medium payout control means detects the game medium paid out from the payout detection means. Based on the payout detection signal, when it is detected that the number of prize game media paid out is less than the number of payouts stored in the volatile storage means, even though the prize game media have been paid out, Since the payout means is configured to execute the retry operation for paying out the prize game media for the shortage up to a predetermined number of times, a recoverable error relating to the payout control is automatically restored. Game can be continued.
[0297]
According to the sixth aspect of the present invention, since one effect control means for controlling a plurality of types of effect means provided in the gaming machine is provided, a plurality of effect control means for controlling each effect means are provided. The cost of the gaming machine can be reduced as compared with the case in which the game is performed.
[0298]
In the invention according to claim 7, since the communication between the payout control means and the recording medium processing device is configured to be performed via the relay substrate, an abnormality occurring in the recording medium processing device is generated in the payment control substrate. It can be prevented from being transmitted.
[0299]
In the invention according to claim 8, the payout means has a function of paying out the rental game medium based on the lending request, and the detection of the premium game medium paid out from the payout means and the detection of the rental game medium are the same. Since it is configured to be performed by the detecting means, the number of parts is reduced and the cost of the gaming machine is reduced.
[Brief description of the drawings]
FIG. 1 is a front view of a pachinko gaming machine viewed from the front.
FIG. 2 is a front view showing a front surface of the game board with a glass door frame removed.
FIG. 3 is a rear view of the gaming machine as viewed from the back.
FIG. 4 is a rear view of the mechanism plate to which various members are attached, as viewed from the rear side of the gaming machine.
FIG. 5 is a front view and a sectional view showing a ball payout device.
FIG. 6 is an exploded perspective view showing a ball payout device.
FIG. 7 is a block diagram showing a circuit configuration example of a game control board (main board).
FIG. 8 is a block diagram illustrating a circuit configuration example of a payout control board.
FIG. 9 is a block diagram illustrating a configuration example of an effect control board, a lamp driver board, and a sound output board.
FIG. 10 is a block diagram illustrating a configuration example of a power supply board.
FIG. 11 is a block diagram illustrating a configuration example of a power supply board.
FIG. 12 is a block diagram showing a CPU, a reset circuit, and a power supply monitoring circuit on the main board.
FIG. 13 is an explanatory diagram showing an example of bit assignment of output ports in the game control means.
FIG. 14 is an explanatory diagram showing an example of bit assignment of output ports in the game control means.
FIG. 15 is an explanatory diagram showing an example of bit assignment of input ports in the game control means.
FIG. 16 is a flowchart illustrating a main process executed by a CPU on a main board.
FIG. 17 is a flowchart illustrating a timer interrupt process.
FIG. 18 is a flowchart illustrating power-off detection processing.
FIG. 19 is a flowchart illustrating a power-off detection process.
FIG. 20 is an explanatory diagram showing an example of forming a switch timer in a RAM.
FIG. 21 is a flowchart illustrating an example of a switch process.
FIG. 22 is a flowchart illustrating an example of a switch check process.
FIG. 23 is an explanatory diagram showing an example of the content of a control signal.
FIG. 24 is a block diagram showing signal lines and the like used for transmitting and receiving control signals.
FIG. 25 is a flowchart showing award ball processing.
FIG. 26 is an explanatory diagram showing a configuration example of a winning ball number table.
FIG. 27 is a flowchart illustrating award ball number addition processing.
FIG. 28 is a flowchart showing a prize ball control process.
FIG. 29 is a flowchart showing winning ball waiting processing 1;
FIG. 30 is a flowchart showing award ball transmission processing.
FIG. 31 is a flowchart showing winning ball waiting processing 2;
FIG. 32 is a flowchart showing winning ball waiting processing 3;
FIG. 33 is a timing chart showing an example of an output state of a control signal.
FIG. 34 is an explanatory diagram showing an example of bit assignment of output ports in the payout control means.
FIG. 35 is an explanatory diagram showing an example of bit assignment of input ports in the payout control means.
FIG. 36 is a timing chart for explaining communication between the prepaid card unit and the gaming machine.
FIG. 37 is a flowchart showing a main process executed by a payout control CPU.
FIG. 38 is a flowchart showing a timer interrupt process executed by the payout control CPU.
FIG. 39 is a flowchart showing a firing motor control process.
FIG. 40 is a flowchart showing a payout motor control process.
FIG. 41 is a flowchart showing main control communication processing.
FIG. 42 is a flowchart showing main control communication normal processing.
FIG. 43 is a flowchart showing processing during main control communication.
FIG. 44 is a flowchart showing main control communication end processing.
FIG. 45 is a flowchart showing a payout control process.
FIG. 46 is a flowchart showing a payout start waiting process.
FIG. 47 is a flowchart showing a payout motor stop waiting process.
FIG. 48 is a flowchart showing a payout passage waiting process.
FIG. 49 is a timing chart for explaining a ball bite detection process.
FIG. 50 is a timing chart for explaining a ball bite release process.
FIG. 51 is an explanatory diagram showing the relationship between the type of error and the display of an error display LED;
FIG. 52 is a flowchart showing an error process.
FIG. 53 is a flowchart showing an error process.
FIG. 54 is a block diagram illustrating an example of an output of a test signal.
FIG. 55 is a conceptual diagram showing an outline of the present invention.
[Explanation of symbols]
1 Pachinko machine
31 Game control board (main board)
37 Dispensing control board
50 Prepaid Card Unit (Card Unit)
56 CPU
66 Interface board (relay board)
80 Production control board
91 Touch sensor board
94 launch motor
97 Ball Dispenser
301 Payment count switch
371 Dispensing control CPU
374 Error display LED
375 Error release switch
917 Capacitor (backup power supply)
920 Power supply monitoring circuit

Claims (8)

A gaming machine in which a player can perform a predetermined game using a game medium fired in a game area, and pays out a premium game medium as a premium based on that a payout condition is established by the game,
Game control means for controlling the progress of the game,
Launching means for launching the gaming medium toward the gaming area;
Payout means for paying out the premium game media,
Payout control means for controlling the payout means,
A communication abnormality detection unit that detects an abnormality related to communication of a signal between the game control unit and the payout control unit;
When the communication abnormality detecting unit detects an abnormality, the device includes a firing stop unit that performs control for stopping the operation of the firing unit,
The game control means,
Storing prize game medium number data capable of specifying the total number of prize game media to be paid out based on establishment of the payout condition, and storing the stored contents at least for a predetermined period when power supply to the gaming machine is stopped. Prize game medium number storage means capable of
A payout command signal transmitting means for transmitting a payout command signal specifying a payout number of a predetermined number of prize game media to the payout control means based on the prize game medium number data;
When a predetermined condition is satisfied after the payout command signal transmitting means transmits the payout command signal, a premium game medium for performing a subtraction process of subtracting a value corresponding to the payout number designated by the payout command signal from the premium game medium number data. Numerical data subtraction means,
The payout control means,
Volatile storage means for storing data that fluctuates according to control,
The payout number of the prize game medium designated by the payout command signal transmitting means in the game control means is stored in the volatile storage means, and the prize game medium of the payout number stored in the volatile storage means is paid out. Including a prize game medium payout control means for performing a payout process of controlling means to pay out,
The payout command signal transmitting means in the game control means, when the prize game medium number data indicates that there is unpaid prize game media after the subtraction processing by the prize game medium number data subtraction means, A game machine for outputting the next payout command signal after the payout processing of the premium game media of the payout number designated by the payout command signal is completed. Power supply monitoring means for monitoring a state of a predetermined power supply used in the gaming machine, and outputting a detection signal when a detection condition related to stopping supply of power to the gaming machine is satisfied,
The game control means shifts from a state in which the progress of the game is controlled to a state in which a power supply stop processing for saving the game state is executed, in response to the input of the detection signal from the power supply monitoring means, and 2. The gaming machine according to claim 1, wherein when the detection signal is turned off after executing the supply stop processing, the game machine returns to a state in which the progress of the game is controlled. The gaming machine according to claim 2, wherein the power supply monitoring means is mounted on a game control board provided with the game control means. The payout control means,
Driving state monitoring means for monitoring the operation state of the dispensing means,
The gaming machine according to any one of claims 1 to 3, further comprising: a drive stopping unit that stops driving the payout unit when the drive state monitoring unit detects an operation failure of the payout unit. The payout control means includes a payout detection means for detecting a game medium paid out from the payout means and outputting a payout detection signal,
The prize game medium payout control means, based on the payout detection signal from the payout detection means, stores in the volatile storage means the number of prize game media paid out even though the prize game medium was paid out. 4. The method according to claim 1, further comprising, when detecting that the number of payouts is less than a predetermined value, causing the payout means to execute a retry operation for paying out a shortage of premium game media up to a predetermined number of times. 5. The gaming machine according to any one of 4. The gaming machine according to any one of claims 1 to 5, further comprising one effect control means for controlling a plurality of types of effect means provided in the gaming machine. The payout control means is communicably connected to a recording medium processing device that performs processing for converting a value specified by information recorded on a recording medium into a game use value that can be used for a game in a gaming machine, Has the function of paying out the lending game media based on the game use value to the payout means,
The communication between the payout control means and the recording medium processing apparatus is performed via a relay board different from a payout control board provided with the payout control means. Gaming machine. The payout means has a function of paying out a rental game medium based on a loan request,
The gaming machine according to any one of claims 1 to 7, wherein the detection of the prize game medium paid out from the payout means and the detection of the rental game medium are performed by the same payout detection means.

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