JP5294215B2 - Pachinko machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a means for further suppressing the number of fraudulently put-out balls per unit time even when a fraudulent act is conducted, and a means for reflecting an accurate put-out rate (for example, a base value) in a hall computer side whatever state a game machine is in. <P>SOLUTION: A Pachinko game machine is configured such that game information can be transmitted to the hall computer, the number of planned put-out game balls promised to be put-out is transmitted to the hall computer regardless of the timing when the prize winning ball is actually put out, and furthermore, one put-out (the whole put-out operation) is executed in a plurality of subdivided put-out operations (divided put-out operations) while extend waiting time between the divided put-out operations to be executed subsequently when abnormal put-out is detected in the divided put-out operation. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention provides a game medium comprising a main control means for determining a prize ball payout, a payout means for paying out a game ball to a player, and a payout detection means for detecting whether or not a game ball is paid out. BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ball ball game machine in which an illegal act related to payout of a game ball is suppressed in a ball ball game machine that is a ball. Furthermore, the present invention provides a gaming machine in which a predetermined winning ball is paid out when a gaming ball enters a winning opening provided in a gaming area, and the winning ball payout information can be output to a hall computer. About.

  A bullet ball gaming machine is a type of gaming machine in which a gaming ball as a gaming medium is paid out when a predetermined condition is satisfied. For example, in a pachinko gaming machine that is the most standard among ball and ball gaming machines, a winning ball is paid out by letting a gaming ball enter a winning opening provided in the gaming area. Recently, a game medium lending machine such as a card unit has been installed adjacent to the ball game machine. Upon receiving a request from the lending machine, a predetermined number of game balls are placed on the upper plate of the ball game machine. Is supplied. Here, when award ball payout or ball lending payout is made, ball payout is generally made in the following procedure (example). First, with respect to award ball payout, when a game ball enters a winning opening such as a start winning opening or a large winning opening, it reaches a winning ball discharge mechanism via a winning ball set, and is detected by a winning ball detection switch there. The main control board side that has received this detection signal transmits a prize ball payout command to the payout control board side. Subsequently, the payout control board that has received the prize ball payout command controls the ball payout apparatus based on this command to execute a predetermined number of prize ball payout processes. Similarly, in the case of this ball lending operation, a ball payout command is received, and the payout control board controls the ball payout device based on this command and executes a predetermined number of ball payout processes.

  By the way, the ball payout device provided on the back of the game board includes a rotor (camshaft), a payout motor for rotating the rotor, and a ball detector (count sensor) for detecting the payout game ball. have. In recent years, in order to improve the ball payout speed, when executing the ball payout, the ball payout motor is driven by the number of payout balls once, and it is confirmed whether or not the unpaid balls exist after the drive. When present, a high-speed prize ball payout mechanism that drives the ball payout motor again to pay out the remaining balls has appeared.

  On the other hand, recently, the sphere detection unit (sensor) of the ball payout function has been made abnormal by radio waves, and the illegal act of trying to obtain a large number of balls in a form that is not detected despite the balls being paid out (goto action) ) Is done. When such a fraudulent act is executed by the high-speed prize ball payout mechanism as described above, the number of illegal balls per unit time is too large, and there is a risk that damage will be serious.

  Therefore, Patent Document 1 proposes a technique (wait delay) in which when a payout abnormality is detected during a payout operation, the time interval until the next payout operation is longer than the normal time interval. According to this method, the pace of the payout operation becomes slow. Therefore, the game ball payout will not stop completely, and the game balls necessary for the game will continue to be supplied, but if a serious abnormality has occurred (in the case of fraudulent acts, etc.) It is possible to reduce the number of game balls that are inappropriately paid out before an abnormality is discovered. In addition, since the time interval until the next payout operation becomes longer, an opportunity to spontaneously eliminate the clogging of balls during this time is also given.

  By the way, as a technology related to the prize ball payout, there is a management system using a hall computer that can manage the number of customers, the operation rate, the payout rate, and the like. Specifically, the management is executed by transmitting game information from the external terminal board of each pachinko gaming machine to the hall computer in real time. Here, among items managed by the hall computer, there is a play rate in a normal gaming state called “base”. Here, the “base” is calculated by a mathematical formula: base (B) = (OUT−out of special award) / (IN−in special award IN) × 100. In the formula, “IN” is the number of balls that have been fired, “OUT” is the number of balls that have been paid out, and “INNER SPECIAL IN” is the number of balls that have been fired during the special prize (big hit). Yes, “outside special award” is the number of winning balls in the special award (big hit). As can be seen from the above formula, a high base value means that it is easy to win a prize (good ball holding) during normal games. Thus, the base value is an important management item for determining the profit on the hall side, and the nail adjustment is performed with reference to this base value in the hall. By the way, in a conventional pachinko gaming machine, a “prize ball signal” corresponding to the number of prize balls actually paid out is output to an external terminal (for example, one pulse is output for 10 prize balls). When a prize ball signal corresponding to the number of prize balls actually paid out is output to the outside, when a payout is delayed due to a payout speed, a full tray, etc., the prize ball signal output from the external terminal is also delayed. Therefore, there arises a problem that accurate data cannot be obtained by the hall computer. In particular, a large number of prize balls are generated when a jackpot is generated in which the grand prize winning opening is kept open. At this time, the speed added to the total prize ball number data may be faster than the game ball payout speed based on the total prize ball number data by the payout device. As a result, even if the big hit ends and returns to the normal game state, the winning ball resulting from the big hit is still being paid out. In this case, as described above, a “prize ball signal” corresponding to the number of prize balls actually paid out is output from the external terminal board. Instead, it causes a situation where it is handled as a prize ball in the normal gaming state.

Therefore, in order to solve this problem, in Patent Document 2, when the number of unpaid prize balls is determined to be greater than or equal to a predetermined number at the end of the jackpot, the number of unpaid prize balls is determined to be less than the predetermined number. A technology to limit the transition from the big hit state to the normal gaming state is proposed.
JP 2002-78915 A JP 2008-93273 A

  However, even with the technique of Patent Document 1, when an illegal act is executed, a situation in which a number of game balls that cannot be ignored is paid out. Therefore, a first object of the present invention is to provide means that can further suppress the number of illegally paid out game balls per unit time even when an illegal act is executed.

  Furthermore, in the technique according to Patent Document 2, since the transition from the big hit state to the normal gaming state is limited until the number of unpaid prize balls is determined to be less than the predetermined number, the game is substantially stopped. In this case, if the stop time is extended for a long period of time, such as when a problem such as a ball clogging or a full tray has occurred, the player is misunderstood that the gaming machine has failed. In particular, as will be described later, in the present invention, a split payout is performed in which one payout operation is divided into a plurality of times, and when a prize ball payout abnormality occurs, the waiting time between the split payout operations is increased. It is configured. When such a configuration is adopted, particularly when a large amount of prize balls are paid out as in special games, when a prize ball payout abnormality occurs, the prize ball payout determination timing and the timing at which the prize ball is actually paid out are A significant time lag occurs between the two. In addition, the technology according to Patent Document 2 is a special process that is executed only at the time of transition from the jackpot state to the normal gaming state, and other situations in which the special process is not executed (for example, during a jackpot, during a time-saving game ) Cannot be accurately grasped. Therefore, the present invention reflects the exact payout rate (for example, base value) on the hall computer side in any state in the pachinko gaming machine capable of transmitting game information to the hall computer. A second object is to provide means that can be used.

The present invention (1)
Main control means (transmission command setting means 1111a functioning as prize ball payout determination means) for determining the prize ball payout;
A payout means (payout unit 13) capable of paying out game balls by performing a payout operation;
A payout control means (payout control means 2300) for controlling the payout operation of the payout means (payout unit 13) based on a payout command that is a command related to award ball payout transmitted from the main control means (transmission / reception control means 1100);
Main control means (main-side control board 1000) and payout control means (payout control means) having game ball detecting means (count sensor 14) for detecting game balls paid out from payout means (payout unit 13). 2300) and ball game machines that operate on a board having a separate CPU,
The payout control means (payout control means 2300) is a payout means (payout unit 13) so that a predetermined number of game balls to be paid out in one payout operation can be divided into a plurality of times by a plurality of divided payout operations. In addition to driving control, control is performed so as to provide a waiting time by stopping the driving of the payout means (payout unit 13) between the divided payout operations.
A ball game machine
A planned payout amount in one divided payout operation is compared with the number of game balls actually detected by the game ball detection means (count sensor 14) as a result of the single divided payout operation, and a payout abnormality occurs. A payout abnormality determining means (payout abnormality determining means 2330) for determining whether or not
When it is determined by the payout abnormality determining means (the payout abnormality determining means 2330) that a payout abnormality has occurred, the waiting time after the divided payout operation in which it has been determined that a payout abnormality has occurred is made longer than the normal wait time. A waiting time control means (waiting time control means 2340);
An external that transmits information on the number of awarded prize balls scheduled to be paid out from the payout means (payout unit 13) to the outside regardless of the execution timing of the payout of the prize balls by the payout means (payout unit 13). A bullet ball game machine having a transmission control means (HC side transmission control means 1114).

The present invention (2)
The external transmission control means (HC side transmission control means 1114) transmits information indicating that the predetermined number of prize balls to be paid out to the outside whenever the cumulative value of the number of scheduled prize balls to be paid reaches a predetermined number. This is a ball game machine of the invention (1).

The present invention (3)
The external transmission control means (HC side transmission control means 1114)
A scheduled prize ball payout number temporary storage means (scheduled payout number related counter 1114c) for temporarily storing the scheduled prize ball payout number;
When the main control means (the prize ball payout determination means 1060 by the main control board 1000) determines the prize ball payout, the value temporarily stored in the scheduled prize ball payout number temporary storage means (scheduled payout number related counter 1114c). A planned winning ball payout number adding means (scheduled payout number adding means 1114a) for adding the planned winning ball payout number related to the determination to
When the scheduled winning ball payout number temporarily stored in the scheduled winning ball payout number temporary storage means (scheduled payout number related counter 1114c) exceeds the predetermined number, the scheduled prize ball payout information is transmitted to the outside, Scheduled prize ball payout number subtracting means (scheduled payout number subtracting means 1114b) for subtracting the predetermined number from the scheduled prize ball payout number temporarily stored in the scheduled prize ball payout number temporary storage means (scheduled payout number related counter 1114c); This is a pachinko gaming machine according to the invention (2).

  Here, this invention (1)-(3) contains aspect (1)-(3) further.

First, in aspect (1), the ball game machine
It further has a means for temporarily storing the number of occurrences of payout abnormalities for counting the number of occurrences of payout abnormalities,
The waiting time control means is the ball game machine according to any one of the inventions (1) to (3), wherein the waiting time is increased stepwise based on the count value of the payout abnormality occurrence number temporary storage means.

  In the aspect (2), the waiting time control unit is configured to perform a plurality of divided payouts constituting the one payout operation in one payout operation executed under a situation where the wait time is longer than a normal wait time. In the operation, when the payout abnormality does not occur in any of the divided payout operations, the ball game machine according to the aspect (1) is configured to clear the count value in the payout abnormality occurrence number temporary storage means.

  In the aspect (3), when the payout control means does not generate any payout abnormality in a certain payout operation under the situation where the waiting time is longer than the normal waiting time, the waiting time still remains. Even if it is time, it is a bullet ball game machine in any one of the said invention (1)-(3) and the said aspect (1) and (2) which performs the next divided payout operation.

  According to the present invention (1), when a single payout (all payout operations) is executed by a plurality of subdivided payout operations (split payout operations), and a payout abnormality is detected in the split payout operation, Since it is configured to increase the waiting time between the divided payout operations to be executed thereafter, it is impossible with the conventional technique to increase the waiting time between all payout operations after executing all the payout operations continuously. In addition to being able to extend the payout time of the first full payout operation itself, the frequency of the waiting time is significantly increased (for example, if the full payout operation is divided into five split payout operations, the full payout operation Is executed twice, while the prior art has only one waiting time, the present invention can construct nine waiting times), which enables more delicate control of the waiting time length. Also play. Further, according to the present invention (1), the game information can be transmitted to the hall computer, and the planned number of payouts to be paid out regardless of the timing at which the prize balls are actually paid out. Is sent to the hall computer, so that the waiting time between the split payout operations becomes longer due to the detection of the payout abnormality in the split payout operation (particularly due to special games, a large number of Even if there is a significant time lag between the winning timing that triggered the payout and the actual payout timing due to the winning, the real-time payout rate is reflected on the hall computer side. There is an effect that it becomes possible.

  According to the present invention (2), in addition to the above-described effect, when the predetermined number of winning ball payouts reaches a predetermined number, the predetermined number is output to the outside each time as a unit. Compared to the case where prize ball number information is transmitted, it is possible to reduce the burden on the hall computer that receives and manages the information.

  According to the present invention (3), in addition to the above effect, when the predetermined prize ball payout information corresponding to the predetermined number is output to the outside, the expected prize ball payout temporarily stored in the scheduled prize ball payout number temporary storage means Since the predetermined number is subtracted from the value relating to the number, it is possible to prevent an increase in the capacity of the scheduled prize ball payout number temporary storage means.

FIG. 1 is a front view (player side) of a pachinko gaming machine according to the best mode. FIG. 2 is a back view of the pachinko gaming machine according to the best mode. FIG. 3 is a schematic diagram of an operation principle of storing payout game balls in the gaming machine in the pachinko gaming machine according to the best mode. FIG. 4 is an external view of the payout unit of the pachinko gaming machine according to the best mode. FIG. 5 is a schematic diagram of the operation principle for paying out the structure of the payout unit and the game ball in the pachinko gaming machine according to the best mode. FIG. 6 is a schematic electrical configuration diagram of the pachinko gaming machine according to the best mode. FIG. 7 is a diagram showing the contents of commands and information transmitted and received between the main control board and the payout control board of the pachinko gaming machine according to the best mode. FIG. 8 is a functional block diagram of the pachinko gaming machine according to the best mode. FIG. 9 is a flowchart of communication processing with the payout control board executed on the main control board side in the pachinko gaming machine according to the best mode. FIG. 10 is a flowchart of serial communication error monitoring processing executed on the main control board side in the pachinko gaming machine according to the best mode. FIG. 11 is a flowchart of the serial communication data reception monitoring process executed on the main control board side in the pachinko gaming machine according to the best mode. FIG. 12 is a flowchart of a payout command request process executed on the main control board side in the pachinko gaming machine according to the best mode. FIG. 13 is a flowchart of a payout command transmission process executed on the main control board side in the pachinko gaming machine according to the best mode. FIG. 14 is a flowchart of the first command (second command) transmission process executed on the main control board side in the pachinko gaming machine according to the best mode. FIG. 15 is a flowchart of the first command reception confirmation process executed on the main control board side in the pachinko gaming machine according to the best mode. FIG. 16 is a flowchart of the second command reception confirmation process executed on the main control board side in the pachinko gaming machine according to the best mode. FIG. 17 is a flowchart showing the management process of the number of scheduled prize balls to be paid out and the process of transmitting the number of scheduled prize balls to be paid out to the hall computer HC in the pachinko gaming machine according to the best mode. FIG. 18 is a flowchart of processing executed on the payout control board side in the pachinko gaming machine according to the best mode. FIG. 19 is a flowchart of communication processing with the main control board executed on the payout control board side in the pachinko gaming machine according to the best mode. FIG. 20 is a flowchart of serial communication error monitoring processing executed on the payout control board side in the pachinko gaming machine according to the best mode. FIG. 21 is a flowchart of the serial communication data reception monitoring process executed on the payout control board side in the pachinko gaming machine according to the best mode. FIG. 22 is a flowchart of communication processing with the main control board executed on the payout control board side in the pachinko gaming machine according to the best mode. FIG. 23 is a flowchart of communication processing with the card unit executed on the payout control board side in the pachinko gaming machine according to the best mode. FIG. 24 is a flowchart of the payout control process executed on the payout control board side in the pachinko gaming machine according to the best mode. FIG. 25 is a diagram showing a first action (payout command transmission by serial communication) in the pachinko gaming machine according to the best mode. FIG. 26 is a diagram showing a first action (payout command transmission by serial communication) in the pachinko gaming machine according to the best mode. FIG. 27 is a diagram showing a second action (extension of the ball passage waiting time due to a payout abnormality) in the pachinko gaming machine according to the best mode. FIG. 28 is a diagram showing a second action (extension of the ball passage waiting time due to a payout abnormality) in the pachinko gaming machine according to the best mode. FIG. 29 is a diagram showing a third action (sending prize ball payout number information to the hall computer HC) in the pachinko gaming machine according to the best mode. FIG. 30 is a flowchart of a payout control process executed on the payout control board side in the pachinko gaming machine according to the best mode (modified example). FIG. 31 is a functional block diagram of a pachinko gaming machine according to the best mode (modified example). FIG. 32 is a flowchart showing the management process of the scheduled prize ball payout number and the transmission process of the scheduled prize ball payout number information to the hall computer HC in the pachinko gaming machine according to the best mode (modified example).

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, a pachinko gaming machine will be described as an example of the best mode of the present invention. However, the gaming machine of the present invention is not limited to a pachinko gaming machine, and may be another ball game machine (for example, a sparrow ball or an arrangement ball) or a slot machine.

"overall structure"
(Front)
First, the basic structure of the front side of the pachinko gaming machine according to the best mode will be described with reference to FIG. Pachinko machines are mainly composed of a gaming machine frame and a gaming board. Hereinafter, these will be described in order.

  First, the gaming machine frame of the pachinko gaming machine includes an outer frame 102, a front frame 104, a transparent plate 106, a door 108, an upper ball dish 110, a lower ball dish 112, and a launch handle 116. First, the outer frame 102 is a frame for fixing the pachinko gaming machine to a position where it should be installed. The front frame 104 is a frame body aligned with the opening portion of the outer frame 102, and is attached to the outer frame 102 through a hinge mechanism (not shown) so as to be opened and closed. The front frame 104 includes a mechanism for launching a game ball, a mechanism for detachably storing a game board, a mechanism for guiding or collecting the game ball, and the like. The transparent plate 106 is made of glass or the like and is supported by the door 108. The door 108 is attached to the front frame 104 through an unillustrated hinge mechanism so as to be opened and closed. The upper ball tray 110 has mechanisms for storing game balls, sending the game balls to the launch rail, and extracting the game balls to the lower ball tray 112. The lower ball tray 112 has a mechanism for storing and extracting game balls. Further, a speaker 114 is provided between the upper ball tray 110 and the lower ball tray 112, and a sound effect corresponding to the gaming state or the like is output. The game effect lamp 190 is provided in the game area 120 or an area other than the game area 120, and plays a role of effect by blinking or the like. Furthermore, a status display unit 130 that displays information relating to the payout of the game ball, which can be visually recognized through the lower right portion of the transparent plate 106, by an LED is provided.

  Next, the game board 120 has a game area 120 defined by an outer rail 122 and an inner rail 124. The game area 120 includes a plurality of not-shown mechanisms such as a game nail and a windmill, various general winning ports, a special drawing start port 2110 (entrance detection sensor 2111), and a general illustration start port 2210 (entrance detection). Sensor 2211), special winning opening 2120 (ball detection sensor 2121), special symbol display device 2130, effect display device 2140, normal symbol display device 2220, center decoration 192 and out port 142 are provided. Then, when a game ball enters a variety of winning holes such as the special figure starting port 2110 or the big winning port 2120, the passing of the game ball is detected by a ball detection sensor provided in these winning ports. This detection signal is transmitted to the main control board (main control device) 1000, and in response to this, a predetermined payout command is sent from the main control board 1000 to the payout control board 2000. As a result, a predetermined number of prize balls are paid out. It is. Further, as shown in FIG. 1, a card unit C that accepts lending of game balls by a prepaid card is provided adjacent to the left of the gaming machine 1.

  Here, the card unit C according to the best mode is the same as a known configuration. Specifically, in the card unit C, although not shown, there is a usable indicator lamp that indicates whether or not it is usable, and there is a fraction (a number less than 100 yen) in the remaining amount information recorded in the card. In this case, a fraction display switch for displaying the fraction on a frequency display LED provided in the vicinity of the upper plate, a connecting table direction indicator indicating which side of the pachinko gaming machine the card unit C corresponds to, a card unit When checking a card insertion indicator lamp indicating that a card has been inserted into C, a card insertion slot into which a card as a recording medium is inserted, and a card reader / writer mechanism provided on the back of the card insertion slot A card unit lock or the like for releasing the card unit is provided.

(back)
Next, the basic structure on the back side of the pachinko gaming machine according to the best mode will be described with reference to FIG. The pachinko gaming machine controls the overall operation of the pachinko gaming machine, and in particular controls the overall gaming operation such as winning / successful lottery when entering the special figure starting port 2110 and sending a prize ball payout command to the payout control board 2000 (ie, Main control board (main control device) 1000 for performing control directly related to the player's profit), and display / acoustics related to various effects / information notifications on the drawing display unit 2141 for adding interest to the game contents Sub control board (production control device) 3000 that controls various effects using side lamps and the like, and sub sub control board (design control) that controls various effects on the effect display device 2140 based on instructions from the sub control board 3000 Device) 4000, a ball payout-related mechanism / device, and an external relay terminal board 5000 for relaying game information transmission to the hall computer HC, etc. It has to. Here, the ball payout-related mechanism / device pays the game balls supplied from the ball tank 11 to the upper ball tray 110 in response to a request from the ball tank 11, the tank rail 12, each winning opening or a card unit. A payout unit 13, a count sensor 14 for detecting a payout ball from the payout unit 13, a saucer full tank switch 15 that is turned on when the pans (the upper ball tray 110 and the lower ball tray 112) are full, and the payout unit 13. The prize ball payout control board (prize ball payout device) 2000 or the like for controlling the payout operation by.

(Payment mechanism)
Next, with reference to FIG. 3, the operation principle of storing a payout game ball in the gaming machine in the pachinko gaming machine according to the best mode will be described. As shown by the arrows in FIG. 3, the game balls supplied from the replenishment device (ancillary equipment of the hall installed to supply the game balls to the ball tank 11 of the game machine) are connected to the ball tank 11 and the tank rail 12. As a result, the payout unit 13 is guided and stored. The game balls stored in the gaming machine in this manner are paid out to the upper ball tray 110 as prize balls based on the entrance to the prize opening or based on a withdrawal request from the card unit.

  Next, the structure of the payout unit 13 of the pachinko gaming machine according to the best mode and the operation principle for paying out the game ball will be described with reference to FIGS. 4 and 5. First, as shown in FIG. 4, the payout unit 13 has a payout motor 13a that is driven at the time of payout. As shown in FIG. 5, the payout unit 13 has a cam shaft 13b connected to the payout motor 13a. The dispensing unit 13 having such a structure operates according to the following principle. First, when a game ball enters a winning opening in the game area 120, a winning signal is sent to the main control board 1000, the main control board 1000 determines the number of payouts, and transmits a signal of the winning ball to the payout control board 2000. . Alternatively, a ball lending request is made from the gaming ball lending device such as the card unit C to the payout control board 2000. In response to this, the payout control board 2000 operates the payout unit 13, and the payout motor 13a in the payout unit 13 executes payout of the game ball. As shown in FIG. 5, when the payout motor 13a rotates, the camshaft 13b rotates and the game balls are paid out one by one. The game balls that have been paid out are detected by a count sensor 14 provided in the payout unit 13, and the payout control board 2000 counts the number of game balls to be paid out.

(External relay terminal board)
Next, the external relay terminal board 5000 according to the best mode will be described with reference to FIG. The external relay terminal board 5000 has a plurality of external connection terminals as output terminal portions to which various cable connectors are connected {for example, information relating to award ball payout, information relating to winning or symbol stop, current gaming state (normal gaming state, Error information for outputting various error information detected by the opening detection sensor when the door is opened, the terminal for gaming state information output for outputting information on specific gaming state, special gaming state, etc.) Output terminals and the like} are provided. Specifically, as shown in the upper part of FIG. 2, the external relay terminal plate 5000 is provided with output terminal portions 5000a, 5000b,. Here, first, the output terminal section 5000a is a terminal for outputting a planned winning ball payout number signal (a signal indicating that a predetermined number of balls are to be paid out) output from the main control board 1000. The output terminal section 5000b is a terminal for outputting a prize ball payout number signal (a signal when the predetermined number of balls are actually paid out) output from the main control board 1000. As for the prize ball information, when a predetermined number (10 balls in this example) is scheduled to be paid out or when it is actually paid out, a predetermined pulse (ON state for about 0.104 seconds) is output. Is done. Other output terminal sections include a jackpot output terminal that outputs a signal during the jackpot when there is a jackpot (there are multiple jackpot types), a door opening output terminal that outputs a signal while the glass door is open, and a start port A terminal for output at the time of winning a winning opening that outputs a signal when winning a prize, a terminal for output when a ball is out of output when the ball is short in the award ball tank, a special symbol that outputs a signal when the special symbol is stopped There is an output terminal for the fixed number of times.

<Electrical configuration>
Next, an electrical schematic configuration of the pachinko gaming machine according to the best mode will be described with reference to the block diagram of FIG. As described above, the pachinko gaming machine according to the best mode includes a main control board 1000 that controls the progress of the game, a payout control board 2000 that controls the payout of game balls based on commands from the main control board 1000, A sub-control board 3000 for controlling various effects on the effect display device 2140 such as variation / stop of the decorative pattern, lighting of the sound / game effect lamp 190 from the speaker 114, and the effect display device 2140 And a sub-sub control board 4000 for controlling the decorative pattern change display / stop display, hold display, notice display, and the like. Here, the payout control board 2000 is connected to a payout unit 13 (payout motor 13a) for paying out game balls, and a state display unit 130 for displaying a state relating to payout of game balls to the outside by LEDs.

  Here, the main control board 1000, the payout control board 2000, the sub-control board 3000, and the sub-sub-control board 4000 are handled by a CPU that performs various arithmetic processes, a ROM that stores programs that prescribe the arithmetic processes of the CPU, and a CPU. A RAM for temporarily storing data (various data generated during the game, computer programs read from the ROM, etc.) is mounted.

  Here, between the main control board 1000 and the payout control board 2000, information transmission is executed in the form of serial transmission. That is, one transmission line is provided from the main control board 1000 to the payout control board 2000, and one transmission line is provided from the payout control board 2000 to the main control board 1000. Here, as will be described in detail later, commands between the main control board 1000 and the payout control board 2000 are configured in units of 2 bytes, and are transmitted serially in units of 1 byte.

  On the other hand, information and commands from the main control board 1000 to the sub control board 3000 are transmitted in parallel. The same applies to information and commands from the sub-control board 3000 to the sub-sub-control board 4000.

<Contents of commands and information transmitted / received via serial communication>
Next, the contents of commands and information transmitted / received between the main control board 1000 and the payout control board 2000 will be described with reference to FIG. As described above, commands from the main control board 1000 to the payout control board 2000 are configured in units of 2 bytes, and are transmitted serially in units of 1 byte. Similarly, information (command correspondence information) from the payout control board 2000 to the main control board 1000 is also configured in units of 2 bytes, and is transmitted serially in units of 1 byte.

Therefore, first, a payout command transmitted from the main control board 1000 to the payout control board 2000 will be described. First, the first transmission command is composed of first command specifying information, information about a full tray and the number of prize balls. Specifically, bits 7 to 5 are fixed to 100 (identification information indicating that the command is the first command). Next, bit 4 is related to the pan full state, “0” means that the pan is not full, and “1” means that the pan is full. Next, bits 3 to 0 relate to the number of prize balls. For example, 0 (0000B) means 0 prize balls and 15 (1111B) means 15 prize balls. . Next, in the second transmission command, bits 7 to 4 are a fixed value (1111) of the confirmation signal, and bits 3 to 0 relate to the number of divided payouts. Here, Table 1 shows the correspondence between bit information and the number of divided payouts. As can be seen from this table, for example, 3 (0011E) means that the number of divided payouts = 3, and 5 (0101E) means that the number of divided payouts = 5. In the best mode, even when there is no prize ball, the first command, which is zero prize balls, is always sent to the payout control board 2000 side at the timing when the first command transmission process is executed (for example, for each scheduled interruption process). ) Continue throwing. In this best mode, a command relating to the number of divided payouts is added to the second transmission command. However, the present invention is not limited to this. May be configured to be transmitted to the payout control board as a separate command.

  Next, payout related information transmitted from the payout control board 2000 to the main control board 1000 will be described. First, the first transmission information is the same as the first transmission command from the main control board 1000. Next, the second transmission information includes a fixed value, payout device abnormality information, and prize ball payout information. Specifically, bits 7 to 2 are fixed to 010101 (identification information indicating that the information is transmission / reception completion information). Next, bit 1 relates to the dispensing device abnormality, “0” means that the dispensing device is not malfunctioning, and “1” means that the dispensing device is malfunctioning. Next, bit 0 relates to a prize ball being paid out, “0” means that a prize ball is not being paid out, and “1” means that a prize ball is being paid out. In the best mode, a certain command is regularly transmitted to the payout control board side. Accordingly, even when the prize ball is being paid out on the payout side, a command or the like whose number of prize balls is “0” is transmitted. If the payout side is abnormal, the payout device may actually be payable, so in this best mode, a normal command (a predetermined number of sets when there is a prize ball payout) is transmitted. .

  As shown in the <Modification> column of FIG. 7, information (first information) related to the first byte transmitted from the payout control board 2000 side to the main control board 1000 side is sent from the main control board 1000 side. The 1's complement or 2's complement of the first command may be used. The 2's complement is generated by adding 1 after performing bit inversion of the first command.

<Functional configuration>
Next, the function of the pachinko gaming machine according to the best mode will be described with reference to the functional block diagram of FIG. The functions mainly shown here are the functions between the main control board 1000 and the payout control board 2000, the functions between the payout control board 2000 and the card unit C, the main control board 1000 / the hall computer HC, which are particularly related to the present invention. It is a function between.

(Main control board 1000)
First, the main control board 1000 is a transmission / reception control means 1100 for controlling transmission / reception of commands and information between the game control means 1050 that controls the progress of the game and the payout control board 2000 and the like, and information transmission to the hall computer HC. A transmission / reception state temporary storage means 1200 for temporarily storing a state relating to transmission / reception between the main control board 1000 and the payout control board 2000, and whether a payout command from the main control board 1000 has been normally transmitted to the payout control board 2000 side. Normal transmission determination means 1300 for determining whether or not, error control means 1400 for executing control of errors related to transmission / reception on the main control board 1000 side, and power resumption when power is cut off due to a power failure or the like A backup to restore the gaming machine to the power-off state when the power is turned on. Includes a means 1500, the. The game control means 1050 has a well-known configuration that the conventional machine has. For example, taking the case of a conventional type 1 gaming machine as an example, the game control means 1050 is based on random number generation, random number acquisition triggered by the starting entrance ball, lottery using the acquired random number, lottery result When a symbol (special symbol) variation or a lottery is won, a well-known process such as a special game for opening a variable winning opening that is normally closed is executed. Hereinafter, each characteristic means of the present invention will be described in detail.

  First, the transmission / reception control means 1100 includes transmission control means 1110 that controls transmission from the main control board 1000 to the payout control board 2000 and the hall computer HC, and reception control that controls reception from the payout control board 2000 to the main control board 1000. Means 1120.

  Here, the transmission control means 1110 has a payout control side transmission control means 1111 that controls transmission to the payout control board 2000, and an HC side transmission control means 1114 that controls transmission to the hall computer HC. ing. Hereinafter, it demonstrates in order.

  First, the payout control side transmission control means 1111 sends two commands (first command and second command) to be sent to the payout control board 2000 for one prize ball payout to a predetermined temporary storage means (transmission command temporary described later). Transmission command setting means 1111a for setting in the storage means 1111c), transmission command management means 1111b for managing the set transmission command including transmission command transmission completion / uncompleted, and transmission to the payout control board 2000 2 There is a transmission command temporary storage unit 1111c that temporarily stores one command until the winning ball payout corresponding to the command is completed. Note that the transmission command setting means 1111a refers to the game side information temporary storage means 1121a and determines whether or not a winning ball payout command can be set, as will be described later in the processing item. Function. The transmission command temporary storage unit 1111c further includes a first command temporary storage area 1111c-1 for temporarily storing the first command, a second command temporary storage area 1111c-2 for temporarily storing the second command, have.

  Next, when the HC-side transmission control unit 1114 receives a pitch signal from the winning hole sensor S, the HC side transmission control unit 1114 plans to cumulatively add the winning ball corresponding to the winning hole and a counter value of a later-described scheduled payout number related counter 1114c. When the counter value of the payout amount adding means 1114a and a later-described expected payout number related counter 1114c reaches a predetermined value (for example, 10), the predetermined value (for example, 10) is subtracted from the counter value of the later-described expected payout number related counter 1114c. A planned payout number subtracting unit 1114b and a planned payout number related counter 1114c for temporarily storing the planned payout number are provided. As will be described later in the processing item, when the count value of the scheduled payout number related counter 1114c reaches a predetermined value, information to the hall computer HC (scheduled payout amount = predetermined number (for example, 10)). The pulse signal corresponding to the minute) is transmitted.

  Further, the reception control means 1120 receives information from the game side reception control means 1121 for receiving game information including prize ball information (entrance signal) and an upper plate full signal, and information from the payout control board 2000 side. Payout control side reception control means 1122 for this purpose. Here, the game-side reception control means 1121 has a game-side information temporary storage means 1121a for temporarily storing information on prize balls for which payout processing has not been executed and upper dish full tank information. Also, the payout control side reception control means 1122 includes a payout control side reception data management means 1122a that manages the information including temporary storage and deletion of information transmitted from the payout control board 2000 side, and a payout control board 2000. The payout control side received data temporary storage means 1122b in which the information transmitted from the side is temporarily stored for the first time and the data temporarily stored in the payout control side received data temporary storage means 1122b are processed in subsequent processing (for example, normally Payout command correspondence information temporary storage means 1122c for storing the command for determination).

  Next, the transmission / reception state temporary storage unit 1200 includes a main control side transmission / reception state temporary storage unit 1210 for temporarily storing a transmission / reception state (ST = 0 to 4) on the main control board 1000 side, and a payout control board 2000 side. A payout control side payout state temporary storage means 1220 for temporarily storing the payout state (for example, whether or not paying out or whether or not a payout abnormality has occurred).

  Next, the normal transmission determination means 1300 indicates the time from when a command is transmitted from the main control board 1000 until reception of information corresponding to the command (information corresponding to the command transmitted from the payout control board 2000). Communication time management means 1310 for management is provided. Here, the communication time management means 1310 further includes a timer 1311 for counting time.

  Next, the error control means 1400 monitors game-related errors including errors related to transmission / reception on the main control board 1000 side (for example, door opening errors other than errors related to transmission / reception) and game-related errors including error status related to transmission / reception. Error flag management means 1420 for managing errors is provided. Here, the error flag management unit 1420 further includes an error flag temporary storage unit 1421 for temporarily storing an on / off state of a game-related error flag including an error flag related to transmission.

  Next, in the case where the power supply is cut off due to the occurrence of a power failure or the like, the backup means 1500 is designed to return the state of the gaming machine to the state before the power cut off when the power is turned on again. Backup information temporary storage means 1510 for storing temporarily stored data, and backup power supply means for supplying backup voltage to the backup information temporary storage means and holding the data even after the gaming machine is turned off 1520. Note that writing to the backup information temporary storage unit 1510 is executed when the power is turned off by a normal process, and on the contrary, restoration of each information written to the backup information temporary storage unit 1510 is executed in the main process when the power is turned on. .

(Discharge control board 2000)
Next, the payout control board 2000 includes transmission / reception control means 2100 that controls transmission / reception of commands and information with the main control board 1000 side, the card unit C side, and the like, and errors related to transmission / reception on the payout control board 2000 side. Error control means 2200 for executing control, and payout control means 2300 for receiving a prize ball payout command or a lending command and executing payout processing of a predetermined number of game balls. Hereinafter, each means will be described in detail.

  First, the transmission / reception control unit 2100 transmits reception information to the main control board 1000 and the card unit C, and reception control means 2110 that controls reception of information (for example, commands and signals) from the main control board 1000 and the card unit C. Transmission control means 2120 for controlling the control.

  Here, the reception control unit 2110 controls reception of information (for example, signals) from the main side reception control unit 2111 that controls reception of information (for example, commands) from the main control board 1000 and the card unit C. Card unit side reception control means 2112. The main reception control means 2111 is transmitted from the main control board 1000 and the main reception data management means 2111a for managing the information including temporary storage and erasure of information received from the main control board 1000. Temporarily stores the received data temporarily stored in the main-side received data temporary storage unit 2111b until the predetermined condition is satisfied (for example, the second command is received). A payout command correspondence information temporary storage unit 2111c for temporarily storing the first command until the first command is received.

  Further, the card unit side reception control means 2112 is transmitted from the card unit C side with the card unit side reception data management means 2112a which manages the management processing of the information including temporary storage and deletion of the information received from the card unit C. Card unit side received information temporary storage means 2112b, in which the received information is temporarily stored for the first time.

  Next, the error control means 2200 has error flag management means 2220 for monitoring errors related to transmission / reception on the payout control board 2000 and managing error states related to transmission / reception. Here, the error flag management unit 2220 further includes an error flag temporary storage unit 2221 for temporarily storing an on / off state of an error flag related to transmission.

  Next, the payout control means 2300 includes payout information temporary storage means 2310 for temporarily storing a prize ball payout command from the main control board 1000, information relating to a ball rental request from the card unit C, and the game ball payout control. Payout processing related information temporary storage means 2320 for temporarily storing such information, payout abnormality determination means 2340 for determining whether or not an abnormal payout smaller than the planned payout number has occurred, and waiting between split payouts Wait time control means 2350 for setting the time. In this best mode, a case where the number of payouts is less than the planned payout is defined as “abnormal payout”, but the present invention is not limited to this. Also good.

  Here, the payout information temporary storage means 2310 is a buffer A for temporarily storing the upper plate full tank information, and a buffer B for temporarily storing the number of prize balls based on the prize ball payout command from the main control board 1000 side. And a buffer C for temporarily storing the number of payouts based on the renting request from the card unit C.

  The payout processing related information temporary means 2320 includes a payout state flag temporary storage means 2321 for temporarily storing a state related to payout (for example, whether payout is being performed or whether a payout abnormality has occurred); A payout counter 2322 in which the number of game balls to be paid out is set at the time of payout processing, and an abnormality for counting the number of abnormal payouts less than the planned payout number in divided payout (unit divided into multiple payouts) A payout counter 2323, an abnormal payout counter 2324 for counting the number of abnormal payouts in one payout, and a ball pass wait for measuring a ball passage waiting time (payout motor stop time) between divided payouts Temporary storage of divided payout number for temporarily storing the time payout 2325 and the divided payout number designated from the main control board 1000 Has a 2326, a.

"processing"
Next, the ball payout control process executed in the pachinko gaming machine according to the best mode will be described with reference to the flowcharts of FIGS. 9 to 17 are flowcharts showing processing on the main control board 1000 side. 18 to 24 are flowcharts showing processing on the payout control board 2000 side. Hereinafter, it will be described in order.

{Processing on the main control board side (communication processing with the payout control board)}
First, the communication process with the payout control board 2000 executed on the main control board 1000 side will be described with reference to the flowcharts of FIGS. First, FIG. 9 is a flowchart of scheduled interrupt processing related to communication control, which is executed on the main control board 1000 side. First, in step 1100, the main control board 1000 executes an error monitoring process for bidirectional communication (serial communication) between the main control board 1000 and the payout control board 2000. Next, in step 1200, the main control board 1000 executes a serial communication data reception monitoring process for monitoring whether information is received from the payout control board 2000. Next, in step 1300, the main control board 1000 executes a payout command request process for setting a payout related command (first command and second command) to be sent to the payout control board 2000 to the transmission command temporary storage means 1111c. . In step 1400, the main control unit 1000 executes a payout command transmission process for transmitting the payout command set in the transmission command temporary storage unit 1111c to the payout control board 2000, and returns to step 1100. Hereinafter, the processing of each subroutine will be described in detail.

  First, FIG. 10 is a flowchart of the serial communication error monitoring process in step 1100 which is the subroutine of FIG. First, in step 1102, the error control unit 1400 refers to the error flag temporary storage unit (status register) 1421 and determines whether an overrun error (AORE), a framing error (AFE), and a parity error (APE) have occurred. Specifically, it is monitored whether or not these flags are on. Here, the overrun error is a case where the next data is received before the already received data is read by the user program. Specifically, the overrun error is temporarily stored in the payout control side received data temporary storage unit 1122b. An error that occurs when the payout control side reception control means 1121 receives the next data before the information from the payout control board 2000 is read and moved to the payout command correspondence information temporary storage means 1122c side. is there. The framing error is an error that occurs when 0 is detected in the stop bit of the received payout command corresponding data. The parity error is an error that occurs when the parity of the received data does not match the parity bit of the data. When an error occurs, the error flag management unit 1420 executes a process of setting 1 to the corresponding error bit in the error flag temporary storage unit (status register) 1421. In step 1104, the error control unit 1400 refers to the error flag temporary storage unit 1421 and determines whether any error is detected. In the case of Yes in step 1104, in step 1106, the error flag management unit 1420 turns off the error flag that is turned on in the error flag temporary storage unit 1421 (clears it to 0), and cancels the serial communication error. Further, in step 1108, the error control means 1400 clears the data received by serial communication (data temporarily stored in the payout control side received data temporary storage means 1122b) and performs the next processing (serial communication of step 1200). Move to data reception monitoring process. On the other hand, also in the case of No in step 1104, the processing shifts to the next processing (serial communication data reception monitoring processing in step 1200).

  Next, FIG. 11 is a flowchart of the serial communication data reception monitoring process in step 1200 which is the subroutine of FIG. First, in step 1202, the payout control side received data management means 1122a refers to the payout control side received data temporary storage means 1122b (data reception monitoring process). In step 1204, the payout control side received data management means 1122a determines whether or not the payout command corresponding data has been received from the payout control board 2000 side. In the case of Yes in step 1204, in step 1206, the payout control side received data management means 1122a uses the payout command corresponding data temporarily stored in the payout control side received data temporary storage means 1122b as the payout command information related temporary storage means. 1122c, and the process proceeds to the next process (payout command request process in step 1300). Even in the case of No in step 1204, the process proceeds to the next process (payout command request process in step 1300).

  Next, FIG. 12 is a flowchart of the payout command request process in step 1300 which is a subroutine of FIG. First, in step 1302, the transmission command setting unit 1111a refers to the main control side transmission / reception state temporary storage unit 1210 (inspection of an untransmitted command). In step 1304, the transmission command setting unit 1111a determines whether the processing state temporarily stored in the main control side transmission / reception state temporary storage unit 1210 is ST = 0, that is, all previous transmission commands have been transmitted. Therefore, it is determined whether or not an unsent command does not exist. In the case of Yes in step 1304, in step 1306, the transmission command setting unit 1111a sets the identification code (100) in the upper 3 bits of the transmission data in the first command temporary storage area 1113a in the transmission command temporary storage unit 1111c. . This “100” is a fixed value and means that this command is the first command. Next, in step 1308, the transmission command setting means 1111a refers to the game side information temporary storage means 1121a, and considers whether or not the full signal from the full tray switch 15 has been received. Set the full state of. Incidentally, “1” means full, and “0” means not full. Next, in step 1310, the transmission command setting unit 1111a refers to the payout control side payout state temporary storage unit 1220 (inspects the prize ball state of the payout control). In step 1312, the transmission command setting unit 1111a determines whether or not the payout control board 2000 is paying out a prize ball. In the case of Yes in step 1312, in step 1314, the transmission command setting means 1111a refers to the game side information temporary storage means 1121a and sets the number of winning balls corresponding to the next winning ball payout to bits 0-3. As for the number of winning balls, the number of winning balls for each winning opening is inspected, and the number of winning balls for the winning ball to be paid this time is subtracted, and then the number of winning balls corresponding to the winning opening is set. To do. On the other hand, in the case of No in step 1312, that is, when the payout control device is in the winning ball, the number of winning balls is not set to bits 0 to 3 (therefore, all bits remain 0). The process proceeds to step 1316. Steps 1306 to 1314 described above are the setting process for the first command.

  The following steps 1316 to 1322 are the setting process for the second command. Specifically, in step 1316, the transmission command setting unit 1111a stores the identification code (in the upper 4 bits of the transmission data in the second command temporary storage area 1113 of the transmission command temporary storage unit 1113 as transmission data of the second command. 1111) is set. This “1111” is a fixed value and means that this command is the second command. Next, in step 1318, the transmission command setting unit 1111a refers to the error flag management unit 1420 and determines whether or not a predetermined error (for example, a door opening error) has occurred. In the case of Yes in step 1318, in step 1320, the transmission command setting unit 1111 sets a predetermined number A (for example, three) divided payout numbers in the bit 0 to 0 in the second command temporary storage area 1113 of the transmission command temporary storage unit 1113. 3. Then, the process proceeds to the next process (payout command transmission process in step 1400). The predetermined number A is set in advance for each model of the main control board, for example. On the other hand, if No in step 1318, that is, if a predetermined error has occurred, the transmission command setting unit 1111 stores the second command temporary storage area 1113 in the transmission command temporary storage unit 1113 in step 1322. A predetermined number B (for example, 1) of divided payouts is set to bits 0 to 3, and the process proceeds to the next process (payout command transmission process in step 1400). It should be noted that the predetermined number A> the predetermined number B, and the predetermined number B is a divided payout number that makes the payout speed extremely slow when a predetermined error occurs and fraud etc. can be executed. Is preferred. Even in the case of No in step 1304, the process proceeds to the next process (payout command transmission process in step 1400).

  Next, FIG. 13 is a flowchart of the payout command transmission process in step 1400 which is a subroutine of FIG. First, in step 1402, the main control board 1000 refers to the main control side transmission / reception state temporary storage unit 1210 (inspects the command transmission state). When the ST in the main control side transmission / reception state temporary storage unit 1210 is “0”, the main control board 1000 proceeds to step 1400-1 to execute the first command transmission process, and the main control side transmission / reception is performed. When the ST in the state temporary storage unit 1210 is “1”, the process proceeds to step 1400-2 to execute the first information reception confirmation process, and the ST in the main control side transmission / reception state temporary storage unit 1210 is “2”. ”, The process proceeds to step 1400-3 to execute the second command transmission process. If the ST in the main control side transmission / reception state temporary storage means 1210 is“ 3 ”, the process proceeds to step 1400-4. The second information reception confirmation process is executed, and the process proceeds to the next process (serial communication error monitoring process in step 1100).

  Next, FIG. 14 is a flowchart of the first command transmission process (second command transmission process) in step 1400-1, which is the subroutine of FIG. Note that the processing in step 1400-3 is basically the same as the processing in step 1400-1 (the parentheses indicate the processing in step 1400-3). First, in step 1402-1 (step 1402-3), the payout control side transmission control unit 1111 refers to the main control side transmission / reception state temporary storage unit 1210 and checks the transmission state of serial communication. Next, in step 1404-1 (step 1404-3), the payout control side transmission control unit 1111 determines whether or not the transmission state of the serial communication can be transmitted. In the case of Yes in step 1404-1 (step 1404-3), in step 1406-1 (step 1406-3), the error flag management unit 1420 turns off the communication error flag in the error flag temporary storage unit 1421 and performs communication. Execute the process to cancel the error. Here, the “communication error flag” is a flag that is turned on when the transmission of the first command (or the second command) from the main control board 1000 side to the payout control board 2000 side is reserved. . In step 1408-1 (step 1408-3), the payout control side transmission control unit 1111 stores the first command temporarily stored in the first command temporary storage area 1111c-1 of the transmission command temporary storage unit 1111c. Transmission data (transmission data of the second command temporarily stored in the second command temporary storage area 1111c-2 of the transmission command temporary storage unit 1111c) is transmitted. Next, in step 1410-1 (step 1410-3), the communication time management unit 1310 sets the reception waiting timeout time in the timer 1311. In step 1412-1 (step 1412-3), the main control board 1000 sets the ST in the main control side transmission / reception state temporary storage unit 1210 to “1” (“3”), and performs the next processing (step 1100 serial communication error monitoring processing). On the other hand, in the case of No in step 1404-1 (step 1404-3), in step 1414-1 (step 1414-3), the error flag management unit 1420 turns on the communication error flag in the error flag temporary storage unit 1421. After executing the process of setting a communication error, the process proceeds to the next process (serial communication error monitoring process in step 1100).

  Next, FIG. 15 is a flowchart of the first information reception confirmation process in step 1400-2 which is the subroutine of FIG. First, in step 1402-2, the payout control side reception control means 1122 determines whether or not the payout command correspondence information temporary storage means 1122c is not 0, that is, whether or not any information is received from the payout control board 2000 side. judge. In the case of Yes in step 1402-2, in step 1404-2, the normal transmission determination unit 1300 transmits the transmission data of the first command temporarily stored in the first command storage area 1111c-1 of the transmission command temporary storage unit 1111c. The contents of the payout command correspondence information transmitted from the payout control board 2000 side temporarily stored in the payout command correspondence information temporary storage unit 1122c are compared. In step 1406-2, the normal transmission determination unit 1300 determines whether the comparison result in step 1402-2 matches. In the case of Yes in step 1406-2, in step 1408-2, the error flag management unit 1420 executes processing for turning off the communication error flag in the error flag temporary storage unit 1420 and canceling the communication error. In step 1410-2, the main control board 1000 sets ST in the main control side transmission / reception state temporary storage means 1210 to “2”, and proceeds to the next processing (serial communication error monitoring processing in step 1100). To do.

  On the other hand, if No in step 1402-2, that is, if no information is received from the payout control board 2000 side, the communication time management means 1310 waits for reception in the timer 1311 in step 1412-2. Subtract the timeout time. In step 1414-2, the error flag management unit 1420 refers to the timer 1311 and determines whether or not a timeout has occurred. In the case of Yes in step 1414-2, in step 1416-2, the error flag management unit 1420 turns on the communication error flag in the error flag temporary storage unit 1421 and executes processing for setting a communication error. Next, in step 1418-2, the main control board 1000 sets the ST in the main control side transmission / reception state temporary storage means 1210 to "0", and proceeds to the next process (serial communication error monitoring process in step 1100). Transition. With this process, if the information is not received for a predetermined time from the payout control board 2000 after the first command is transmitted, the first command is transmitted again.

  Next, FIG. 16 is a flowchart of the second command reception confirmation process in step 1400-4 which is the subroutine of FIG. First, in step 1402-4, the normal transmission determination unit 1300 determines whether or not the payout command correspondence information temporary storage unit 1122c is not 0, that is, whether or not any information is received from the payout control board 2000 side. . In the case of Yes in step 1402-4, in step 1404-4, the normal transmission determination unit 1300 transmits the second command transmission data temporarily stored in the second command temporary storage area 1111c-2 of the transmission command temporary storage unit 1111c. The contents of (upper 6 bits) and the information (upper 6 bits) transmitted from the payout control board 2000 side temporarily stored in the payout command related information temporary storage means 1122c are compared. In step 1406-2, the normal transmission determination unit 1300 determines whether the comparison result in step 1402-2 matches. In the case of Yes in step 1406-4, in step 1408-4, the error flag management unit 1420 turns off the communication error flag in the error flag temporary storage unit 1421 and executes processing for canceling the communication error. In step 1410-4, the payout control side received data management means 1122a refers to the information (lower 2 bits) transmitted from the payout control board 2000 side temporarily stored in the payout command related information temporary storage means 1122c. Whether or not a prize ball is being paid out (ascertained from bit 0) and whether or not the payout device is abnormal (ascertained from bit 1) are temporarily stored in the payout control side payout state temporary storage means 1220. In step 1412-4, the main control board 1000 sets the ST in the main control side transmission / reception state temporary storage unit 1210 to “0” and proceeds to the next processing (serial communication error monitoring processing in step 1100). To do.

  On the other hand, if No in step 1402-4, that is, if no information is received from the payout control board 2000, the communication time management means 1310 waits for reception in the timer 1311 in step 1414-4. Subtract the timeout time. In step 1416-4, the error flag management unit 1420 refers to the timer 1311 and determines whether or not a timeout has occurred. In the case of Yes in step 1416-4, in step 1418-4, the error flag management unit 1420 turns on the communication error flag in the error flag temporary storage unit 1421 and executes processing for setting a communication error. Next, in step 1420-4, the main control board 1000 sets the ST in the main control side transmission / reception state temporary storage means 1210 to “2” and proceeds to the next process (serial communication error monitoring process in step 1100). Transition. By this process, if the information is not received for a predetermined time from the payout control board 2000 after the second command is transmitted, the second command is transmitted again.

{Processing on the main control board side (communication processing with hall computer)}
Next, FIG. 17 is a flowchart showing the management process of the scheduled prize ball payout number and the process of transmitting the scheduled prize ball payout number information to the hall computer HC. First, in step 1502, the HC side transmission control means 1114 refers to the game side information temporary storage means 1121a, and determines whether or not the entry information for a new winning opening has been received. In the case of Yes in step 1502, in step 1504, the HC-side transmission control unit 1114 temporarily stores the number of prize balls (n) corresponding to the winning slot in the payout process related information temporary storage unit 2320. Next, in step 1506 and step 1508, the scheduled payout number adding means 1114a subtracts 1 from the n value temporarily stored in the payout processing related information temporary storage means 2320, and then the counter value of the planned payout number related counter 1114c. 1 is added to (C value). In step 1510, the HC-side transmission control unit 1114 refers to the scheduled payout number related counter 1114c and determines whether or not the counter value (C value) has reached a predetermined number (for example, 10). In the case of Yes in Step 1510, in Step 1512, the HC side transmission control means 1114 outputs a pulse signal corresponding to the predetermined number (for example, 10) via the external relay terminal board. The hall computer HC that has received this information knows that a prize ball corresponding to the predetermined number (for example, 10) is scheduled to be paid out before the prize ball is actually paid out. Become. In step 1514, the planned payout number subtraction unit 1114b subtracts the predetermined number from the counter value (C) of the planned payout number related counter 1114c. In step 1516, the HC side transmission control unit 1114 refers to the game side information temporary storage unit 1121a and determines whether the n value is 0 or not. If YES in step 1516, the process proceeds to the next process. In the case of No in step 1502 and in the case of No in step 1510, the process proceeds to the next process, and in the case of No in step 1516, the process proceeds to step 1506. In the best mode, the counter value of the scheduled payout number related counter 1114c is incremented. However, the present invention is not limited to this, and a signal is transmitted when the counter value is decremented to 0 and is again set to the predetermined value. May be set. Further, as the scheduled payout number related counter 1114c, a signal that outputs a signal (divided pulse) every time a predetermined number is counted may be used.

(Processing on the payout control board side)
Next, control processing executed on the payout control board 2000 side will be described with reference to the flowcharts of FIGS. First, FIG. 18 is a flowchart of processing relating to communication processing with the main control board 1000 and communication processing with the lending device such as a gaming machine (card unit) executed on the payout control board 2000 side. First, in step 2100, the payout control board 2000 executes communication processing with the main control device 1000 side. Next, in step 2200, the payout control board 2000 executes communication processing with the card unit C. In step 2300, the payout control board 2000 drives the payout unit to execute payout control of the game ball, and returns to step 2100. Hereinafter, the processing of each subroutine will be described in detail.

  Next, FIG. 19 is a flowchart of the communication process with the main control apparatus 1000 side in step 2100 which is the subroutine of FIG. First, in step 2100-1, the payout control board 2000 executes an error monitoring process for bidirectional communication (serial communication) between the main control board 1000 and the payout control board 2000. Next, in step 2100-2, the payout control board 2000 executes serial communication data reception monitoring processing for monitoring whether information is received from the main control board 1000. Next, in step 2100-3, the payout control board 2000 executes payout command correspondence information transmission processing for sending information corresponding to the payout command received from the main control board 1000 side to the main control board 1000 side. Return to -1. Hereinafter, the processing of each subroutine will be described in detail.

  First, FIG. 20 is a flowchart of serial communication error monitoring processing in step 2100-1, which is the subroutine of FIG. First, in step 2102-1, the error control unit 2200 refers to the error flag temporary storage unit (status register) 2221, and an overrun error (AORE), a framing error (AFE), and a parity error (APE) occur. It is monitored whether or not, specifically, whether or not these flags are on. In step 2104-1, the error control unit 2200 determines whether any error has been detected. When an error occurs, the error flag management unit 2220 executes a process of setting 1 to the corresponding error bit in the error flag temporary storage unit 2221. If YES in step 2104-1, in step 2106-1, the error flag management unit 2220 turns off the error flag that is on in the error flag temporary storage unit 2221 (clears it to 0), and serial communication. Cancel the error. Further, in step 2108-1, the error control means 2200 clears the data received by serial communication (data temporarily stored in the main-side received information temporary storage means 2111b) and performs the next processing (in step 2100-2). Shift to serial communication data reception monitoring process. On the other hand, also in the case of No in step 2104-1, the processing shifts to the next processing (serial data reception monitoring processing in step 2100-2).

  Next, FIG. 21 is a flowchart of the data reception monitoring process of serial communication in step 2100-2 which is the subroutine of FIG. First, in step 2102-2, the main-side received data management unit 2111a refers to the main-side received information temporary storage unit 2111b (data reception monitoring process). In step 2104-2, the main-side received data management unit 2111a determines whether or not a payout command has been received from the main control board 1000 side. In the case of Yes in step 2104-2, in step 2106-2, the main side received data management means 2111a uses the payout command temporary storage means to store the payout command correspondence data temporarily stored in the main side received information temporary storage means 2111b. 2111c, and proceeds to the next process (payout related information transmission process of step 2100-3). In addition, also when it is No at step 2104-2, it transfers to the following process (payout relevant information transmission process of step 2100-3).

  Next, FIG. 22 is a flowchart of the payout related information transmission / reception process of step 2100-3 which is a subroutine of FIG. First, in step 2102-3, the payout control board 2000 determines whether or not the payout command temporary storage unit 2111c is not 0, that is, whether or not any information is received from the main control board 1000 side. In the case of Yes in Step 2102-3, in Step 2104-3, the main-side reception control unit 2111 determines whether or not the upper 3 bits temporarily stored in the payout command temporary storage unit 2111c is “100”, that is, It is determined whether or not the command received from the main control board 1000 this time is one command. In the case of Yes in step 2104-3, in step 2106-3, the transmission control unit 2120 transmits the information temporarily stored in the payout command temporary storage unit 2111c to the main control board 1000 side. In step 2108-3, the main-side received data management unit 2111 a stores the pan full state in the buffer A based on the presence / absence of receiving the pan full signal. Next, in step 2110-3, the main-side received data management unit 2111a stores the prize ball number information in the buffer B based on the information (particularly bits 3 to 0) temporarily stored in the payout command temporary storage unit 2111c. Then, the process proceeds to the next process (communication process with the card unit in step 2200).

  On the other hand, in the case of No in step 2104-3, in step 2112-3, the main-side reception control unit 2111 determines whether the upper 4 bits of the command temporarily stored in the payout command temporary storage unit 2111c is “1111”. That is, it is determined whether or not the command received from the main control board 1000 this time is two commands. In the case of Yes in step 2112-3, in step 2113-3, the payout control means 2300 divides into divided payout number temporary storage means 2326 based on the lower 4 bits of the command temporarily stored in the payout command temporary storage means 2111c. Set the number of payouts (see Table 1). In step 2114-3, the transmission control means 2120 confirms whether or not there is an abnormality in the payout device and whether or not a prize ball is being paid out prior to transmission of the confirmation information to the main control board 1000 side. . In step 2116-3, the transmission control means 2120, as confirmation information to the main control board 1000 side, bits 7 to 2 are fixed values (“010101”), bit 1 is a dispensing device abnormality, bit 0 is a prize ball Information indicating that the payout is in progress is transmitted. In step 2118-3, the payout control board 2000 temporarily stores the contents of the buffer A and the buffer B in the payout processing related information temporary storage unit 2320 as the tray full information and the number of prize balls. In response to the setting of these pieces of information in the payout process related information temporary storage means 2320, a payout process based on the contents of the set is executed in the payout control process described later. In step 2120-3, the payout control board 2000 clears the buffer A and the buffer B, and proceeds to the next process (payout control process in step 2400).

  Next, FIG. 23 is a flowchart of the communication process with the card unit C in step 2200 which is the subroutine of FIG. First, in step 2202, the payout control board 2000 refers to the payout processing related information temporary storage unit 2320 and determines whether or not the payout flag is off. Next, in step 2204, whether the payout control board 2000 has received ON of BRDY (card unit READY signal) and BRQ (table terminal lending request completion confirmation signal) with reference to the card unit side received information temporary storage unit 211 b. Determine whether or not. Here, BRDY is a signal indicating whether or not the card unit C is in a state in which it can make a lending request to the pachinko gaming machine, and is output from the card unit C to the pachinko gaming machine. This BRDY is normally at the H level. When the lending switch is operated, the BRDY shifts to the L level, and the L level state is maintained until the lending process is completed. BRQ is a signal for instructing the pachinko gaming machine from the card unit C to increase the number of game balls. This BRQ signal is normally at the H level, but the inversion to the L level is repeated a predetermined number of times in accordance with the operation of the lending switch. In this example, the inversion of the BRQ to the L level is a lending instruction for 100 yen, and a predetermined number (for example, 25 shots) of game balls is added to the pachinko gaming machine for each pulse signal. Next, in step 2206, the payout control board 2000 accesses the payout processing related information temporary storage means 2320 and turns on EXS. Here, EXS is a signal for informing the card unit C from the pachinko gaming machine that the BRQ signal has been received. This EXS is normally at the H level, shifts to the L level after a predetermined time from when the BRQ signal becomes the L level, and further returns to the H level in response to the shift of the BRQ signal to the H level. Next, in step 2208, the payout control board 2000 refers to the card unit side received information temporary storage means 2112b, and determines whether or not BRQ (table terminal lending request completion confirmation signal) is received within a predetermined time. To do. In the case of Yes in step 2208, in step 2210, the payout control board 2000 cancels the error if an error has occurred. Next, in step 2212, the payout control board 2000 sets a predetermined number (for example, 25 shots) in the buffer C. In step 2214, the payout control board 2000 determines whether or not a predetermined number of payouts have been completed, that is, whether or not the payout counter is zero. In the case of Yes in step 2214, in step 2216, the payout control board 2000 accesses the payout process related information temporary storage unit 2320, turns off EXS, and proceeds to the next process (payout control process in step 2300).

  If No in step 2202, that is, if the paying-out flag is on, the process proceeds to step 2214. On the other hand, in the case of No in step 2208, that is, when the BRQ signal is not received within the predetermined time, in step 2218, the payout control board 2000 sets an error and proceeds to step 2216. Further, in the case of No in step 2204 and step 2214, the process proceeds to the next process (payout control process in step 2300).

  Next, FIG. 24 is a flowchart of the communication process with the card unit in step 2300 which is the subroutine of FIG. First, in step 2302, the payout control means 2300 refers to the payout process related information temporary storage means 2320, and determines whether or not the divisional execution flag is off. Here, the “divided number of execution flag” is a flag that is turned on when a predetermined number of payouts are divided into a plurality of times and executed, but a certain number of divided times are still being executed. In the case of Yes in step 2302, in step 2304, the payout control means 2300 refers to the payout process related information temporary storage means 2320, and determines whether or not the division continuation flag is off. Here, the “division times continuation flag” is a flag that is turned on when there are division times even after a certain division time has ended. In the case of Yes in step 2304, in step 2306, the payout control means 2300 determines whether or not the payout ball data exists in the buffer C (whether it is not 0), that is, whether or not there is a loan request from the card unit C. Determine. In the case of Yes in step 2306, the payout control means 2300 sets the payout ball number temporarily stored in the buffer C in the payout counter 2322 in step 2308. In step 2310, the payout control unit 2300 clears the buffer C. In the best mode, the payout counter 2322 is decremented by 1 each time a game ball is detected by the count sensor 14 at the time of payout described below. On the other hand, in the case of No in step 2306, in step 2314, the payout control means 2300 determines whether or not the payout ball data exists in the buffer B (whether it is not 0), that is, based on the winning in the winning opening. It is determined whether or not there is a payout request. If Yes in step 2314, the payout control means 2300 sets the payout ball number temporarily stored in the buffer B in the payout counter 2322 in step 2316. In step 2318, the payout control unit 2300 clears the buffer B. This completes the processing for setting the number of game balls to be paid out. In step 2312, the waiting time control unit 2350 clears the abnormal abnormal payout counter 2324.

Next, a payout process for the set number of game balls is executed. Specifically, first, in step 2320, the payout control means 2300 refers to the buffer A and determines whether or not the tray is full. In the case of Yes in step 2320, in step 2322, the waiting time control means 2350 sets the ball passing waiting time (T _w ) in the ball passing waiting time counter 2325 based on the counter value in the abnormal payout number counter. In step 2323, the payout control unit 2300 starts the timer 2330. Next, at step 2324, the payout control means 2300 drives the payout motor 13 by a predetermined number of balls based on the divided payout number (N) set in the divided payout number temporary storage means 2326 and stops it. Here, the “predetermined number of balls” is N spheres (for example, three balls) when the payout remaining ball number N _rem is N or more, and the payout remaining ball number is N _rem less than N spheres. N _rem (for example, one or two balls). In step 2326, the payout control unit 2300 refers to the timer 2330 and determines whether or not the set ball passage waiting time (T _w ) has been reached after the payout motor 13 is stopped. In the case of Yes in step 2326, in step 2328, the payout control means 2300 determines whether or not a predetermined number of balls have passed through the count sensor 14 from the start of driving until now. In the case of Yes in step 2328, the payout control means 2300 determines that the payout has been normally made for the current driving for the predetermined number of balls, and proceeds to the next processing (step 2336). In this way, when the passage of a predetermined number of balls is confirmed, the next payout can be made without waiting for the ball passing waiting time (T _w ) even if the set ball passing waiting time (T _w ) has not been reached. The process (or the payout process relating to the next division) is executed. In the case of No in step 2328, that is, in a state where the set ball passage waiting time ( _Tw ) has not been reached and the passage confirmation of the predetermined number of balls has not yet been confirmed, the payout control means in step 2330. In step 2330, the divided execution flag in the payout process related information temporary storage unit 2320 is turned on, and the process proceeds to the next process (communication process with the main control device in step 2100).

On the other hand, in the case of No in step 2326, that is, when the ball passing waiting time (T _w ) is reached in a situation where the passage confirmation of the predetermined number of balls is not made, in step 2332, the payout abnormality determination means 2340 1 is added to the payout counter 2323. Next, in step 2334, the payout abnormality determination means 2340 adds 1 to the abnormal turnout counter 2324, and proceeds to the next process (step 2336). With the above, the payout process relating to the current divided time is completed.

  In step 2336, the payout control means 2300 refers to the payout counter 2322, and whether or not the counter value (remaining ball value) of the payout counter 2322 is 0, that is, whether or not all the planned ball numbers have been discharged. Determine. In the case of Yes in step 2336, in step 2338, the waiting time control means 2350 refers to the abnormal number of payout times counter 2324 and determines whether or not the counter value is 0, that is, pays all the balls that are scheduled this time. It is determined whether or not a payout abnormality has occurred at the time of dispensing. In the case of Yes in step 2338, in step 2340, the waiting time control means 2350 clears the abnormal payout counter 2323 and proceeds to the next process (communication process with the main control device in step 2100).

  On the other hand, in the case of No in step 2336, in step 2342, the payout control means 2300 turns on the division continuation flag in the payout process related information temporary storage means 2320 and performs the next process (the main control board in step 2100). To communication processing). If No in step 2304, that is, if the division continuation flag is on, in step 2344, the payout control means 2300 turns off the division continuation flag in the payout processing related information temporary storage means 2320. The process proceeds to the next process (step 2320).

  In the case of No in step 2320, that is, when the tray is full, in step 2346, the dispensing control means 2300 drives the dispensing motor 13 for one ball and waits for a predetermined time until the tray is not full. Stop (60 seconds) and go to Step 2336.

<Action>
Next, the operation according to the best mode of the present invention will be described with reference to the drawings. First, the first operation (payout command transmission by serial communication) according to the best mode of the present invention will be described with reference to FIGS. 25 to 26, and then with reference to FIGS. 27 to 28, The second action according to the best mode of the present invention (extension of the ball passage waiting time due to a payout abnormality) will be described, and with reference to FIG. 29, the third function according to the best mode of the present invention (to the hall computer). Will be explained).

(Transmission command transmission via serial communication)
<When normal>
First, the uppermost part of FIG. 25 is an operation diagram when transmission / reception is normally performed. First, the main control board 1000 transmits a payout command of the first command (identification information indicating that it is the first command, tray full information, prize ball number information) to the payout control board 2000 side as shown in FIG. To do. On the payout control board 2000 side, the first command transmitted from the main control means 1000 is normally received and stored in the payout command temporary storage means 2111c. Then, the payout control board 2000 transmits the same information as the received command (identification information indicating that it is the first command, tray full information, prize ball number information) to the main control board 1000 side. On the main control board 1000 side, the information (one command correspondence information) transmitted from the payout control means 2000 is normally received and stored in the payout command correspondence information temporary storage means 1122c. Here, on the main control board 1000 side, the first command transmission data temporarily stored in the first command storage area 1111c-1 of the transmission command temporary storage means 1111c and the one command received from the current payout control board 2000 side are associated. As a result of comparing the information and determining whether or not they are the same, it is determined that the current reception is normal reception. In response to this, the main control means 1000 transmits a payout command of the second command having the contents shown in FIG. 7 to the payout control board 2000 side. On the payout control board 2000 side, the second command transmitted from the main control unit 1000 is normally received. In response to this, the payout control unit 2000 executes award ball payout based on the content of the first command received from the main control board 1000 side. Furthermore, the payout control board 2000 transmits the information shown in FIG. 7 (identification information indicating that it is transmission / reception completion information, information relating to payout abnormality, and information relating to prize ball payout). On the main control board 1000 side, the information (two information) transmitted from the payout control means 2000 is normally received, and the current transmission / reception is completed.

<If abnormal, 1: 1 command receiving side error>
Next, the case where the first command received by the payout control unit 2000 is different from the first command transmitted by the main control unit 1000 will be described with reference to the second column of FIG. First, the main control board 1000 side gives the payout command of the first command (identification information indicating that it is the first command, tray full information, prize ball number information) to the payout control board 2000 side as shown in FIG. Send. However, on the payout control board 2000 side, information different from the first command transmitted from the main control means 1000 is received (for example, information having different prize ball number information) and stored in the payout command temporary storage means 2111c. Then, the payout control board 2000 transmits the same information as the received command (for example, information with different prize ball number information) to the main control board 1000 side. On the main control board 1000 side, the information (one command correspondence information) transmitted from the payout control means 2000 is normally received and stored in the payout command correspondence information temporary storage means 1122c. However, on the main control board 1000 side, the transmission data of the first command temporarily stored in the first command storage area 1111c-1 of the transmission command temporary storage means 1111c is compared with the information received from the current payout control board 2000 side. As a result of the determination whether or not they are the same, it is determined that the current reception is an erroneous reception. Accordingly, in response to this, the main control board 1000 transmits the first command having the same content again to the payout control board 2000 side. On the payout control board 2000 side, the first command transmitted from the main control means 1000 is normally received and stored in the payout command temporary storage means 2111c in the form of overwriting the first command received last time. Thereafter, it is the same as the normal case.

<In case of abnormality 2: Abnormality on receiving side of 1st command>
Next, a case where the payout control unit 2000 cannot normally receive the first command will be described with reference to the third column in FIG. First, the main control board 1000 side gives the payout command of the first command (identification information indicating that it is the first command, tray full information, prize ball number information) to the payout control board 2000 side as shown in FIG. Send. However, on the payout control board 2000 side, information different from the first command transmitted from the main control means 1000 is received (for example, reception error) and discarded without being stored in the payout command temporary storage means 2111c. On the other hand, the main control board 1000 waits for information corresponding to the command (1-command correspondence information) to be transmitted from the payout control board 2000 after transmitting the first command, but for a predetermined time (T _max )), it is determined that the payout control board 2000 has received an error. In response, the main control board 1000 transmits the first command having the same content again to the payout control board 2000 side. Thereafter, it is the same as the normal case.

<In case of abnormality 3: Abnormal reception of 1st command>
Next, a case where the first information transmitted by the payout control unit 2000 is different from the first command transmitted by the main control unit 1000 will be described with reference to the fourth column of FIG. Basically, it is the same as “1 when abnormal”, but the difference is that the payout control board 2000 has normally received the first command, but the information corresponding to the command (1-command correspondence information) is the main. This is a case where the main control board 1000 receives erroneous information (for example, information with a different number of prize balls) different from the information corresponding to the normal first command when transmitted to the control board 1000 side. Other than that, it is the same as “Abnormal Case 1”.

<In case of abnormality 4: 1 Information receiving side abnormality>
Next, a case where the first information transmitted by the payout control unit 2000 is different from the first command transmitted by the main control unit 1000 will be described with reference to the fifth column of FIG. Basically, it is the same as “Abnormal Case 3”, except that the payout control board 2000 itself normally received the first command, but the information corresponding to the command (1 command correspondence information) is the main. This is a case where the main control board 1000 receives an abnormality (for example, a reception error) when transmitting to the control board 1000 side. Otherwise, it is the same as “Abnormal Case 3”.

<In case of abnormality 5: Abnormality on the second command receiving side>
Next, a case where the payout control unit 2000 cannot normally receive the second command will be described with reference to the first column of FIG. The process up to the transmission of the second command from the main control board 1000 is the same as the “normal case”, and will be described below. First, the main control board 1000 transmits a payout command of the second command having the contents shown in FIG. 7 to the payout control board 2000. However, on the payout control board 2000 side, information different from the second command transmitted from the main control means 1000 is received (incorrect fixed value information), and the information is stored in the payout command temporary storage means 2111c. Then, the payout control board 2000 transmits the same information as the received command to the main control board 1000 side. On the main control board 1000 side, the information (2 information) transmitted from the payout control means 2000 is normally received and stored in the payout command correspondence information temporary storage means 1122c. However, on the main control board 1000 side, the transmission data of the second command temporarily stored in the second command storage area 1111c-2 of the transmission command temporary storage means 1111 is compared with the information received from the current payout control board 2000 side. As a result of the determination whether or not they are the same, it is determined that the current reception is an erroneous reception. Accordingly, in response to this, the main control board 1000 transmits the second command again to the payout control board 2000 side. On the payout control board 2000 side, the second command transmitted from the main control unit 1000 is normally received. In response to this, the payout control unit 2000 executes award ball payout based on the content of the first command received from the main control board 1000 side. Then, the payout control board 2000 transmits the second command received this time to the main control board 1000 again. As a result, on the main control board 1000 side, the information (2 information) transmitted from the payout control means 2000 is normally received, and the current transmission / reception is completed.

<In case of abnormality 6: Abnormality on receiving side of second command>
Next, a case where the payout control unit 2000 cannot normally receive the second command will be described with reference to the second column of FIG. The process up to the transmission of the second command from the main control board 1000 is the same as the “normal case”, and will be described below. First, the main control board 1000 transmits a payout command of the second command having the contents shown in FIG. 7 to the payout control board 2000. However, on the payout control board 2000 side, information different from the second command transmitted from the main control means 1000 is received (for example, reception error) and discarded without being stored in the payout command temporary storage means 2111c. On the other hand, the main control board 1000 waits for information corresponding to the command (2-command correspondence information) to be sent from the payout control board 2000 side after sending the second command, but for a predetermined time (T _max )), it is determined that the payout control board 2000 has received an error. In response to this, the main side control board 1000 transmits the second command having the same content again to the payout control board 2000 side. Thereafter, it is the same as “5 if abnormal”.

<In case of abnormality 7: Abnormality on receiving side of second information>
Next, a case where the second information transmitted by the payout control unit 2000 is different from the second command transmitted by the main control unit 1000 will be described with reference to the third column of FIG. Basically, it is the same as “5 if abnormal”, but there are two differences. The first point is that the payout is executed when the payout control board 2000 normally receives the second command. Second, the payout control board 2000 itself received the second command normally, but when the information corresponding to the command (two information) is transmitted to the main control board 1000 side, the main control board 1000 receives an abnormal reception (for example, Incorrect fixed value information). Other than that, it is the same as “5 when abnormal”.

<An abnormal case 8: Abnormality on the second information receiving side>
Next, a case where the second information transmitted by the payout control unit 2000 is different from the second command transmitted by the main control unit 1000 will be described with reference to the fourth column of FIG. Basically, this is the same as “7 if abnormal”, but the difference is that the payout control board 2000 itself normally received the second command, but the information (2 information) corresponding to the command is sent to the main control board. This is a case where the main control board 1000 receives an abnormal reception (for example, reception error) when transmitting to the 1000 side. Other than that, it is the same as “Abnormal Case 7”.

(Extension of waiting time for ball passing due to abnormal withdrawal)
Next, with reference to FIG. 27, the state of extension of the ball passage waiting time due to the payout abnormality will be described. Here, in this example, a description will be given by taking as an example a process in which a payout control command for 25 balls is received from the card unit C and the payout control board 2000 pays out 25 balls at a time. First, in this example, the 25-ball payout is divided into a plurality of times, and a maximum of 3 balls are paid out in each division unit (split payout). Here, this divided payout unit is designated by a payout command (second command = 11110011) from the main control board 1000. A predetermined ball passage waiting time is set between the division units. Here, when there is a payout abnormality in a certain division unit, the subsequent ball passage waiting time becomes longer, and the ball passage waiting time becomes longer stepwise according to the number of past payout abnormalities recorded in the counter value. It is comprised so that it may become. Hereinafter, each case will be described in detail.

<In case of normal payment>
First, the first stage of FIG. 27 is an example of payout when there is no abnormality in the payout operation of 25 balls. In this way, a total of nine divided payouts of eight times of three-ball driving and one time of one-ball driving are executed. In any of the divided payouts, the ball during the payout operation and after the payout operation is executed. During the passage waiting time (T _o ), all the numbers of balls scheduled for the installment can be normally counted. For this reason, the shortest ball passage waiting time (T _o ) is maintained for any ball passage waiting time between any divided payouts.

<In case of abnormal withdrawal>
Next, the second stage of FIG. 27 is an example showing how the ball passage waiting time changes when there is an abnormal payout during a certain payout. When time series describing the figure, first, for the first split payout, in the drive time and the ball passing time after the drive time (T _o), only pay Spherical less than 3 balls which was scheduled It has not been issued. In response to this, a long T ₁ is is set than T _o Internally as the next sphere passing latency. Next, for the second divided payout, the three balls that have been scheduled are paid out within the driving time and the ball passing time (T ₁ ) after the driving time. Therefore, as the next sphere passing latency same T ₁ is is set as the previous. Next, for the third divided payout, only one ball, which is less than the planned three balls, is paid out within the payout motor driving time and the ball passing time (T ₁ ) after the driving time. In response to this, internally, T ₂ longer than T ₁ is set as the next ball passage waiting time. Next, with respect to the fourth divided payout, only two balls, which are fewer than the planned three balls, are paid out within the driving time and the ball passing time (T ₂ ) after the driving time. In response to this, the internal long T ₃ is set than T ₂ as the next sphere passing latency. In this example, since T ₂ is the longest ball passage waiting time, even in the fifth divided payout, the planned time 3 within the driving time and the ball passage waiting time (T ₂ ) after the driving time 3 Although only paid out by spherical less than a sphere, so that the T ₃ continues to be set in the subsequent ball passing time.

<In the case of an abnormal payment (when there is a normal payment at the time of partial payment)>
Next, the first stage in FIG. 28 shows the ball after a certain partial payout in a case where a normal payout is made at the time of a certain partial payout under a situation where the ball passing time is extended due to the abnormal payout being executed. It is an example which showed the mode of passage waiting time. Here, “payout motor (planned)” is a ball passage waiting time set internally, and “payout motor (actual)” is an actual ball passage waiting time. What should be noticed is the fifth and subsequent installments. First, the ball passage waiting time before the fifth divided payout is executed is “T ₂ ” which is an extended time. In the fifth divided payout, two balls are paid out within the payout motor driving time of the divided payout, and the remaining one ball is shorter than “T ₃ ” which is a scheduled ball passage waiting time. And “T _x ” longer than the shortest “T ₀ ” is paid out. In response to this, although the ball passage waiting time still remains “T ₃ -T _x ”, the sixth divided payout is immediately executed. In the sixth divided payout, two balls are paid out within the payout motor driving time of the divided payout, and the remaining one ball is shorter than “T ₃ ” which is a scheduled ball passage waiting time. And, it is paid out in a time shorter than the shortest “T ₀ ”. In this case, the seventh divided payout is executed after waiting for the shortest “T ₀ ”. In this way, when the number of game balls planned before reaching the scheduled ball passage waiting time is paid out, the next ball waiting time does not wait until the next ball passing waiting time is reached. Perform payout.

<In the case of abnormal payment (when all previous payments were normal)>
Next, the second stage of FIG. 28 is an example showing a state in which the ball passage time returns to the normal state under the situation where the ball passage time is extended because of the abnormal payout. Here, “payout motor (planned)” is a ball passage waiting time set internally, and “payout motor (actual)” is an actual ball passage waiting time. As can be seen from this figure, the ball passing waiting time scheduled for the “previous payout” is “T ₂ ”, but both are scheduled payouts within the time (and the normal ball passing waiting time “T ₀ ”). (Although not shown, scheduled payout is executed for all installment payouts constituting “previous payout”). In response to this, in the “current payout”, as shown in “payout motor (scheduled)”, the scheduled ball passage waiting time returns from “T ₂ ” to “T ₀ ”.

(Scheduled payout information transmission to hall computer)
Next, referring to the timing chart of FIG. 29, a description will be given of the scheduled payout number information transmission to the hall computer, which is the third action of the pachinko gaming machine according to the best mode. First, the item of “conventional prize ball payout pulse” in the upper part of the drawing shows the transmission timing of prize ball payout information to the hall computer in the prior art. Here, from the transmission timing of the prize ball payout information to the hall computer in the prior art, as shown in the figure, the predetermined number (10 balls in this example) is actually paid out at the timing when it is paid out. Each time it reaches, a prize ball payout pulse is output to the hall computer. By the way, in this prior art, as can be seen from the first half of the figure, in a non-special game, unless a payout error occurs, there is a large amount of time between the timing of entering the winning opening and the actual payout timing. There is no deviation (circled numbers 1 to 4 in the figure). However, even during non-special games, when a payout error occurs, a large time difference occurs between the timing when the player enters the winning opening and the actual payout timing (circled number 5 in the figure). And as you can see from the second half of the figure, after the special game transition, the payout of the winning ball cannot catch up, and there is a big time gap between the timing of entering the winning hole and the timing of actually paying out near the end of the special game. Arise. As a result, a prize ball payout pulse resulting from winning in a special game is transmitted to the hall computer in spite of the situation of shifting to a non-special gaming state that hardly enters the winning opening compared to the special gaming state. . Accordingly, the hall computer HC that has received this estimates a small number of balls for special games and estimates a high base for non-special games. In particular, if a payout error occurs when paying out a large amount of prize balls due to a special game, the best mode is configured so that the interval between payout balls will be longer, so that the player has entered the winning entrance even more. This causes a situation in which a large time difference occurs between the timing and the timing of actual payout.

  By the way, in addition to the scheduled winning ball pulse indicating that a predetermined number of winning balls is scheduled to be paid out from the pachinko gaming machine to the hall computer HC, game information (for example, jackpot information, start opening winning information, jackpot information) , Game state information, hit ball launch information, etc.). On the hall computer HC side, fraud can be detected to some extent by comparing these data. For example, there is a possibility of fraud when a winning ball scheduled pulse is output without hitting a ball, and when a winning ball scheduled pulse is continuously output without receiving jackpot information. And notify the hall staff's income. Further, a prize ball payout pulse indicating that a predetermined number of prize balls has been actually paid out is transmitted from the pachinko machine to the hall computer HC. On the side of the hall computer HC receiving this, a difference value is derived by subtracting the value of the winning ball payout pulse from the accumulated value (integrated value) of the winning ball scheduled pulse. By taking this difference, in addition to the occurrence of ball clogging in the prize ball payout device or the like, it is possible to grasp to some extent whether or not the time between divisions in division payout is extended. For example, the lower part of FIG. 29 shows a timing chart focused on a special game in which a large number of prize balls are generated. Here, the solid line of the difference value indicates the case where the winning ball at the big hit is discharged smoothly without the occurrence of clogging. On the other hand, the dotted line of the difference value indicates a case where the prize ball discharge speed has decreased due to some reason (for example, a possibility of a ball clogging or a possibility that the time between split payouts has been extended). It is a thing. In such a situation, the effect is notified to the hall staff's income and the like, and measures such as confirmation work of the prize ball payout device and fraud are performed.

  On the other hand, in this best mode, as shown in the figure, when a game ball enters the winning opening, the counter value is updated at the winning timing, and when the counter value becomes 10 or more, the expected winning ball payout pulse Is output. Because of such a configuration, the hall is not affected by the actual state of paying out a prize ball, that is, without being influenced by a prize ball payout error or special game execution, etc. Information on the number of winning balls to be paid out is transmitted to the computer.

  According to this best mode, the payout control board that has received the payout command is configured to send information corresponding to the payout command to the main control board instead of a simple ACK signal, so that the payout control board sends a correct payout command. The main control board side can recognize whether or not it has been received. Further, according to this best mode, just because the payout control board receives the payout command, the payout-related control corresponding to the payout command is not performed, but the main information that received the information corresponding to the payout command is not received. Only when a confirmation command from the control board is further received, the payout-related control corresponding to the payout command is implemented, so it has changed due to an abnormality or fraud that is not assumed on the main control board side. There is an effect that the payout-related control based on the payout command can be surely prevented. Furthermore, according to the present best mode, the information transmission from the payout control board side to the main control board side is also configured to be performed by serial communication. Therefore, it is assumed when the information transmission is performed by parallel communication. There is an effect that it is possible to further prevent a change in information due to abnormality or fraud. In addition, according to the best mode, if the main control board does not receive information corresponding to the payout command within the specified time, the payout command is retransmitted, while the data corresponding to the payout command is received within the specified time. When the command is received, the determination processing by the payout command normal transmission determination means is executed, and is scheduled to be executed after the standby until the information corresponding to the payout command is received. There is an effect that it becomes possible to prevent data accumulation of the payout command relating to the payout control. Furthermore, according to this best mode, since the command transmission from the main control board to the payout control board and the information transmission from the payout control board to the main control board are both serial communication of one transmission line, the number of parts There is also an effect that reduction can be achieved.

  Further, when a payout command is received when the payout command is temporarily stored in the payout command temporary storage means, the previous payout command temporarily stored in the payout command temporary storage means is newly received. Since the payout command is rewritten, it is possible to prevent the payout control process based on the previous payout command, which is unknown whether the command is correct, from being executed.

  Further, when a single payout (all payout operations) is executed by a plurality of subdivided payout operations (split payout operations) and a payout abnormality is detected in the split payout operation, a split payout operation executed thereafter It is configured to increase the waiting time between them, so the first full payout operation itself, which was impossible in the prior art that increases the wait time between all payout operations after continuously executing all payout operations The payout time can be extended, and the frequency of waiting time increases dramatically (for example, when the total payout operation is five split payout operations, when the full payout operation is executed twice, While the technology has only one waiting time, the best mode can construct nine waiting times), which also has the effect of enabling more delicate waiting time control. Further, since the payout control means is configured to execute split payout with the payout number specified by the main control means, the main control can be performed without preparing a plurality of types of payout control boards with different split payout numbers set. As a result of being able to deal with various divided payout numbers corresponding to the specifications of the board, there is an effect that it is possible to flexibly deal with, for example, the divided number can be changed for each model.

  Furthermore, since the waiting time is increased stepwise based on the number of occurrences of payout abnormality, it is possible to achieve a payout speed corresponding to the degree of possibility of fraud.

  In addition, when the waiting time is long and abnormality detection does not occur for a predetermined period (one payout) and the probability of fraud is being reduced, the number of payout abnormality occurrences is temporarily counted in the storage means. Since the value is cleared and the waiting time is configured to return to the normal length, it can be avoided that the irritation of the player due to the waiting time extension due to ball clogging etc. that is not cheating is continued for a long time, It has the effect of being able to cope with clever fraud.

  In addition, if the payout abnormality does not occur in a certain payout operation under a situation where the waiting time is longer than the normal wait time, the next payout operation is performed even when the wait time still remains. Is configured to run. In other words, under a situation where the waiting time is longer than the normal waiting time, the illegal player is forced to digest the long waiting time. Even if the waiting time becomes longer than the normal waiting time due to abnormality detection, if the number of balls paid out after the ball clogging has been resolved = the number confirmed by the count sensor, wait for digestion of the long waiting time. As a result of executing the next payout operation without any effect, there is an effect that the player does not feel uncomfortable.

  Furthermore, the prize ball payout information can be transmitted to the hall computer, and the scheduled payout number that is paid out is sent to the hall computer regardless of the timing at which the prize ball is actually paid out. Since the payout abnormality is detected in the split payout operation, the waiting time between the split payout operations becomes long (especially when a large number of balls are paid out due to special games). Even if there is a significant time lag between the winning timing that triggered the win and the actual payout timing due to the winning, it will be possible to reflect the exact payout rate in real time on the hall computer side There is an effect.

  Further, when the predetermined number of payouts reaches a predetermined number, it is configured to output the predetermined number as a unit to the outside each time. It is possible to reduce the burden on the hall computer on the side that receives and manages.

  Further, when the scheduled prize ball payout information corresponding to the predetermined number is output to the outside, the predetermined number is subtracted from the value relating to the scheduled prize ball payout number temporarily stored in the scheduled prize ball payout number temporary storage means. Since it is comprised, there exists an effect that it becomes possible to prevent the increase in the capacity | capacitance of a scheduled winning ball payout number temporary storage means.

(Example of changes related to serial communication)
Next, a modified example of the best mode will be described. In this best mode, when an error occurs in the reception processing of a certain command or information, the command or information is retransmitted from the sender side. However, the present invention is not limited to this. For example, as shown in Table 2, when an error occurs in the reception process of two commands, the first command that was normally received before that is discarded, and the first command is sent again. Good. In such a configuration, for example, a command for setting ST on the main side to 0 is transmitted from the payout control device to the main control device side so that the first command is transmitted again from the main control device side. Specifically, the reception control unit 2110 discards the one command information temporarily stored in the main side reception information temporary storage unit 2111b when the second command cannot be normally received. After that, the transmission control means 2120 transmits a command for returning the ST on the main side to 0 to the main side control board 1000 side. When the payout control side reception control means 1122 receives a command for returning ST to 0 from the payout control board 2000 side, the payout control side payout state temporary storage means 1220 executes processing for returning ST to 0. To do.

(Example of changes related to withdrawal abnormalities)
Next, an example of change related to payout abnormality will be described. In this best mode, when an abnormality is detected, the number of abnormality detections is updated. If no abnormality is detected during a series of payouts, the number of abnormality detections is cleared and the ball passes from the next payout to the normal time. The waiting time (T ₀ ) is set. However, such a configuration is only an example, and if no abnormality is detected during a series of payouts, the ball passage waiting time may be shortened step by step. For example, a method of subtracting a predetermined number of times (for example, once) instead of clearing the number of times of abnormality detection when there is no abnormality detection during a series of payouts can be mentioned. Specifically, instead of step 2340 in FIG. 24, as step 2340 (1), the waiting time control means 2350 subtracts a predetermined number of times (for example, one time) from the number of times of abnormality detection in the abnormal payout number counter 2323. With this processing, at the time of the next series of payouts, in step 2322, the ball passage waiting time is set based on the subtracted abnormality detection count. By configuring in this way, it becomes possible to make a transition from the payout operation at the time of abnormality detection to the normal time payout operation step by step in accordance with the number of normal payout operations.

The following modification will be described. In the best mode, when there is an abnormal payout, the ball passage waiting time is extended. However, if there is an abnormal payout, a series of payout times need only be extended as a whole, so payout in divided payout units without extending the ball passage waiting time (or extending the ball passage waiting time). You may comprise so that a number may be decreased. Here, the payout control process in the present modification will be described with reference to the flowchart of FIG. In addition, since the process except (1) in the figure is the same as FIG. 24, only the process given (1) will be described. First, immediately before execution of the payout process, in step 2322 (1), the waiting time control means 2350 sets the number of payouts in units of divided payouts based on the counter value in the abnormal payout number counter. In this modified example, the ball passage waiting time is always constant (T _o ). Next, after execution of the payout process, during execution of a certain payout unit, in step 2326 (1), the payout control means 2300 refers to the timer 2330, stops the payout motor 13, and then waits for the ball passage time (T ₀ ) is determined. In the case of Yes in step 2326 (1), in step 2328 (1), the payout control means 2300 determines whether or not a predetermined number of balls have passed through the count sensor 14 from the start of driving. In the case of Yes in step 2328 (1), the process proceeds to step 2336. If No in step 2326 (1), the process proceeds to step 2330, and if No in step 2328 (1), the process proceeds to step 2332.

Here, Table 3 shows the number of payouts per unit time according to the number of payouts per installment payout unit. As described above, the number of payouts per unit time decreases as the number of payouts per installment payout decreases.

  The following modification will be described. In this best mode, when the second information (information corresponding to the second command) is transmitted from the payout control device to the main control device side, predetermined bits (bits 7 to 2 in this best mode) are fixed information. Some or all of the fixed information may be information indicating the ball passage waiting time (in the case of the best mode) and the number of payouts per division unit (in the case of the above-described modification). For example, in the case of the above modified example, out of the bits 7 to 2 in the best mode, the bits 7 and 6 are fixed information, and the remaining 4 bits of 5 to 2 are used, and the payout for 16 stages in Table 3 is performed. A mode in which numerical information is incorporated can be mentioned.

  The following modification will be described. In this best mode, it is configured to continuously transmit information specifying the number of divided payouts from the main control device side to the payout control device side (for example, every scheduled interrupt process). You may comprise so that it may transmit at such timing and / or what frequency. For example, a mode in which information specifying the number of divisions is transmitted only immediately after the power is turned on can be cited.

(Example of changing the number of prize balls to be paid to the hall computer)
The following modification will be described. In the present best mode, the main control board 1000 is configured to manage the number of scheduled winning ball payouts and to output information related to the number of scheduled winning ball payouts from the main control board 1000 to the hall computer HC. The present invention is not limited, and it may be configured such that the planned prize ball payout number related information is output from the payout control board 2000 to the hall computer HC after the payout control board 2000 is managed. Hereinafter, the difference from the best mode will be mainly described with reference to the functional block diagram of FIG. First, unlike the best mode, the main control board 1000 does not manage the scheduled payout ball, and information on the expected number of winning balls to be paid out by the payout to the payout control board 2000 when winning is given. On the side of the payout control board 2000 that has received this, management and transmission processing to the hall computer HC related to the scheduled payout similar to the best mode is executed.

  Specifically, first, with respect to the main control board 1000 side, the payout control side transmission control means 1111 is scheduled to pay out corresponding to the winning opening when a game ball enters the winning opening. There is a scheduled payout ball information transmission control means 1111d for transmitting the prize ball number information to the payout control board 2000. On the other hand, on the payout control board 2000 side, first, the transmission control means 2120 controls the main side transmission control means 2120a having the same function as the “transmission control means 2120” in the best mode, and the control of information transmission to the hall computer HC. HC side transmission control means 2120b for managing The HC side transmission control means also exists on the main control board 1000 side. However, in this modified example, separate information (for example, game state information and various game error information from the main control board side, and the payout control board side). Is configured to transmit the award ball scheduled payout information and various payout error information) to the hall computer HC, but is not limited thereto. For example, all information to be transmitted from the main control board side to the hall computer is transmitted to the payout control board 2000 side, and the information is transmitted from the payout control board side to the hall computer HC in addition to the expected winning ball payout information. Alternatively, overlapping information on the main control board side and the payout control board side may be transmitted to the hall computer HC. Here, when the HC-side transmission control means 2120b receives the award ball scheduled payout information from the main control board 1000, the award ball portion corresponding to the award ball expected payout information, a planned payout number related counter 2120b-3 described later. When the counter value of the scheduled payout number adding means 2120b-1 for accumulating the counter value and the planned payout number related counter 2120b-3 described later reaches a predetermined value (for example, 10), the planned payout number related counter 2120b- described later is reached. And a predetermined payout number subtracting means 2120b-2 for subtracting a predetermined value (for example, 10) from the counter value of 3, and a planned payout number related counter 2120b-3 for temporarily storing the planned payout number. As will be described in the item of processing described later, when the counter value of the scheduled payout number related counter 2120b-3 reaches a predetermined value, information to the hall computer HC (scheduled payout amount = predetermined number (for example, 10) Pulse signal) corresponding to the corresponding number of minutes) is transmitted.

  Further, the payout control board 2000 is provided with backup means 2400 for returning the state of the payout control board to the state when the power is turned off when the power is turned off due to the occurrence of a power failure or the like. Yes. Here, when the power is cut off due to the occurrence of a power failure or the like, the backup unit 2400 restores the state of the payout control board 2000 to the state before the power is turned off when the power is turned on again. Backup information temporary storage means 2410 for storing the data temporarily stored on the side, and a backup power supply for maintaining the data by supplying a backup voltage to the backup information temporary storage means even after the gaming machine is turned off Supply means 24200. Note that writing to the backup information temporary storage unit 2410 is executed when the power is turned off by normal processing, and on the contrary, restoration of each information written to the backup information temporary storage unit 2410 is executed in the main processing when the power is turned on. .

  Next, FIG. 32 is a flowchart showing the management process of the scheduled prize ball payout number and the transmission process of the scheduled prize ball payout number information to the hall computer HC. First, in step 2402, the HC side transmission control unit 2120b refers to the main side reception information temporary storage unit 2111b and determines whether or not new scheduled payout number information has been received. In the case of Yes in step 2402, in step 2404, the HC side transmission control unit 1114 temporarily stores the number of prize balls (n) corresponding to the new scheduled payout number information in the payout processing related information temporary storage unit 2120b-3. Next, in step 2406 and step 2408, the planned payout number adding means 2120b-1 subtracts 1 from the n value temporarily stored in the payout processing related information temporary storage means 2320, and then the planned payout number related counter 2120b- 1 is added to the counter value (C value) of 3. In step 2410, the HC-side transmission control means 2120b refers to the scheduled payout number related counter 2120b-3 and determines whether or not the counter value (C value) has reached a predetermined number (for example, 10). In the case of Yes in step 2410, in step 2412, the HC side transmission control means 2120b outputs a pulse signal corresponding to the predetermined number (for example, 10) via the external relay terminal plate. The hall computer HC that has received this information knows that a prize ball corresponding to the predetermined number (for example, 10) is scheduled to be paid out before the prize ball is actually paid out. Become. In step 2414, the planned payout number subtraction means 2120b-2 subtracts the predetermined number from the counter value (C) of the planned payout number related counter 2120b-3. In step 22416, the HC-side transmission control unit 2120b refers to the payout process related information temporary storage unit 2320 and determines whether the n value is 0 or not. If Yes in step 2416, the process proceeds to the next process. In the case of No in step 2402 and in the case of No in step 2410, the process proceeds to the next process, and in the case of No in step 2416, the process proceeds to step 2406. In the best mode, the counter value of the scheduled payout number related counter 2120b-3 is incremented. However, the present invention is not limited to this, and a signal is transmitted when the counter value is decremented from 0 to 0, and again. You may comprise so that a predetermined value may be set. Further, as the scheduled payout number related counter 2120b-3, one that outputs a signal (divided pulse) every time a predetermined number is counted may be used.

  In this modification, the main control board 1000 is configured to transmit the scheduled payout number information separately from the prize ball payout command to the payout control board 2000, but the present invention is not limited to this. For example, the payout control board 2000 may acquire planned payout number information based on a prize ball payout command from the main control board 1000 side. However, in this case, as in this best mode, it is not configured that the prize ball payout command transmission timing is equal to the prize ball payout timing. On the main control board 1000 side, the payout is made at the timing when the winning signal is received from the winning opening. A prize ball payout command is transmitted to the control board 2000 side. Then, on the payout control board 2000 side, the prize ball information relating to unpaid up until the prize ball payout is completed so that the prize ball payout command information transmitted from the main control board 1000 side at every winning can be managed. It is necessary to provide prize ball payout command information temporary storage means that can be temporarily stored. The rest of the configuration is the same as that of the modified example. By adopting such a configuration, it is configured to manage the planned number of payouts using the information of the prize ball payout command related to the actual prize ball payout. Compared to the case where information related to the planned payout number is transmitted separately from the ball payout command, there is also an effect that the software burden on the main control unit can be reduced.

  The following modification will be described. In this best mode, the number of divisions is uniform in any situation, but this is not a limitation. For example, the aspect which determines a division | segmentation number corresponding to the number of payout can be mentioned. As a specific example, when a prize ball payout command with a large number of payouts is received, an example in which the number of divided payouts is smaller than when a prize ball payout command with a small number of payouts is received. For example, when a predetermined number α (for example, 25) prize ball payout commands are received, X (for example, 3) as the number of divided payouts per time, and a predetermined number β (for example, 15) awards. When a ball payout command is received, Y (for example, 5) as the number of divided payouts per time, and when a predetermined number γ (for example, 10) award ball payout commands are received, As an example, the number of the divided payouts may be Z (for example, 10) (where α> β> γ, Z> Y> X). In this way, the number of divided payouts can be reduced according to the type of prize ball payout command, and particularly when the number of prize balls is large, by reducing the number of divided payouts, it is possible to reduce damage during fraud. Further, the number of divisions may be determined according to the gaming state. As a specific example, an aspect in which the number of divisions is set to be small in a gaming state where a lot of prize balls are paid out can be cited. For example, a predetermined number A during a special game, a predetermined number B during a specific game such as a probability variation game or a time-reduced game, a predetermined number C {a predetermined number C (for example, 10)> a predetermined number B during a normal game (For example, 5)> predetermined number A (for example, 3)}.

  It should be noted that the above-described best modes and modified examples should not be construed as being limited to being applied to specific items, and may be in any combination. For example, it should be understood that a modification of one best mode is a modification of another best mode, and even if one modification and another modification are described independently, It should be understood that a combination of the modified example and another modified example is also described.

13 payout unit 14 count sensor 1000 main control board 1110 transmission control means 1122 payout control side reception control means 1300 normal transmission judgment means 2000 payout control board 2111 main side reception control means 2111c payout command temporary storage means 2120 transmission control means 2300 payout control means 2323 Abnormal payout counter 2330 Payout abnormality determination means 2340 Wait time control means

Claims (3)

A main control means for determining a prize ball payout;
A payout means capable of paying out game balls by performing a payout operation;
Based on a payout command that is a command related to award ball payout transmitted from the main control means, payout control means for controlling the payout operation of the game ball by the payout means;
In a ball game machine having a game ball detecting means for detecting a game ball paid out from a payout means, wherein the main control means and the payout control means are each operated by a board having a separate CPU.
The payout control means drives and controls the payout means so that a predetermined number of game balls to be paid out in one payout operation are divided into multiple payouts by a plurality of split payout operations, and is paid out between the split payout operations. Control to stop the driving of the means and provide a waiting time,
A ball game machine
The planned number of payouts in one divided payout operation is compared with the number of game balls actually detected by the game ball detecting means as a result of the single payout operation, and it is determined whether or not a payout abnormality has occurred. A payout abnormality determining means for determining;
When it is determined by the payout abnormality determining means that a payout abnormality has occurred, the waiting time control means for making the wait time longer than the normal wait time after the divided payout operation in which it has been determined that a payout abnormality has occurred,
A bullet ball game machine comprising: external transmission control means for transmitting to the outside information relating to a predetermined number of winning ball payouts scheduled to be paid out from the payout means.   2. The bullet ball according to claim 1, wherein the external transmission control means transmits, to the outside, information indicating that the predetermined number of winning ball payouts are scheduled each time the cumulative value of the number of scheduled winning ball payouts reaches a predetermined number. Gaming machine. External transmission control means
A scheduled prize ball payout number temporary storage means for temporarily storing the scheduled prize ball payout number;
When the main control means determines the prize ball payout, the planned prize ball payout number adding means for adding the scheduled prize ball payout number related to the determination to the value temporarily stored in the scheduled prize ball payout number temporary storage means;
When the scheduled prize ball payout number temporarily stored in the scheduled prize ball payout number temporary storage means becomes equal to or greater than the predetermined number, the scheduled prize ball payout information is transmitted to the outside, and the scheduled prize ball payout number is temporarily stored. 3. A pachinko gaming machine according to claim 2, further comprising: scheduled prize ball payout number subtracting means for subtracting the predetermined number from the scheduled prize ball payout number temporarily stored in the means.

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