JP2007222690A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a game machine that does not disturb complicated control even if a serial transmission is employed. <P>SOLUTION: The game machine comprises a main control board 1 in charge of the comprehensive control of a game and a plurality of sub-control boards 2 to 5 that work according to control commands from the main control board. The main control board 1 sequentially outputs different control commands to different serial communication circuits USART per byte regardless of the length of a control command byte. By repeating this operation a control command transmission process completes. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a gaming machine such as a pachinko machine, an arrangement ball machine, a sparrow ball game machine, and a revolving game machine, and more particularly to a gaming machine in which a main control board and a sub-control board are connected by a serial communication line. .

  A ball game machine is generally composed of a plurality of circuit boards separated by function, and a plurality of circuit boards cooperate to realize a complex game operation as a whole. Such a gaming machine is generally composed of a main control board that is responsible for overall game control and a plurality of sub-control boards that operate based on control commands from the main control board.

  Sub-control boards include, for example, a symbol control board that controls a liquid crystal display, a payout control board that controls the payout operation of a game ball, a lamp control board that flashes an LED lamp, etc., and a game operation that is voiced There is a voice control board and the like. In order to send control commands from the main control board to the plurality of sub control boards, the main control board is provided with the same number of output ports as the sub control boards. Note that the time that can be allocated to the transmission of the control command is extremely limited in order to realize a complex and advanced operation as a whole.

  However, in the conventional gaming machine, since all control commands are transmitted and received as parallel data, the number of signal lines connecting the boards increases, and accordingly, the number of pins of the connector is required. For this reason, when a cable connecting the main control board and another control board is repeatedly attached or detached due to maintenance work or recycling, the possibility of momentary disconnection or contact failure has increased. There have also been proposals for transmitting control commands as serial data, but with these configurations, the transmission time of the control commands is prolonged, which complicates complex and sophisticated game control.

  The present invention has been made in view of this problem, and it is an object of the present invention to provide a gaming machine that does not hinder complicated game control even when a serial transmission method is adopted.

  In order to solve the above-described problems, the present invention includes lottery means for executing a lottery process for determining whether or not a profit state advantageous to a player is generated, and can control a game operation based on a result of the lottery process. A main control unit and a plurality of sub-control units that receive a control command from the main control unit through one-way serial communication and perform a predetermined gaming operation based on the received control command are provided on different circuit boards, respectively. In the gaming machine, the main control unit is provided with a number of serial communication circuits corresponding to the sub-control unit, and the main control unit sequentially performs every predetermined byte regardless of the byte length of the control command. By outputting to another serial communication circuit and repeating this operation, the transmission process of the control command toward the sub-control unit is completed.

  In the present invention, the target of serial communication of the control command may be all of the sub-control units that perform a predetermined game operation based on the control command, or only some of the sub-control units. When only a part of the sub-control units adopts the serial communication method, the parallel communication method is adopted for the remaining sub-control units. Further, the number of serial communication circuits corresponding to the sub-control units is not necessarily the same as the number of sub-control units that receive serial signals, and the number does not exceed the number of sub-control units.

  The present invention also includes a lottery means for executing a lottery process for determining whether or not to generate a profit state advantageous to the player, and a main control unit capable of controlling a game operation based on a result of the lottery process, A gaming machine that receives a control command from a main control unit by one-way serial communication, and has a plurality of sub-control units that perform predetermined game operations based on the received control command, respectively, on separate circuit boards, The main control unit includes a single serial communication circuit, a gate circuit corresponding to the sub-control unit, and a selection signal output circuit that outputs a select signal to the gate circuit, and the serial control circuit The serial signal from the communication circuit is supplied to all of the gate circuits, while only the serial signal selected by the select signal is transmitted to the sub-control unit. .

  In the present invention, the serial communication of the control command may be all of the sub-control units that perform a predetermined game operation based on the control command. However, the processing is limited to only some of the sub-control units. This is advantageous for shortening the time. In this case, considering the importance of the control command, it is preferable to perform serial communication only to the sub-control board that receives the less important control command. Further, the number of gate circuits provided corresponding to the sub-control units is not necessarily the same as the number of sub-control units that receive serial signals, and the number does not exceed the number of sub-control units.

  The present invention also includes a lottery means for executing a lottery process for determining whether or not to generate a profit state advantageous to a player, and a main control unit capable of controlling a game operation based on a result of the lottery process; A gaming machine that receives a control command from a control unit by one-way communication, and has a plurality of sub-control units that perform a predetermined game operation based on the received control command on different circuit boards, A part of the sub-control unit is configured to receive a control command having the same content, and the sub-control unit receiving the control command having the same content realizes the same intention effect as a whole while executing different processes. Like to do.

  In the present invention, since at least a part of the sub-control unit is configured to receive control commands having the same content, the communication time can be shortened as a whole. The present invention can be applied to a parallel communication system, but is particularly suitable when a serial communication system is employed. In order to receive a control command having the same content, for example, a configuration in which a control command having the same content is always output from the main control unit as illustrated in FIGS. 9 and 10 is preferable. Here, when a configuration in which the passage of the serial signal is controlled by the gate circuit is adopted, the level of the select signal applied to the gate circuit may be made common in terms of hardware or software.

  In addition, although it is desirable that the number of control commands is shared among a plurality of sub-control units configured to receive control commands having the same content, the number is not necessarily limited. That is, when the first sub-control unit is designed to operate based on N control commands and the second sub-control unit is designed to operate based on M control commands (N> M), The extra NM control commands received by the two sub-control units may be configured to be ignored.

  As described above, according to the present invention, it is possible to realize a gaming machine that does not hinder complicated control control even if a serial transmission method is adopted.

  Embodiments of the present invention will be described in detail below based on examples. FIG. 1 is a block diagram illustrating an overall configuration of a pachinko machine according to an embodiment.

  The illustrated pachinko machine includes a main control board 1 for centrally controlling the game operation, a symbol control board 2 for controlling the operation of the liquid crystal display 8, a voice control board 3 for accelerating the game operation, and lamps. In response to the lamp control board 4 that activates the flashing of the game operation, the payout control board 5 that pays out the game ball, the launch control board 7 that is controlled by the payout control board 5 to launch the game ball, and AC24V The power supply board 6 supplies a DC voltage to each part of the apparatus.

  The main control board 1, the symbol control board 2, the voice control board 3, the lamp control board 4, and the payout control board 5 are configured by a computer circuit including a one-chip microcomputer incorporating a Z80 CPU equivalent product. 5 realizes an individual control operation based on a control command from the main control board 1. In this embodiment, the control command is 2 bytes long and is transmitted in one direction by serial communication. However, it is not particularly limited, and it is needless to say that bidirectional communication may be used as necessary.

  FIG. 2 is a block diagram showing a circuit configuration of the main control board 1. As shown in the figure, the main control board 1 includes a CPU circuit 50 composed of a one-chip microcomputer, a system clock generator 51 that generates a clock signal Φ0 that is an integer multiple of the CPU operating clock CLK, and an address signal from the CPU. Based on a decode circuit 52 for generating a chip select signal CS for each part, an output port circuit 53 for outputting data from the CPU, an input port circuit 54 for the CPU to take in external data, and each sub-control board 2 5, an output drive circuit 55 for outputting a control command and a switch input circuit 56 for inputting ON / OFF states of switches of each part of the game board.

  FIG. 3 is a block diagram illustrating specific configurations of the output port circuit 53 and the output drive circuit 55, and is an embodiment in which the communication speed (baud rate) cannot be increased too much. The output port circuit 53 includes four serial communication circuits (USART: Universal Synchronous Asynchronous Receiver) corresponding to the four sub-control boards. For example, a Z80 SIO equivalent product is used as the serial communication circuit USART.

  The serial communication circuit USART has an asynchronous (start-stop) method and a synchronous use method. In the embodiment, the serial communication circuit USART is operated by an asynchronous communication method. By employing this asynchronous communication method, the wiring between the substrates can be minimized. Furthermore, one-way communication is performed from the main control board 1 to the sub-control boards 2 to 5, thereby eliminating the possibility of transmitting an illegal signal to the main control board 1.

  A control command from the main control board 1 to the sub control boards 2 to 5 is transmitted as binary data. Therefore, transmission is completed with 1-byte data having a bit length of 8 + α bits, and the communication time can be shortened compared to the case where the data is transmitted as character data (ASCII data). The serial communication circuit USART is set to output 8 data bits following the L level start bit and finally output 1 bit (minimum value) of the H level stop bit.

  Specifically, the output drive circuit 55 includes driver ICs (DR0 to DR3) that transmit the serial signal from the output port circuit 53 to each control board. This output drive circuit 55 is not necessary when the communication distance between the main control board 1 and the sub control board is short, but since the driver IC is mounted as standard, for example, the distance between the boards can be changed. Even so, the main control board 1 can be used in common.

  On the other hand, the input unit of the sub-control boards 2 to 5 is configured by a serial communication circuit 58 (USART). The serial communication circuit 58 starts a data reception operation when a start bit (L level) is sent from the main control board 1 and interrupts the CPU every time reception of 1 byte data (part of a control command) is completed. It is set to generate a signal. Of course, the baud rates of the serial communication circuits 53 and 58 on the transmission side and the reception side are unified.

  In the sub control boards 2 to 5 that have received the interrupt, parallel data (1 byte) is acquired from the serial communication circuit 58 and stored in the memory in the interrupt processing program. In this embodiment, all control commands are 2 bytes long, and the control command is acquired by repeating the process of acquiring 1-byte data twice by a unique method.

  4 and 5 are flowcharts showing a control program for the main control board 1. FIG. The control program for the main control board 1 is an initial processing program (FIG. 4) that is executed after the power is turned on and normally ends with an infinite loop process (ST6), and a timer interrupt process (Maskable Interrupt disableable interrupt) that is started every predetermined time. The program (FIG. 5) and an NMI processing program (not shown) that is driven by an NMI (Non Maskable interrupt) signal to back up the register value of the CPU when the power supply voltage falls below a predetermined value.

  Hereinafter, the timer interrupt process will be described with reference to FIG. When a timer interrupt occurs, the contents of each register are saved in the stack area, and random number generation processing, switch input management processing, error management processing, and the like are performed (ST30). The switch input management process is a determination as to whether or not a game ball has passed through a gate or an electric tulip, and the error management process is a determination as to whether an abnormality has occurred inside the device. The random number generation process means a process of updating the hit random number value or the big hit random value in software or hardware.

  Thereafter, the value of the process division counter is determined, and the corresponding process from ST32 to ST36 is performed (ST31). The above error management and switch management should be repeated at short time intervals. On the other hand, the processing related to the pachinko game production is complicated and sophisticated according to the player's needs, and therefore requires a certain amount of processing time. It will be. Therefore, in this embodiment, not all the game control operations are completed by one interrupt process, but are divided into five types of processes, and each divided process is divided and executed for each interrupt. Yes. Therefore, a processing division counter that circulates in the range of 0 to 4 is provided to perform processing according to the value of the processing division counter.

  More specifically, when the processing division counter is 0, processing relating to the opening of the big prize opening is performed (ST32), and when the processing division counter is 1, whether the winning state (electric tulip is open) or not. Normal symbol processing is performed (ST33), and when the processing division counter is 2, processing relating to whether or not a big hit state is performed (ST34). If the processing division counter is 3, timer management processing related to the opening / closing timing of the electric tulip and the big prize opening and command creation processing transmitted from the main control board to each control board are performed (ST35). If the process division counter is 4, information output and error display command creation processing is performed (ST36).

  When any one of steps ST32 to ST36 is completed, the value of the process division counter is updated (ST37), and the generated command is output to each control board (ST38). Further, the value of each register is restored and changed to the interrupt enabled state, and the routine returns from the interrupt processing routine to the main routine (ST39).

  FIG. 6A is a flowchart showing in detail the above-described command output process (ST38), and FIG. 6B shows the RAM command buffer area (eight bytes from the TOP address). In the command buffer area, necessary control commands are already stored by the timer interrupt process (ST35, ST36). In this embodiment, there are control commands for symbol control boards, voice control boards, lamp control boards, and payout control boards, but in the initial state, all command buffer areas are cleared to zero. .

  6A, after the pointer PT is cleared to zero (ST41), the head address TOP of the command buffer area is set in the address variable AD (ST42), and the port number Pi is initialized (ST43). ). Here, the port number is the port number of each of the four serial communication circuits 53. The design control board USART is P1, the voice control board USART is P2, the lamp control board USART is P3, and the payout control board USART. Is set to P4.

  Next, it is determined whether or not the control command data exists at the address indicated by AD + PT (ST44). If the control command data exists, 8-bit control command data is output to the serial communication circuit 53 having the port number Pi. (ST45). The address indicated by AD + PT is cleared to zero (ST46).

  When the control command data is output to any of the serial communication circuits 53 by the process of step ST45, the corresponding serial communication circuit 53 converts the control command data, which is parallel data, into serial data, and the corresponding sub-control board. Start transmission towards Here, in order to shorten the communication time from when the serial communication circuit 53 starts transmission of serial data until the serial communication circuit 58 of the sub control board finishes receiving data, first, the transmission side and the reception side It is conceivable to increase the baud rate of the serial communication circuits 53 and 58.

  However, if the communication speed is increased unnecessarily, it may cause a malfunction depending on the communication environment. In this embodiment, the main control board 1 has four serial communications corresponding to the four sub-control boards. A circuit 53 is provided. Therefore, in this embodiment, when the process of step ST45 is completed, the serial communication circuit 53 of the next port number Pi can be immediately operated. Specifically, after adding 2 to the address variable AD (ST47), if the final address of the command buffer area is not exceeded, the port number Pi is updated (ST49), and another serial communication circuit 53 is operated. ing. As a result of such an operation, the communication process can be completed together with other processes during the limited interruption time without increasing the baud rate.

  The port number of the serial communication circuit 53 is changed from port1 → port2 → port3 → port4 by the update process of step ST49 described above, and the symbol control board 2 → lamp control board 3 → sound by the process of step ST45 following step ST49. The first byte of each control command is transmitted in the order of control board 4 → payout control board 5.

  If the address variable AD sequentially updated by the process of step ST47 exceeds the final address, the pointer PT is incremented (ST50), and the processes of steps ST42 to ST48 are repeated until the pointer PT = 2. If necessary to complete the serial transmission of 8-bit data, time consumption processing (ST52) is executed.

  In this embodiment, the pointer PT is set to 1 when the first round of processing is completed, and the pointer PT is set to 2 when the subsequent second round of processing is completed. At the time of execution of the second round, since the pointer PT = 1, the second byte of each control command in the order of symbol control board 2 → lamp control board 3 → voice control board 4 → payout control board 5 Is transmitted to complete the control command transmission process.

  As described above, in this embodiment, the control command is transmitted as the serial signal SG to all the sub-control boards. However, the control command is not necessarily limited to this configuration, and the malfunction should occur as the communication time is shortened. In consideration of the magnitude of the adverse effects in this case, a parallel signal may be transmitted to the payout control board 5 (in some cases, also to the symbol control board 2) via another circuit.

  By the way, this gaming machine is configured such that an NMI (Non Maskable interrupt) is applied to the CPUs of the main control board 1 and the payout control board 5 when the power supply voltage falls below a predetermined value during operation. When an NMI interrupt occurs, all the registers of the CPU are saved in the RAM area, and the voltage of the RAM work area including the RAM is maintained by a backup power source. On the other hand, after the power is restored, the stored register value is restored to the state before the game interruption, and the interrupted game is resumed normally. Hereinafter, based on this point, the operation content after power-on will be described based on the flowchart of FIG.

  When the power is turned on, after the CPU is set to the interrupt disabled state, the CPU registers are initialized (ST1), and the CPU is set to the interrupt mode 2 (ST2). Thereafter, the RAM clear signal and the backup flag are checked (ST3, ST4). The RAM clear signal corresponds to the initialization switch. When the power switch is turned on while pressing the initialization switch with the front frame of the pachinko machine opened, as in the start of business, the RAM clear signal The clear signal is ON.

  If the RAM clear signal is ON (ST3: yes), after all the game information stored in the RAM is erased, the CPU sets an initial symbol to be displayed on the first symbol display means 22. In addition, after performing initial processing such as setting an interrupt cycle for periodically executing interrupt processing during the execution of this game control, the EI command is executed to set itself in an interrupt enabled state (ST5). Thereafter, random number processing (ST6) for the off symbol repeated in an infinite loop is performed. Note that the random symbol processing for the out symbol defines the out symbol pattern drawn on the liquid crystal display 8 when the special symbol lottery is excluded in the interrupt processing described later.

  On the other hand, when the RAM clear signal is in the OFF state when the power is turned on (ST3: no), after confirming that the backup flag is not zero (ST4), a backup data restoration process is performed. The backup data restoration process is a process for restoring the data backed up by the NMI process at the time of a power failure or the like, and this processing is performed when the power is turned on without pressing the initialization switch after the power failure is restored. The backup flag indicates whether or not the backup process has been completed, and is meaningful when the power failure occurs again before the process up to step ST12 is completed.

  If the power is restored from the power failure state, the content of the backup flag BFL is 5AH. Therefore, the processing of the CPU shifts from step ST4 to step ST7, and 16-bit data read from the SP storage area of the RAM is written into the stack pointer SP of the CPU (ST7).

  Subsequently, the RAM area data saved in the NMI process at the time of a power failure is read to create a backup return command (ST8 to ST10). Here, the backup return command creation processing (ST8) for the payout control board means a preparatory operation for rechecking the error signal and outputting a control command according to the current state of the gaming machine to the payout control board 5. . For example, if the upper plate is full before the power failure, the error state is saved by the backup data, but the player is likely to collect the game balls due to the power failure. The current situation is being confirmed.

  In addition, the backup return command creation process (ST9, ST10) for the symbol control board and the lamp control board is a so-called probability change state in which the gaming machine before the power failure is in a big hit state or the winning probability is increased. In such a case, the background color of the liquid crystal display unit is set in accordance with the operation state, and a sound effect can be generated.

  Next, the CPU executes a POP instruction to restore the value of each register (BC, DE, HL) excluding the AF register from the stack area (ST11). As a result of this process, the recovery process after the power failure is completed, so the backup flag BFL is cleared to zero to indicate that (ST12). Finally, it is checked whether or not the interrupt was prohibited before the power failure (ST13 and ST14), and after the AF register is returned from the stack area, the processing is ended in the interrupt disabled state (ST15 and ST16). Alternatively, the process is returned to the interrupt enabled state (ST17 to ST19).

  FIG. 7 illustrates the configuration of the second embodiment. In this embodiment, only the audio control board 3 and the lamp control board 4 among the sub-control boards adopt the serial transmission method. It is particularly suitable to be applied to a gaming machine in which the symbol control board 2 does not exist and a control command of 1 byte length is transmitted to the voice control board 3 and the lamp control board 4. Further, it is preferable to use in a communication environment where the baud rate can be set high.

  As shown in FIG. 7, the output port circuit 53 includes a single serial communication circuit 53a (USART: Universal Synchronous Asynchronous Receiver) and a select signal output circuit 53b. The select signal output circuit 53b outputs data of bit0 and bit1 of the data bus. In this embodiment, a D-type flip-flop (74273 equivalent product) is used as the select signal output circuit 53b.

  The output drive circuit 55 includes NAND gates 57b and 57c that receive the outputs of the select signal output circuit 53b and the serial communication circuit 53a, and drivers 54b and 54c that transmit the outputs of the NAND gates b and 57c to the control boards 3 and 4, respectively. It is configured. Therefore, if the output of the select signal output circuit 53b is 01H, the serial signal SG from USART is transmitted to the sound control board 3, and if the output of the select signal output circuit 53b is 02H, the serial signal SG is transmitted to the lamp control board 4. become. For the remaining sub-control boards 2 and 5, control commands are transmitted in a parallel communication system through another circuit.

  The input parts of the sub-control boards 3 and 4 are constituted by a serial communication circuit 58 (USART) that operates at the same baud rate as the main control board side. Therefore, when a start bit (L level) is sent from the main control board 1, the serial communication circuit 58 starts a data reception operation.

  The serial communication circuit 58 of the sub-control boards 3 and 4 is set to generate an interrupt signal to the CPU every time reception of a 1-byte control command is completed. Then, the CPUs of the sub-control boards 3 and 4 obtain a 1-byte control command from the serial communication circuit 58 and store it in the memory in each interrupt processing program.

  FIG. 8A is a flowchart for explaining command transmission processing in the second embodiment, and FIG. 8B shows a command buffer area reserved for 2 bytes from the TOP address. First, the address variable AD is set to the start address TOP of the command buffer area, and the select signal SE is set to 01H (ST61). Next, it is determined whether or not command data exists at the AD address (ST62).

  If command data exists at the AD address, first, the select signal SE is output to the SE output port 53b (ST63). As a result, since the select signal SE is 1, the NAND gate 57b is opened. Thereafter, the main control board reads out the control command at the AD address and outputs it to the serial communication circuit 53a (ST64), and clears the contents at the AD address to zero (ST65).

  The serial communication circuit 53a serially converts the control command data, which is parallel data received from the CPU, and transmits it to the audio control board 3 via the NAND gate 57b and the driver 54b bit by bit.

  During transmission of such a serial signal SG, the main control board 1 needs to wait for the sub control board to finish acquiring the serial signal SG. Therefore, the necessary time is consumed (ST66), and then the select signal SE is cleared to zero (ST67). This processing closes all NAND gates 57b and 57c.

  Next, the address variable AD is incremented (ST68), and the select signal SE is shifted to the left by 1 bit (ST69). By this processing, the select signal SE which is the binary number 01 is changed to the binary number 10. Then, the processes of steps ST62 to ST69 are repeated unless the final address is exceeded. By this process, the SE data changes from 01 → 10, and the transmission process of the control command toward the lamp control board 4 is performed.

  In the case of the second embodiment, since the control command is 8 bits long and the baud rate is set high, there is no particular problem even if the control commands are sequentially transmitted to each control board by serial operation. Even if the sub-control board reads out the control command due to a communication trouble, it is not harmful because it is a control command related to the sound effect and the lamp effect. However, in the configuration of the second embodiment, the serial transmission method may be adopted for all the sub-control boards 2 to 5, and the control command may be 2 bytes long.

  When a control command is transmitted to the symbol control board 2, the voice control board 3 and the lamp control board 4 by a serial transmission method, as shown in FIG. 9A, the control for the voice control board 3 and the lamp control board 4 is performed. The number of commands and data contents may be unified. For example, when the same control command (for example, 10H) is received, the sound control board 3 starts a sound effect for starting the big hit game, while the lamp control board 4 starts the lamp effect for starting the big hit game.

  For the command buffer area, one storage area is shared as a control command for the voice control board and the lamp control board (see FIG. 9B). In such a case, the same serial signal SG is always transmitted to the sound control board 3 and the lamp control board 4 as shown in FIG. The command transmission process is completed in two transmission times. That is, as in the case described with reference to FIG. 8, the transmission of the three control commands toward the symbol control board 2, the voice control board 3, and the lamp control board 4 can be completed by two rounds of processing.

  When the control command is shared, the serial signal SG is not fixedly shared as shown in FIG. 9A, but the select signal applied to the NAND gate as shown in FIG. 9C. May be shared. In such a configuration, the control command for the voice control board 3 and the control command for the lamp control board 4 do not have to be completely the same, and SE2 = SE3 only when it is desired to transmit the same command. It ’s fine. In addition, the same control command can be transmitted to all the sub-control boards at the same time as necessary.

  Further, in the case where control commands for a plurality of sub control boards are shared and one storage area of the command buffer area is shared, the circuit of FIG. 3 can be modified and configured as shown in FIG. it can. Also in this case, when processing is performed according to the flowchart of FIG. 6A, the control command can be transmitted to the four sub control boards 2 to 5 in the same transmission time as the control command is transmitted to the three sub control boards.

  Subsequently, the above-mentioned bullet ball game machine will be further described. FIG. 11 is a perspective view showing the pachinko machine 22 of the present embodiment, and FIG. 12 is a side view of the pachinko machine 22.

  The pachinko machine 22 shown in FIG. 11 is mounted in a rectangular frame-shaped wooden outer frame 23 that is detachably mounted on the island structure and a hinge H that is fixed to the outer frame 23 so as to be pivotable. And a frame 24. A plurality of pachinko machines 22 are arranged in the length direction of the island structure of the pachinko hall while being electrically connected to the card-type ball lending machine 21.

  A game board 25 is detachably mounted on the front frame 24 pivotally attached to the outer frame 23 via the hinge H, and a glass door 26 having a window portion corresponding to the front side of the game board 25 and A front plate 27 is pivotally attached to each other so as to be opened and closed. An upper plate 28 for storing game balls for launching is mounted on the front plate 27, and a lower plate 29 for storing game balls overflowing or extracted from the upper plate 28 and launching means 30 at the lower part of the front frame 24. And a firing handle 31 are provided.

  The launching unit 30 includes a launching handle 31 that can be rotated, and a launching motor that launches a game ball with a striking rod 32 (FIG. 14) with a striking force corresponding to the pivoting angle of the launching handle 31. An operation panel 33 for lending the ball to the card-type ball lending machine 21 is provided on the right side of the upper plate 28. A card remaining amount display unit 33a for displaying the remaining amount of the card with a three-digit number is provided on the operation panel 33. A ball lending switch 33b for instructing lending of game balls for a predetermined amount, and a return switch 33c for instructing to return the card at the end of the game.

  As shown in FIG. 13, the game board 25 is provided with a guide rail 35 formed of a metal outer rail and an inner rail in a substantially annular shape, and a color liquid crystal is provided in a game area 25 a inside the guide rail 35. Display (LCD monitor) 8, symbol start opening (design start means / winning means) 37 having a detection switch, open / close-type winning means (large winning means) 38, a plurality of normal winning means 39 (in addition to the upper normal winning means 39) The six normal winning means 39 on the left and right sides of the openable winning means 38) and the two gates 40 (passage openings) are arranged at predetermined positions, respectively.

  The liquid crystal display 8 functions as a first symbol display means 42 (variable display device) that displays a changing symbol and also displays a background image, a moving image of various characters, and the like. The first symbol display means 42 displays a background image and a character in an animated manner, and has three (left, middle, and right) symbol display portions 42 a to 42 c arranged in the left-right direction. On the condition that the ball wins, the display symbols of the symbol display portions 42a to 42c are variably displayed (scrolled) for a predetermined time, and based on the lottery result corresponding to the winning timing of the game ball to the symbol start opening 37. Stop at the determined stop symbol pattern.

  A normal winning means 39 and a second symbol display means 43 are provided immediately above the liquid crystal display 8. The second symbol display means 43 has a normal symbol display unit for displaying one normal symbol. When a game ball passing through the gate 40 is detected, the display symbol of the normal symbol display unit (variable display device) is predetermined. It fluctuates by time, and stops by displaying a stop symbol determined by a random number for lottery drawn at the time when the game ball passes through the gate 40. The symbol start opening 37 is an electric tulip provided with a pair of left and right opening and closing claws 37a that can be opened and closed. When the stop symbol after the change of the second symbol display means 43 is hit and the symbol is displayed, the opening and closing claws 37a It is open for a predetermined time, making it easy to win.

  The open / close-type winning means 38 includes an opening / closing plate 38a that can be opened forward. When the stop symbol after the fluctuation of the first symbol display means 42 is a winning symbol such as “777”, a special game called “big hit” is started. The opening / closing plate 38a is opened to the front side. There is a specific area 38b inside the openable winning means 38, and when the winning ball passes through the specific area 38b, the special game is continued. Here, the special game state corresponds to a first state advantageous to the player.

  After the opening / closing plate 38a of the open / close winning means 38 is opened, when a predetermined time elapses or when a predetermined number (for example, 10) of game balls wins and the opening / closing plate 38a is closed, the game ball is moved to the specific area 38b. If the game has not passed, the special game ends. However, if the game passes the specific area 38b, the special game is continued up to, for example, 16 times, and is controlled in a state advantageous to the player.

  As shown in FIG. 14, a back mechanism plate 50 that presses the game board 25 from the back side is detachably mounted on the back side of the front frame 24, and an opening 50a is formed in the back mechanism plate 50. A prize ball tank 53 and a tank rail 54 extending from the prize ball tank 53 are provided. Dispensing means 55 connected to the tank rail 54 is provided on the side of the back mechanism plate 50. A passage unit 56 connected to the (dispensing motor) 55 is provided. The game balls paid out from the payout means 55 are paid out to the upper plate 8 from the upper plate discharge port 28a (FIG. 11) via the passage unit 56.

  In the opening 50a of the back mechanism plate 50, a back cover 57 mounted on the back side of the game board 25 and a winning ball discharge basket (not shown) for discharging the winning game balls in the winning means 37 to 39 are fitted. Are combined. The main control board 1 is disposed inside the case 58 attached to the back cover 57, and the symbol control board 2 is disposed on the front side thereof (FIG. 12). Below the main control board 1, the lamp control board 4 is provided in a case 61a attached to the back cover 57, and the sound control board 3 is provided in a case 61b adjacent to the case 61a.

  A power supply board 6 and a payout control board 5 are provided inside the case 64 mounted on the back mechanism plate 50 below the cases 61a and 61b. As shown in FIG. 14, a power switch 80 and an initialization switch 85 are arranged on the power supply board 6. A portion corresponding to both the switches 80 and 85 has a case 64 cut away so that each of the switches 80 and 85 can be operated simultaneously with a finger.

  A launch control board 7 is provided inside a case 67 attached to the rear side of the launching means 30. These control boards 1 to 7 are independent boards, and the control boards 1 to 5 except for the power supply board 6 and the launch control board 7 are equipped with a computer circuit including a one-chip microcomputer. The other control boards 2 to 5 are electrically connected via a connector with a plurality of signal lines.

It is a block diagram which shows the whole structure of the pachinko machine which concerns on an Example. It is a block diagram which shows the structure of a main control board. The connection part of a main control board and a sub control board is illustrated in detail. It is a flowchart which shows the system reset process in a main control board. It is a flowchart which shows the timer interruption process in a main control board. It is a flowchart which shows the command output process in a main control board. In the second embodiment, the connection between the main control board and the sub control board is illustrated in detail. It is a flowchart which shows the command output process in a main control board about 2nd Example. FIG. 8 illustrates a modified circuit example of FIG. 7. FIG. 4 illustrates a modified circuit example of FIG. 3. It is a perspective view of the pachinko machine concerning an example. It is a side view of the pachinko machine of FIG. It is a front view of the pachinko machine of FIG. It is a rear view of the pachinko machine of FIG.

Explanation of symbols

1 Main control unit (main control board)
2-5 Sub-control unit (sub-control board)
USART serial communication circuit

Claims (7)

A lottery means for executing a lottery process for determining whether or not to generate a profit state advantageous to a player, a main control unit capable of controlling a game operation based on a result of the lottery process, and a control from the main controller A gaming machine that receives a command by one-way serial communication and has a plurality of sub-control units that perform a predetermined gaming operation based on the received control command, respectively, on different circuit boards,
The main control unit is provided with a number of serial communication circuits corresponding to the sub-control unit,
Regardless of the byte length of the control command, the main control unit outputs to the serial communication circuit one after another for each predetermined byte, and repeats this operation to transmit the control command to the sub control unit. A gaming machine characterized by completion. A lottery means for executing a lottery process for determining whether or not to generate a profit state advantageous to a player, a main control unit capable of controlling a game operation based on a result of the lottery process, and a control from the main controller A gaming machine that receives a command by one-way serial communication and has a plurality of sub-control units that perform a predetermined gaming operation based on the received control command, respectively, on different circuit boards,
The main control unit is provided with a single serial communication circuit, a gate circuit provided corresponding to the sub-control unit, and a selection signal output circuit for outputting a select signal to the gate circuit,
The serial signal from the serial communication circuit is supplied to all of the gate circuits, while only the serial signal selected by the select signal is transmitted to the sub-control unit. A gaming machine. A lottery means for executing a lottery process for determining whether or not to generate a profit state advantageous to a player, a main control unit capable of controlling a game operation based on a result of the lottery process, and a control from the main controller A gaming machine in which a command is received by one-way communication and a plurality of sub-control units that perform a predetermined gaming operation based on the received control command are provided on separate circuit boards,
At least some of the plurality of sub-control units are configured to receive control commands having the same content,
The gaming machine characterized in that the sub-control unit that receives the control command having the same content realizes the same intention effect as a whole while executing different processes.   The main control unit first accesses an area where a control command for the sub-control unit should be stored, and if there is no significant data, performs transmission processing of the control command for the sub-control unit. The gaming machine according to claim 1, wherein the gaming machine is omitted.   The gaming machine according to claim 1, wherein the one-way communication is realized by a serial signal that is binary data.   The gaming machine according to claim 1, wherein the one-way communication is realized by an asynchronous serial communication method.   The sub-control unit includes a voice control unit that performs a sound effect and a lamp control unit that performs a lamp effect, and the control commands transmitted to the sound control unit and the lamp control unit include The gaming machine according to any one of claims 1 to 6, which is configured to always match.

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