JP5056154B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine that uses an AC power source supplied from the outside of the gaming machine by converting it to a DC power source.

  Conventionally, pachinko machines are known as this type of gaming machine. The pachinko machine receives an AC 24V power supply from an AC 24V outlet provided at the place where the pachinko machine is installed, and uses it as a main power source. The main power source is converted into a direct current power source of 32V by a conversion circuit, and a launch motor for driving a launching device for launching a game ball to the game board, a prize ball payout motor for driving a payout device for paying out a prize ball, etc. Is supplied as drive power. The 32V DC power is converted into 12V and 5V DC power by two DC-DC converters, and the 12V DC power is supplied by a winning opening switch or a payout device for detecting a winning ball that has won a winning opening. It is supplied as a drive power source to a payout sensor for detecting the awarded ball.

The 5V DC power supply includes a main control microprocessor for controlling the progress of the game (hereinafter referred to as MPU), an effect display MPU for controlling the symbol display, LED and sound, and payout. It is supplied as an operating power to a payout control MPU for controlling the apparatus.
In addition, a fuse and a varistor for protecting the pachinko machine from an overcurrent are connected to the main power supply line.

Japanese Patent Laying-Open No. 2001-187192 (paragraphs 39 to 41, FIG. 5)

However, the conventional pachinko machine has a problem that the voltage of the DC power supply tends to become unstable because there is only one conversion circuit for converting the AC power supply into the DC power supply. In particular, if the DC power supply of 5V becomes unstable, the operation of the MPU becomes unstable, which affects the progress and effects of the game, which may cause unexpected disadvantages to the player.
In addition, since there is only one conversion circuit, the amount of heat generated from the conversion circuit is large, and the heat generation may increase the temperature of peripheral transistors, diodes, and the like, which may deteriorate operating characteristics.

By the way, in the pachinko parlor, around the pachinko machine, a CR unit that reads game value information stored in the IC card and transfers it to the pachinko machine, a ball replenishment facility that refills the game ball behind the pachinko machine, etc. are installed. These are supplied with AC power of 100V. Normally, a pachinko machine is supplied with power from a 24V AC outlet. Once installed, even if there is a 100V AC outlet nearby, it may be accidentally connected to a 100V AC outlet. There is no end.
However, when replacing a pachinko machine with a new model or changing the arrangement, there is a risk of accidental connection to an AC 100V outlet. In this case, an inrush current when connected to an AC 100V outlet becomes a problem, but the inrush current cannot be prevented with a fuse that is not blown for a very short time. In addition, a varistor that targets an extremely short pulse generated by a lightning strike cannot prevent an inrush current when AC 100V is connected.

  Therefore, the present invention can stabilize the voltage of the DC power source converted from the AC power source, has a small amount of heat generated from the conversion circuit for converting the AC power source to the DC power source, and further reliably protects against the inrush current. It aims at realizing the gaming machine which can do.

In order to achieve the above object, according to the first aspect of the present invention, in the gaming machine (1) that uses the AC power supply (8) supplied from the outside of the gaming machine converted into a DC power supply, Two conversion circuits (B1, D2, D3) for converting an AC power source into a DC power source and the other system of the conversion circuit are attached, and heat generated from the conversion circuit of the other system is radiated. A radiator (94) and an NTC type power thermistor (Pa) connected to the output side of one system of the conversion circuit and disposed in a region for receiving heat radiated from the radiator. The conversion circuit of the other system converts the AC power source to a DC power source of a predetermined voltage, and a DC power supply line on the output side of the power thermistor connected to the conversion circuit of the one system The one Using technical means that converter for converting DC power converted by the conversion circuit of the integrated to a voltage lower than the predetermined voltage is connected.
In addition, the code | symbol in said parenthesis respond | corresponds with the code | symbol used in embodiment mentioned later.

(Effect of the invention according to claim 1)
Since two conversion circuits are provided as conversion circuits for converting AC power supplied from the outside of the gaming machine into DC power, the voltage of the DC power supply is less than that of conventional gaming machines having only one conversion circuit. There is no risk of stability.

  In addition, since there are two conversion circuits, the amount of heat generated from one conversion circuit can be reduced compared to a conventional gaming machine having only one conversion circuit, so that There is no possibility that the temperature of the arranged transistors, diodes, etc. will rise and the operating characteristics will be deteriorated.

  Furthermore, since the power thermistor is connected to the output side of one system of the conversion circuit, it is possible to prevent the inrush current from flowing from the system to which the power thermistor is connected.

  Furthermore, since the power thermistor is of the NTC type and its own resistance value decreases as its temperature rises, its own resistance value is further reduced by receiving the heat generated from the radiator. The increase in power consumption due to can be suppressed.

A pachinko machine according to an embodiment of the present invention will be described with reference to the drawings.
[Overall main configuration]
First, the main configuration of the pachinko machine of this embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a perspective view showing the external appearance of the pachinko machine, and FIG. 2 is a front view showing a schematic configuration of the game board provided in the pachinko machine shown in FIG.

  As shown in FIG. 1, the pachinko machine 1 is provided with a frame-like outer frame 2 that constitutes an outer shell, and a front frame 3 is pivotally supported by the outer frame 2 so as to be opened and closed. A glass plate 3 a is disposed on the front surface of the front frame 3, and a game board 5 is detachably disposed on the front frame 3 inside the glass plate 3 a. The pachinko machine 1 includes a firing lever 9, an upper plate 6, and a lower plate 7.

[Main components of the game board]
As shown in FIG. 2, an effect display 10 that displays effect images such as moving images and still images is provided in the approximate center of the game board 5. Below the effect display 10, there is provided an ordinary electric accessory 16 having a start port 15 inside and having both wings that can be opened and closed. The effect indicator 10 displays a plurality of special symbols in a predetermined order in addition to variably displaying a plurality of special symbols. In this embodiment, the normal symbol is composed of symbols such as ○ and X, and when the game ball passes through the gate 11 provided on the game board 5, the effect display unit 10 starts to display the normal symbol variation display. When the normal symbol (for example, ◯) is stopped, both wings of the ordinary electric accessory 16 are opened, and the winning to the start port 15 becomes easy.

In addition, the game board 5 is provided with a plurality of general winning holes 13, and a predetermined number (for example, five) of winning balls is paid out when the general winning hole 13 is won.
In addition, the game board 5 is provided with a windmill 12, a guide rail 14 for guiding the launched game ball to the game area, an out port 19 for collecting the game ball that has not won anywhere as an out ball, and the like. Although not shown in the drawing, many game nails are driven into the surface of the game board 5, and the fired game balls change the flow direction by colliding with the game nails, so that the start opening 15 and the general prize opening Win 13 or pass through the gate 11.

[Electric configuration of pachinko machine 1]
Next, the main electrical configuration of the pachinko machine 1 will be described with reference to FIGS. FIG. 3 is an explanatory diagram showing main electrical configurations such as a main control board and a payout control board in blocks. FIG. 4 is an explanatory diagram showing main electrical configurations such as a power supply board and an effect control board in blocks. FIG. 5 is a circuit diagram of a power supply circuit mounted on the power supply board shown in FIG.

  As shown in FIG. 3, the pachinko machine 1 is provided with a main control board 40, and a main control microprocessor unit (hereinafter referred to as MPU) 41 is mounted on the main control board 40. The main control MPU 41 includes a main control CPU 42, a main control ROM 43, and a main control RAM 44. The main control CPU 42 comprehensively controls the progress of the game. In the main control ROM 43, a control program executed by the main control CPU 42, a control command transmitted to each control board, a big hit value to be referred to when determining whether or not the big hit is recorded, and the like are readable.

In the main control RAM 44, processing results and determination results generated when the main control CPU 42 executes the control program are stored so as to be readable and overwritten.
The main control RAM 44 is used for game control to back up main control reproduction data required by the main control CPU 42 to reproduce the gaming state before the power is cut off when the cut off power is turned on. A data storage area is provided.

  A payout control board 50 is electrically connected to the main control board 40. The payout control board 50 is equipped with a payout control MPU 51 for controlling payout of game balls. The payout control MPU 51 includes a payout control CPU 52, a payout control ROM 53, and a payout control RAM 54. .

  In the payout control ROM 53, a control program executed by the payout control CPU 52 is recorded in a readable manner. In the payout control RAM 54, processing results and determination results generated by the payout control CPU 52 executing the control program are stored so as to be readable and overwritten. The payout control RAM 54 includes an unpaid prize ball number data storage area for backing up data indicating the number of unpaid prize balls when there is an unpaid prize ball number when the power is cut off.

  A DC5V line L8 is electrically connected to the main control MPU 41, and a backup capacitor BC1 for supplying a backup DC5V power to the main control MPU 41 when the power is cut off is electrically connected to the DC5V line L8. Has been. Further, a DC5V line L9 is electrically connected to the payout control MPU 51, and a backup capacitor BC2 for supplying backup DC5V power to the payout control MPU 51 when the power is shut off is electrically connected to the DC5V line L9. It is connected to the.

  The backup capacitor BC1 executes a process in which the main control CPU 42 writes necessary data to the main control RAM 44 when the power is shut down due to a power failure or the like, and further backs up to the main control RAM 44 until the power is restored. It has a capacitance that can supply enough power to keep the data being stored from being lost.

  Further, the backup capacitor BC2 executes a process for writing data necessary for the payout control CPU 52 to the payout control RAM 54 when the power supply is shut down due to a power failure or the like. Further, during the period until the power is restored, the backup capacitor BC2 It has a capacitance that can supply sufficient power necessary to keep the data being backed up from being lost. For the backup capacitors BC1 and BC2, an aluminum electrolytic capacitor, an electric double layer capacitor, or the like is applied.

  In addition, a diode D5 for preventing a reverse flow of the discharge current from the backup capacitor BC1 is electrically connected to the charging path to the backup capacitor BC1 of the DC5V line L8. Thereby, when the power is shut off, the discharge current of the backup capacitor BC1 flows backward, and there is no possibility that the power supplied to the main control MPU 41 is insufficient.

  In addition, a diode D6 for preventing a reverse flow of the discharge current from the backup capacitor BC2 is electrically connected to the charging path of the DC5V line L9 to the backup capacitor BC2. Thereby, when the power is shut off, the discharge current of the backup capacitor BC2 flows backward, and there is no possibility that the power supplied to the payout control MPU 51 is insufficient.

  As shown in FIG. 4, a panel relay terminal plate 60 is electrically connected to the main control board 40, and the panel prize relay opening / closing member 18 is opened and closed to the panel relay terminal board 60. A mouth solenoid 69, a normal electric accessory solenoid 70 for opening and closing both wings of the ordinary electric accessory 16, and a big prize opening switch (large prize opening SW) 71 for detecting a game ball won in the big prize opening, A winning port switch (winning port SW) 72 for detecting a game ball won in the general winning port 13, a gate switch (gate SW) 73 for detecting a gaming ball that has passed through the gate 11, and a start port 15 Is connected to a start port switch (start port SW) 74 for detecting a game ball won. In FIG. 4, three of the four winning opening switches 72 corresponding to the general winning opening 13 shown in FIG. 2 are omitted.

  As shown in FIG. 3, the effect control board 30 is electrically connected to the main control board 40. The effect control board 30 includes an effect control MPU 31, and the effect control MPU 31 includes an effect control CPU 32, an effect control ROM 33, and an effect control RAM 34. The effect control board 30 is electrically connected to a lamp control board 80 that controls lighting of LEDs provided in the pachinko machine 1.

  In addition, the left speaker 91 is electrically connected to the effect control board 30 via the left speaker relay terminal board 90, and the right speaker 93 is electrically connected via the right speaker relay terminal board 92. . The left speaker 91 and the right speaker 93 output sound effects during the game under the control of a sound control device (not shown) mounted on the effect control board 30.

  A payout control board 50 is electrically connected to the main control board 40. The payout control board 50 is equipped with a payout control MPU 51, and the payout control MPU 51 includes a payout control CPU 52, a payout control ROM 53, and a payout control RAM 54.

  As shown in FIG. 4, on the payout control board 50, a payout motor 61 for driving a member for paying out game balls, a payout sensor 62 for detecting game balls paid out by the payout motor 61, and A ball break switch 63 for detecting a state in which a game ball to be paid out is lost, a lower plate full switch (lower plate full SW) 64 for detecting a state in which the lower plate 7 is full of game balls, and a glass A door opening switch (door opening SW) 65 for detecting the state in which the frame 3 is opened is electrically connected to a launch control board 66 for controlling a launch motor 75 that launches a game ball.

  The payout control MPU 51 and the main control MPU 41 are electrically connected by a communication line M1, and the payout control CPU 52 receives a payout control command (a predetermined number of games) transmitted from the main control CPU 42 via the communication line. In accordance with a command for instructing to pay out a ball, the driving of the payout motor 61 is controlled to pay out a winning ball or a rental ball. The payout control CPU 52 counts the number of game balls that have been paid out based on the change in the payout detection signal from the payout sensor 62.

  A launch motor 75, a launch volume 67, and a touch sensor 68 are electrically connected to the launch control board 66. The launch volume adjusts the launch intensity of the game ball launched by the launch motor, and the touch sensor 68 is disposed on the launch lever 9 and detects a hand touching the launch lever 9. When the touch sensor 68 is turned on, the firing motor 75 is driven.

  As shown in FIG. 3, the power supply board 20 is electrically connected to the effect control board 30, the main control board 40, the payout control board 50, and the lamp control board 80. A power supply 8 and a RAM clear switch (RAM clear SW) 4 are electrically connected. A power supply circuit 21 is mounted on the power supply board 20, and a main power supply changeover switch SW (FIG. 5) for switching the main power supply 8 to ON or OFF is electrically connected to the power supply circuit 21. A power cord having a power plug at the tip is connected to the power board 20, and the main power supply 8 is connected by inserting the power plug into an AC 24 V power outlet disposed in the vicinity of the installation location of the pachinko machine 1. AC24V is supplied to the pachinko machine 1.

  When the RAM clear switch 4 is turned on while the main power supply switch SW is turned on, the main control reproduction data backed up in the main control RAM 44 and the unpaid winning ball number data backed up in the payout control RAM 54, etc. Is erased.

(Configuration of power supply circuit)
As shown in FIG. 5, the power supply circuit 21 includes a light emitting diode LD2 that lights in green when the AC power supplied from the main power supply 8 is in the vicinity of the rated 24V, and the AC power supplied from the main power supply 8 is rated. A light emitting diode LD1 that is lit in red when the allowable range of the power source is exceeded, and a drive circuit 27 for driving the light emitting diodes LD1 and LD2 are provided. A b-contact type relay Ry that opens when the AC power supply exceeds the allowable range of the rated power supply is connected to the supply line L1 of the AC power supply supplied from the main power supply 8.

  A power switch SW for supplying and stopping supply of the AC 24V to the pachinko machine 1 is connected to the supply electric lines L1 and L2 at the subsequent stage of the relay Ry by opening and closing the supply electric lines L1 and L2. A fuse Fu that cuts off the supply electric circuit L1 by fusing when an overcurrent flows through the supply electric circuit L1 is connected to the supply electric circuit L1 at the latter stage of the power switch SW. A varistor Va for protecting the circuit from a lightning surge or the like is connected between the supply electric circuits L1 and L2 at the subsequent stage of the fuse Fu.

A diode bridge B1 for converting AC 24V supplied from the main power supply 8 into a 32V DC power supply is connected to the supply electric lines L1 and L2 in the subsequent stage of the varistor Va.
The 32V DC power converted by the diode bridge B1 is supplied to the main control board 40 and the payout control board 50. The 32V DC power supplied to the main control board 40 is used as driving power for the special prize opening solenoid 69 and the ordinary electric accessory solenoid 70 via the panel relay terminal plate 60. The 32V DC power supplied to the payout control board 50 is used as drive power for the payout motor 61 and the launch motor 75.

  The anode of the diode D2 is connected to the supply circuit L1 between the varistor Va and the diode bridge B1, and the anode of the diode D3 is connected to the supply circuit L2 between the varistor Va and the diode bridge B1. Yes. That is, AC24V supplied from the main power supply 8 is divided into two by the diode bridge B1 and the diodes D2 and D3.

  In this embodiment, the four diodes D7 to D10 and the diodes D2 and D3 constituting the diode bridge B1 are Schottky barrier diodes. By using the Schottky barrier diode, the heat generation amount of the power supply circuit 21 can be reduced and the power supply utilization efficiency can be increased by utilizing the characteristic of the Schottky barrier diode that the resistance value is small.

  The cathodes of the diodes D2 and D3 are connected to a common DC power supply line L5 (cathode common), and the DC power supply line L5 on the cathode side of the diodes D2 and D3 protects the circuit against inrush current. An NTC type power thermistor Pa is connected. The anode of the diode D4 is connected to the DC power supply line L5 on the output side of the power thermistor Pa, and the DC power supply converted by the diodes D2 and D3 is connected to the DC power supply line L5 on the cathode side of the diode D4. Is connected to a DC-DC converter 1 that converts the power to a DC power source of 5V.

The DC power supply line L5 between the cathode of the diode D4 and the DC-DC converter 1 is an operation for compensating the operation of the DC-DC converter 1 when the supply of AC 24V from the main power supply 8 is cut off. A compensation capacitor C5 is connected in parallel.
The 5V DC power converted by the DC-DC converter 1 is supplied to the main control board 40, the payout control board 50, and the effect control board 30, and each operation of the main control MPU 41, the payout control MPU 51, and the effect control MPU 31. Used as a power source. Further, the 5 V DC power supply is supplied from the payout control board 50 to the launch control board 66 and used as an operation power supply for a launch control MPU (not shown) mounted on the launch control board 66.

A DC power supply line L6 is connected to the cathode side of the diode D4, and a DC-DC converter that converts the DC power converted by the diodes D2 and D3 into a 12V DC power supply is connected to the DC power supply line L6. 2 is connected.
The DC power supply line L6 is connected in parallel with an operation compensation capacitor C6 for compensating for the operation of the DC-DC converter 2 when supply of AC 24V from the main power supply 8 is cut off.

  The 12V DC power converted by the DC-DC converter 2 is supplied to the main control board 40 and the payout control board 50. The 12V DC power supplied to the main control board 40 is used as operating power for each of the big winning opening switch 71, each winning opening switch 72, the gate switch 73 and the starting opening switch 74 via the panel surface relay terminal board 60. . The 12V DC power supplied to the payout control board 50 is used as each operation power supply for the payout sensor 62 and the touch sensor 68.

A direct current power supply line L7 is connected to the direct current power supply line L5 on the anode side of the diode D4, and the direct current power converted by the diodes D2 and D3 is converted into a 12V direct current power supply to the direct current power supply line L7. A DC-DC converter 3 for conversion is connected.
Compensation capacitors C7 and C8 for compensating for the operation of the DC-DC converter 3 when the supply of AC 24V from the main power supply 8 is cut off are connected to the DC power supply line L7 in parallel.

  The 12V DC power converted by the DC-DC converter 3 is supplied only to the effect control board 30. The 12V DC power supplied to the effect control board 30 is supplied to the lamp control board 80 and the effect indicator 10. The 12V DC power supplied to the lamp control board 80 is used as an operating power for various LEDs provided on the game board 5 and the like. The 12V DC power supplied to the effect display 10 is used as an operating power supply for the effect display 10. The 12V DC power supplied to the effect control board 30 is used as an operation power supply for a sound control device (not shown) mounted on the effect control board 30.

  Diode D4 prevents power supply noise from flowing into DC-DC converters 1 and 2 from DC power supply line L5. Further, the diode D4 prevents the discharge current of the operation compensation capacitors C5 and C6 from flowing backward when the power is cut off and being consumed by the effect control board 30.

  As described above, the AC 24V supplied from the main power supply 8 is converted into a 32V DC power supply by the diode bridge B1, and the 32V DC power supply is supplied to the high voltage operating system of the motor and the solenoid. The DC power converted by the diodes D2 and D3 is converted into a 5V DC power by the DC-DC converter 1, and the 5V DC power is supplied to the low voltage operating system of each MPU. The DC power converted by the diodes D2 and D3 is converted into a 12V DC power by the DC-DC converters 2 and 3, and the 12V DC power is supplied to the low voltage operating system of each switch and sensor. The

That is, in the conventional configuration, the current that has been concentrated in one system of the conversion circuit is branched into two systems of the diode bridge B1 and the diodes D2 and D3 having the cathode common, and the former is connected to the high voltage operation system, Since the low voltage operating system is connected to the latter via the DC-DC converters 1 to 3, the adverse effect of noise propagating from the high voltage operating system on the stable operation of the low voltage operating system can be alleviated.
In particular, there is no possibility that the MPU operated by the 5V DC power supply malfunctions due to the influence of the drive noise of the motor and solenoid continuously operated by the 32V DC power supply.

In the DC power supply line L5, a diode D4 is provided between the main board (main control board and payout control board) system that affects the game result and the effect control board system that does not affect the game result. Since the connection is made, it is possible to mitigate malfunctions of the main board system caused by power consumption in the effect control board.
Further, since the current that has been concentrated on the single conversion circuit in the conventional configuration is branched into two lines, the amount of heat generated by the diode bridge B1 and the like can be reduced.
Accordingly, changes in temperature characteristics of transistors, diodes, and the like can be suppressed, so that the operation of the power supply circuit 21 can be stabilized.

  FIG. 6 is an explanatory diagram showing a part of the power supply board 20. A radiator 94 is attached to the power supply board 20, and a packaged diode bridge B <b> 1 is attached to the radiator 94. The radiator 94 radiates heat generated from the diode bridge B1, thereby suppressing a temperature rise of the diode bridge B1 and reducing a change in temperature characteristics of each diode constituting the diode bridge B1. The radiator 94 has a plurality of heat radiation fins 94a. In this embodiment, the radiator 94 is made of aluminum because it has a high heat exchange rate and is lightweight.

  A power thermistor Pa is disposed immediately above the radiator 94. That is, the power thermistor Pa is disposed in a region that receives heat radiated from the radiator 94. The power thermistor Pa is a so-called NTC (Negative Temperature Coefficient) type power thermistor having negative temperature characteristics. As is well known, an NTC type power thermistor has a property that its own resistance value decreases as its temperature rises.

  Since the power thermistor Pa of this embodiment is disposed in a region that receives heat radiated from the radiator 94, in addition to its own heat generation, the heat thermistor Pa radiates heat radiated from the radiator 94 due to heat generation of the diode bridge B1. Since the heat is received and heated, the resistance value is further reduced than the resistance value is decreased due to self-heating.

  Accordingly, the amount of heat generated by the power supply circuit 21 can be reduced by that amount, and the use efficiency of the AC 24V supplied from the main power supply 8 can be increased. it can.

Moreover, since the conversion circuit for converting AC24V supplied from the main power supply 8 into the DC power supply of 32V is two systems of the diode bridge B1 and the diodes D2 and D3, the amount of heat generated from the conversion circuit is dispersed. Can do.
Therefore, there is no possibility that the temperature of the transistor or the diode disposed in the vicinity of the conversion circuit will rise and the operating characteristics will not be deteriorated.

Furthermore, since the heat generation amount of the diode bridge B1 can be reduced, the heat dissipation area of the radiator 94 for radiating the heat generated from the diode bridge B1 can be reduced, and thus the radiator 94 can be downsized. Can do.
Therefore, the power supply board 20 can be reduced in size.

When a diode bridge such as the diode bridge B1 (hereinafter referred to as a diode bridge B3) is used in place of the diodes D2 and D3, feedback is made to the main power supply 8 corresponding to the current supplied via the diode bridge B1. Current that flows through the diode bridge B3 from the ground may be consumed, which introduces uncertain elements in the thermal design, such as the selection of a radiator. If it does so, there is no method other than attaching the thing of the largest dimension which can be assumed with respect to the calorific value which cannot be predicted as a heat sink of each diode bridge, and will invite the enlargement of the power supply board 20.
However, in this embodiment, since the diodes D2 and D3 not having the bridge configuration are used, the above-described problem does not occur, and the size of the heat sink 94 of the diode bridge B1 can be selected to the minimum. Can be miniaturized.

(Configuration of power failure detection)
As shown in FIG. 3, a power supply voltage monitoring unit 22 is mounted on the power supply board 20. The power supply voltage monitoring unit 22 is electrically connected to the DC32V line L4 on the output side of the diode bridge B1 (FIG. 5). The power supply voltage monitoring unit 22 includes a power failure detection circuit 23, a power cut signal generation circuit 24, a power cut signal output prohibition circuit 25, and an output signal control IC 26. The power supply voltage monitoring unit 22 is electrically connected to each control board.

  The power failure detection circuit 23 detects a voltage drop of DC 32 V and DC 12 V, and when it drops to a predetermined voltage (hereinafter referred to as a power failure detection voltage), a signal indicating a power failure (hereinafter referred to as a power failure detection signal) is generated. To 24.

  The power cut signal generation circuit 24 inputs the power cut detection signal output from the power cut detection circuit 23, and outputs the power cut signal to the output signal control IC 26 and the power cut signal output prohibition circuit 25 while the power cut detection signal is input. Output to.

  The power-off signal output prohibiting circuit 25 plays a role of outputting a power-off signal and a role of prohibiting output of the power-off signal. When the power is shut off, the power-off signal output from the power-off signal creation circuit 24 is input, the power-off signal is output to the output signal control IC 26, and the system reset signal is output to the output signal control IC 26. Further, when the power is restored, the output of the power-off signal is prohibited and the system reset signal is canceled.

  The output signal control IC 26 inverts the level of the power-off signal PWRDWN) output from the power-off signal output prohibiting circuit 25 and outputs it to the power-off signal input terminals of the main control MPU 41 and the payout control MPU 51. When the main control CPU 42 determines the input of the power-off signal, the main control CPU 42 executes NMI (non-maskable interrupt) processing for prohibiting access to the main control RAM 44, and the payout control CPU 52 receives the power-off signal. Then, NMI processing for prohibiting access to the payout control RAM 54 is executed.

  Further, the output signal control IC 26 inverts the level of the system reset signal (SYSRST) output from the power-off signal output prohibiting circuit 25 and outputs it to the system reset signal input terminals of the main control MPU 41 and the payout control MPU 51. . When determining that the system reset signal is input, the main control MPU 41 and the payout control MPU 51 each execute a system reset process.

  The power-off signal output prohibiting circuit 25 has a power-off signal delay circuit for delaying the output timing of the power-off signal. In other words, the period during which the power-off signal output is in the active state is more varied than the timing at which the system reset signal is output, such as variations in the input circuit time constant that exists between at least the main control MPU 41 and the payout control MPU 51. By extending the time exceeding the maximum value of the delay time deviation due to, each control CPU can smoothly transition from the NMI processing to the system reset operation.

Further, the power-off signal output prohibiting circuit 25 has a reset signal delay circuit for delaying the output timing of the reset signal. In other words, the system reset signal SR is enabled during the NMI processing by outputting the reset signal after the period during which the power-off signal is in the active state (the period in which data backup and NMI processing are effective). Never become.
Therefore, there is no difference between the gaming state reproduced at the time of power recovery based on the backed up data and the gaming state at the time of power failure.

It is a perspective view which shows the external appearance of the pachinko machine which concerns on embodiment of this invention. It is the schematic explanatory drawing which looked at the game board with which the pachinko machine shown in FIG. 1 was equipped from the front. It is explanatory drawing which shows main electrical structures, such as a main control board and a payout control board, with a block. It is explanatory drawing which shows main electrical structures, such as a power supply board and an effect control board, with a block. FIG. 4 is a circuit diagram of a power supply circuit mounted on the power supply board shown in FIG. 3. FIG. 3 is an explanatory diagram showing a part of a power supply substrate 20.

Explanation of symbols

1 ... Pachinko machines (game machines), 8 ... Main power supply (AC power supply), 94 ...
B1 .. Diode bridge (conversion circuit),
D2, D3 · · diode (conversion circuit),
Pa power thermistor.

Claims (1)

In gaming machines that use AC power supplied from outside the gaming machine converted to DC power,
Two conversion circuits for converting the AC power source into a DC power source;
The other system of the conversion circuit is attached, and a heat radiator that radiates heat generated from the conversion circuit of the other system ,
An NTC type power thermistor connected to the output side of one system of the conversion circuit and disposed in a region for receiving heat radiated from the radiator;
Equipped with a,
The conversion circuit of the other system is configured to convert the AC power source into a DC power source having a predetermined voltage,
The DC power supply line on the output side of the power thermistor connected to the conversion circuit of the one system converts the DC power converted by the conversion circuit of the one system into a voltage lower than the predetermined voltage. A gaming machine characterized in that a converter is connected .

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