JP2010142543A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a slot machine capable of reliably eliminating an illegal action. <P>SOLUTION: The slot machine includes a putout control section 55 receiving a power supply DC5V to be supplied to a photocoupler PC, a power supply DC24V to be supplied to a putout motor MO and a token putout signal PAY turning on the photocoupler PC, from other control section through a wiring connector, wherein the putout control section 55 actuates the putout motor MO and puts out tokens to a player. The slot machine is provided with: a first means (ST16) to start feeding of the DC power supply prior to the ON operation of the photocoupler PC; and a second means (ST26) to stop feeding of the DC power supply after the ON operation of the photocoupler PC is completed. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electronic gaming machine having a built-in computer device, and is particularly preferably applied to a spinning game machine or a ball game machine that uses medals or game balls as game media.

  In a spinning machine such as a slot machine, when a player inserts a medal into a medal slot and operates a start lever, the rotation of the rotating reel is started accordingly. When the player presses the stop button to stop the rotating reel, when the symbols on the stop line are aligned, a payout medal corresponding to the symbol is paid out. However, the success / failure state of each game is actually determined in advance by the lottery process inside the device at the start of each game, and the player wins the dividend medal by aligning the symbols won by this lottery process on the stop line. Is paid out.

  This payout medal is stored in advance in a medal hopper arranged in each slot machine. Then, when the payout motor MO rotates and pays out medals, and the payout detection sensor confirms the required number of payouts, the payout operation ends.

  The payout motor MO is composed of, for example, a DC motor that rotates at a voltage of DC 24V. A photocoupler that receives the medal payout signal PAY is provided, and when the medal payout signal PAY becomes L level, the transistor on the output side of the photocoupler is turned on to form a DC motor current drive circuit. Yes.

However, since the payout motor starts rotating when the medal payout signal PAY becomes L level, there is a concern about an illegal act of misusing this relationship and dropping the medal payout signal to the ground. Therefore, various crime prevention circuits have been proposed to eliminate such illegal acts (Patent Document 1). However, when an excellent crime prevention circuit is mounted, illegal acts using a so-called “hanging board”. Become powerless.
JP 2005-143656 A

  Here, the “hanging board” means an illegal circuit board disposed between a regular circuit board and a regular circuit board, and a desired illegal signal is generated and output on the illegal circuit board. Then, the security function will be disabled.

  Therefore, there is a strong demand for a configuration of a gaming machine that reliably exhibits a crime prevention function even after the wiring connector is removed and the illegal circuit board is attached, and even when the gaming machine is reset in power.

  In addition, since the crime prevention function is provided, for example, it is meaningless if the payout operation is disturbed, and a circuit configuration of a gaming machine that always operates properly is required.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a gaming machine that can reliably eliminate illegal acts and always operates appropriately.

  In order to achieve the above object, the present invention provides a wiring connector comprising a first power source supplied to an interface element, a second power source supplied to a payout motor, and a payout signal for turning on the interface element. The payout control unit receives the valuables from the player by driving the payout motor in response to the ON operation of the interface element. A game machine that outputs the first power supply and / or the second power supply in response to a change in level of the payout signal for turning on the interface element; and the payout signal The second means for stopping the power supply of the first power source and / or the second power source is provided in response to the level return.

  In the present invention, since the first power supply and the second power supply are not supplied to the dispensing control unit except when necessary, the dispensing motor is rotated even if an illegal circuit board is arranged between the regular circuit boards. I can't. Since this crime prevention function is maintained in the same manner even when the gaming machine is reset, the illegal action cannot be successful anyway. Even if a battery is mounted on an illegal circuit board, the necessary electrical energy cannot be generated.

  In a simple manner, the first means of the present invention should start the power supply of the power supply prior to the change in the level of the payout signal. With such a configuration, the first power source and the second power source are reliably stabilized at the rotation start timing of the payout motor, and there is no room for transient abnormal operation. Even when power supply is started in synchronization with the change in the level of the payout signal, a rotation limiting operation can be performed by providing a current limiting circuit that suppresses a rush current or the like or by providing an appropriate operation delay circuit. Normal operation at the start can be ensured.

  On the other hand, the second means of the present invention should simply stop the power supply after the return of the level of the payout signal is completed. By adopting such a configuration, even after the payout motor finishes the payout operation, the power supply state is maintained for a while, so that the payout motor can be appropriately braked. Of course, even when the power supply is stopped in synchronization with the return of the level of the payout signal, it is possible to prevent payout of an extra valuable material due to inertial force by providing an appropriate power storage mechanism (such as a large capacity capacitor).

  By the way, when this invention takes the embodiment which controls the electric power feeding of any one of a 1st power supply and a 2nd power supply, the power supply control circuit should preferably control a 2nd power supply. Because the power supply voltage and current capacity of the second power supply is usually higher than that of the first power supply, even if an illegal circuit is installed, the second power supply can be illegally generated based on the first power supply. Because it is difficult.

  In any case, the payout signal is output from a signal output circuit that receives a drive signal having a pulse width corresponding to the number of payouts of valuable materials and performs a switching operation, and the signal output circuit is sent to the other control unit. It is preferred that they are arranged. Preferably, the power supply control circuit for realizing the first means and the second means should be disposed in the other control unit.

  The power supply control circuit preferably includes a first switch circuit disposed on a power supply line of the first power supply. Here, the first switch circuit preferably operates by receiving a control signal having the same logic level as that of the drive signal and a pulse width wider than that of the drive signal. In this case, the first means starts power supply before the ON operation, and the second means stops power supply after completing the ON operation.

  The first switch circuit includes a NOT circuit that receives the control signal and performs a logic inversion operation, and a unipolar transistor that receives an output of the NOT circuit at a control input terminal. preferable.

  The power supply control circuit preferably includes a second switch circuit disposed on a power supply line of the second power supply. Here, it is preferable that the second switch circuit operates by receiving a control signal having the same logic level as that of the drive signal and a pulse width wider than that of the drive signal. The second switch circuit includes a first transistor that performs an ON operation in response to the control signal, and a second transistor that performs an ON operation in response to the ON operation of the first transistor, It is effective that the second power supply is supplied to the dispensing control unit in response to the ON operation of the second transistor. The second transistor is preferably a unipolar transistor.

  According to the present invention described above, it is possible to realize a gaming machine that can reliably eliminate illegal acts and always operates appropriately.

  Hereinafter, the present invention will be described in more detail based on examples. 1 to 4 illustrate a slot machine SL according to an embodiment. In this slot machine SL, a rectangular box-shaped main body case 1 and a front panel 2 fitted with various game members are connected via a hinge 3 so that the front panel 2 can be opened and closed with respect to the main body case 1. (FIG. 2). 1 is a front view of the front panel 2, FIG. 2 is a right side view (a) and a plan view (b) of the slot machine SL, FIG. 3 is a rear view of the front panel 2, and FIG. A front view is shown.

  As shown in FIG. 4, a symbol rotating unit 4 including three rotating reels 4 a to 4 c is disposed in the approximate center of the main body case 1, and a medal payout device 5 is disposed below the symbol rotating unit 4. On each of the rotating reels 4a to 4c, a BB symbol, an RB symbol, various fruit symbols, a replay symbol, and the like are drawn. The medal payout device 5 is provided with a medal hopper 5a for storing medals, a payout motor MO, a medal payout control board 55, a payout relay board 63, a payout sensor SE (FIG. 5), and the like. Here, the medal is derived from the payout opening 5b toward the front of the drawing based on the rotation of the payout motor MO. Note that medals stored exceeding the limit amount are configured to fall into the auxiliary tank 6 through the overflow portion 5c.

  A power supply board 62 is arranged adjacent to the medal payout device 5, a main control board 50 is arranged above the symbol rotation unit 4, and a rotating drum setting board 54 is arranged adjacent to the main control board 50. ing. In addition, inside the symbol rotating unit 4, a rotating LED relay substrate 58 and a rotating relay substrate 57 are provided, and an external concentrated terminal plate 56 is disposed adjacent to the symbol rotating unit 4.

  As shown in FIG. 1, a liquid crystal display unit 7 is disposed on the upper portion of the front panel 2, and three display windows 8a to 8c corresponding to the rotating reels 4a to 4c are disposed on the lower portion thereof. Through the display windows 8a to 8c, about 3 symbols can be seen in the rotational direction of each of the rotating reels 4a to 4c, and a total of 9 symbols in the horizontal direction and 2 in the diagonal direction. Becomes a virtual stop line. On the left side of the display window 8a, an LED group 9 indicating a gaming state is provided. Below that, a payout display unit 10 for displaying the number of medals to be paid out as a gaming result, and the number of medals in a credit state are displayed. The storage number display part 11 to display is provided.

  In the center of the front panel 2 in the vertical direction, a medal insertion slot 12 for inserting medals is provided, and adjacent thereto, a return button 13 for returning medals filled in the medal insertion slot 12 is provided. Also, a credit check button 14 for paying out a credit medal, an insertion button 15 for artificially inserting one credit medal in place of inserting a medal into the medal slot 12, and a credit medal in a pseudo manner A maximum loading button 16 for loading three sheets is provided.

  Below these game members, a start lever 17 for starting the rotation of the rotating reels 4a to 4c and stop buttons 18a to 18c for stopping the rotating reels 4a to 4c are provided. In addition, below the front panel 2, a horizontally long tray 19 for storing medals and a medal outlet 20 communicating with the payout port 5b of the payout device 5 are provided. Speakers SP are arranged on the left and right sides of the medal outlet 20.

  As shown in FIG. 3, on the back side of the front panel 3, a medal sorting device 21 that sorts medals inserted into the medal slot 12, and medals that are determined to be inappropriate by the medal sorting device 21 A return passage 22 that guides the vehicle 20 is provided. A substrate case 23 that houses the effect control board 51, the effect interface board 52, the liquid crystal control board 61, and the like is disposed on the upper back side of the front panel 3. A game relay board 53 that relays signals between the various game members shown in FIG. 1 and the main control board 50 is provided on the medal sorting device 21.

  FIG. 5 is a block diagram illustrating a circuit configuration of the slot machine SL according to the embodiment. As shown in the figure, this slot machine SL realizes an effect operation based on a main control board 50 that controls the operation of various game members including the rotating reels 4a to 4c and a control command received from the main control board 50. The control board 51 and a power supply board 62 that converts an alternating voltage (24V) into a direct voltage (5V, 12V, 24V) and supplies them to each part of the apparatus are mainly configured.

  The main control board 50 outputs, to the effect control board 51, control commands for realizing the sound effect by the speaker SP, the lamp effect by the LED lamp or the cold cathode ray tube discharge tube, and the symbol effect by the liquid crystal display unit 7. is doing. The effect control board 51 is connected to the liquid crystal control board 61 through the effect interface board 52, and the liquid crystal control board 61 realizes a design effect in the liquid crystal display (LCD) unit 7.

  The effect control board 51 realizes lamp effects in various LEDs and cold cathode ray tube discharge tubes via the LED board 59, the inverter board 60, and the rotary LED drive board 58 together with the effect interface board 52. In addition, the effect control board 51 drives the speaker SP through the effect interface board 52 to realize an audio effect.

  The main control board 50 is connected to various game members of the slot machine through the game relay board 53. Specifically, the start switch of the start lever 17, the stop switch of the stop buttons 18a to 18c, the input switch of the input buttons 15 and 16, the liquidation switch of the checkout button 14, and the photointerrupters PH1 and PH2 constituting the input number determination unit 21d The blocker solenoid 31 constituting the inserted medal return unit 21c and the various LED elements 9 to 11 are connected.

  Further, the main control board 50 is connected to the three stepping motors for rotating the rotating reels 4a to 4c and the index sensor for detecting the reference position of the rotating reels 4a to 4c via the rotating relay board 57. Has been. Then, by rotating or stopping the stepping motor, the rotating operation of the rotating reels 4a to 4c and the stopping operation at the target position are realized.

  The main control board 50 is also connected to the medal payout device 5 through the payout relay board 63. The medal payout device 5 is provided with a medal payout control board 55, a medal payout sensor SE, and a payout motor MO. The medal payout control board 55 is based on a medal payout signal PAY from the main control board 50. The payout motor MO is rotated to pay out a predetermined amount of medals. The payout motor MO is a DC motor such as a brush motor, and continues to rotate as long as it receives DC 24V.

  In addition, the main control board 50 is also connected to the external concentration terminal board 56 and the rotary setting board 54. The external concentrated terminal board 56 is connected to, for example, the hall computer HC, and the main control board 50 outputs the number of inserted medals and the number of paid out medals through the external concentrated terminal board 56. Further, the rotating setting board 54 outputs a setting key signal indicating the rank setting value of the probabilistic medal payout number set by the staff.

  FIG. 6A is a schematic diagram illustrating the connection relationship among the main control board 50, the payout relay board 63, and the medal payout control board 55. As illustrated, the medal payout control board 55 receives the medal payout signal PAY, DC5V, and DC24V from the main control board 50 via the payout relay board 63. Here, each circuit board 50, 63, 55 is connected to an adjacent circuit board via the wiring connectors CN1 to CN4.

  As shown in FIG. 6A, the output unit of the main control board 50 includes a signal output unit 70 that outputs a medal payout signal PAY, and a power supply control unit 71 that controls the feeding of DC5V and DC24V. ing. The medal payout signals PAY, DC5V, and DC24V are output from the wiring connector CN1 together with other signals including the ground signal.

  The signal output unit 70 includes a bipolar transistor Qa that performs a switching operation in response to a driving pulse SG having a pulse width τ corresponding to the number of medals to be paid out, and a base resistance Ra of the transistor Qa. As shown in the drawing, the base terminal of the transistor Qa receives the drive pulse SG through the base resistor Ra, and the emitter terminal is connected to the ground. The collector terminal of the transistor Qa is connected to the wiring connector CN1 as an output terminal of the medal payout signal PAY.

  As shown in FIG. 6C, the medal payout signal PAY is supplied to the current outflow terminal of the photocoupler PC (light emitting diode D) of the medal payout control board 55, and the current inflow terminal of the photocoupler PC has a current limiting resistor. The output of the power supply control unit 71 is supplied through R1. In a normal operation state, the corresponding output of the power supply controller 71 is approximately DC 5 V, so the ON current Ion flowing through the photocoupler PC is Ion≈ (5-Vf) / R1. Vf is a voltage drop at the photocoupler PC.

  As shown in FIG. 6B, the drive pulse SG becomes the H level only during the payout operation, and maintains the L level in the other steady state. For this reason, the transistor Qa is turned on only during the payout operation, and is kept in the OFF state at other times. As a result, when the power supply control unit 71 outputs DC 5 V, the medal payout signal PAY becomes L level only during the payout operation when the drive pulse SG becomes H level, and maintains the H level in other steady states. .

  FIG. 6C illustrates an example of the circuit configuration of the power supply control unit 71. The power controller 71 includes a first switch circuit 91 that controls opening / closing of a DC 5V power line and a second switch circuit 92 that controls opening / closing of a DC 24V power line. And is controlled by a single enable pulse ENBL. That is, when the enable pulse ENBL is at the H level, DC 24V and DC 5V are output, but when the enable pulse ENBL is at the L level, the output of each DC voltage is prohibited.

  The first switch circuit 91 includes a NOT gate G1 that receives the enable pulse ENBL, and a unipolar transistor Qb that receives the output of the NOT gate G1 at its gate terminal. Specifically, the transistor Qb is a P-channel MOS transistor, and DC5V is supplied to the source terminal, and the drain terminal is connected to the wiring connector CN1.

  The second switch circuit 92 is configured to turn on the N-channel MOS transistor Qc receiving the enable pulse ENBL at the gate terminal, the bias resistor R22 connected between the drain terminal of the transistor Qc and the DC24V power supply line, and the transistor Qc. Correspondingly, it has a P-channel MOS transistor Qd which is turned on.

  The source terminal of the transistor Qc is connected to the ground, and the drain terminal is connected to the bias resistor R22 and the gate terminal of the transistor Qd. Then, DC24V is supplied to the source terminal of the transistor Qd, and the drain terminal is connected to the wiring connector CN1.

  Next, the operation content of the power supply control unit 71 having the above configuration will be described. First, consider a steady state (when not driven) in which the dispensing motor MO is not rotated.

  At the time of non-driving, the enabling pulse ENBL is at the L level, so that the gate terminal of the transistor Qb is at the H level, the transistor Qb is turned off, and DC5V is not output to the wiring connector CN1. Similarly, since the gate terminal of the transistor Qc is at the L level, both the transistor Qc and the transistor Qd are turned off, and no DC 24V is output to the wiring connector CN1.

  On the other hand, the drive pulse SG rises to the H level at the timing of driving the payout motor MO, but in this embodiment, the permission pulse is controlled to rise to the H level prior to the rise timing. When the permission pulse becomes H level, the transistors Qb to Qd are all turned on, and DC5V and DC24V are output to the wiring connector CN.

  Then, after each circuit of the medal payout control board 55 that is supplied with power from each DC power supply is stabilized, the drive pulse SG becomes H level to turn on the transistor Qa. Then, when the photocoupler is turned on, the medal payout operation is started. This payout operation will be further described later.

  Thereafter, when a series of payout operations are completed, the drive pulse SG falls to the L level. After that, after the payout motor MO is completely stopped, the enable pulse ENBL becomes the L level and the above-described steady state is started. . Therefore, there is no possibility that the medal is overpaid due to inertial force or the like.

  FIG. 7 is a flowchart for explaining the medal payout operation including the control of the permission pulse ENBL. First, it is determined whether or not the number of medals to be paid out to the player is 0 (ST10). If the number of medals paid out is not 0, the number of credits is increased until the number of credits reaches an upper limit (for example, 50). By doing so, a pseudo payout process is executed (ST11 to ST13).

  On the other hand, when the number of credits reaches the upper limit value or reaches the upper limit value in this way, the value of the operation flag FLG is first checked (ST15). Here, the operation flag FLG indicates whether or not the enable pulse ENBL has been raised to the H level, and FLG = 1 is set at the timing of step ST16 prior to the payout operation, and the step in which the payout operation has been finished reliably. FLG = 0 is set at the timing of ST27.

  Therefore, now, assuming that the operation flag FLG = 0 and the payout operation has not yet started, the operation flag FLG is set to 1 and the enable pulse ENBL is raised to the H level (ST16). Then, since DC 24V and DC 5V are supplied to the medal payout control board 55, time is consumed for a predetermined time until the operation of each circuit that receives the supply is stabilized (ST17).

  Then, after the operation of the medal payout control board 55 is stabilized, the medal payout signal PAY is set to the ON level (L level) (ST18). Specifically, the photocoupler PC of the medal payout control board 55 is turned on by turning on the transistor Qa of the main control unit 50. As a result, the payout motor MO starts rotating and the payout of medals is started.

  When the medal payout operation is started, it is next determined whether or not the payout sensor SE (FIG. 5) detects medal payout (ST19), and waits for a predetermined waiting time until the medal payout is detected ( ST21). If a medal payout is detected, the payout number is subtracted (ST20), and the same operation is repeated until the remaining payout number becomes zero.

  On the other hand, if the payout sensor SE does not detect the payout of medals even after the predetermined standby time is exceeded, it is considered that the medal hopper 5a is empty, and an abnormality notification process to that effect is executed (ST22). When the opening / closing of the door sensor is detected (ST23), assuming that the replenishment process by the clerk is completed, the error notification process is canceled (ST24), and the process returns to step ST15.

  If such processing is repeated, the remaining payout number eventually becomes 0 (ST13), and first, the medal payout signal PAY is returned to the OFF level (H level) (ST14). Specifically, the photocoupler PC of the medal payout control board 55 is turned off by turning off the transistor Qa of the main control unit 50. As a result, the rotation of the payout motor MO is stopped.

  Subsequently, after waiting for a predetermined time during which the payout motor MO is surely stopped (ST25), the permission pulse ENBL is returned to the L level (ST26), the operation flag FLG is returned to zero, and the process is ended (ST27).

  As described above, in the present embodiment, by providing the time consumption process (ST17, ST25), the enabling pulse ENBL is raised appropriately preceding the driving pulse SG, and the enabling pulse ENBL is appropriately delayed after the driving pulse SG. Has fallen. As a result, an appropriate medal payout operation is realized without causing a device trouble. Further, since the DC power is not supplied to the medal payout control board 55 at the timing when the payout motor MO is not driven, there is no possibility of illegal action.

  FIG. 8 illustrates the circuit configuration of the medal payout control board 55 and the operation during the payout operation. The payout relay board 63 is not shown because it only distributes and transmits various signals.

  As described with reference to FIG. 6, the medal payout control board 55 is connected to the payout relay board 63 through the connector CN4, and receives DC24V, DC5V, and the medal payout signal PAY from the main control board 50. If the payout motor MO is connected to the connector CN5 of the medal payout control board 55 and the medal payout signal PAY is at the active level (L level), the payout motor MO receives DC24V and continuously rotates. It has become.

  The medal payout control board 55 includes a signal transmission circuit 81 using a photocoupler PC, a current limiting circuit 82 using bipolar transistors Q3 and Q4, a drive control circuit 83 using a unipolar transistor Q5, and a braking circuit 84 using a unipolar transistor Q6. And are provided.

  The signal transmission circuit 81 is composed of a series circuit of a current limiting resistor R1 and a light emitting diode D of the photocoupler PC, DC5V output from the power supply control unit 71 of the main control board 50, and medal payout signal output from the transistor Qa. Functioning in response to PAY. That is, when the photocoupler PC receives the L level medal payout signal PAY in the DC 5V power supply state, the light emitting diode D emits light and the phototransistor Tr is turned on. In response to the ON operation of the transistor Tr, DC24V can be supplied, and the current limiting circuit 82 and the drive control circuit 83 can be operated.

  The current limiting circuit 82 includes a PNP transistor Q3, a collector resistor R4, a bias resistor R10, a current detection resistor R13 of the payout motor MO, a bias resistor R5, a capacitor C1, an NPN transistor Q4, and a current limiting resistor R8. And a reverse current blocking diode D2.

  The emitter terminal of the transistor Q3 is connected to the emitter terminal of the transistor Tr of the photocoupler and the current limiting resistor R8. A current limiting resistor R8 and a diode D2 are connected in series between the emitter terminal and the base terminal of the transistor Q3, and the cathode terminal of the diode D2 is connected to the base terminal of the transistor Q3. The cathode terminal of the diode D2 is connected to the collector terminal of the transistor Q4, and the emitter terminal thereof is connected to the ground. The base terminal of the transistor Q4 is connected to the ground through a capacitor C1 and a resistor R5 connected in parallel.

  The base terminal of the transistor Q4 is connected to the source terminal of the N-channel MOS transistor Q5 through the resistor R10. A resistor R13 is connected between the source terminal of the N-channel MOS transistor Q5 and the ground to monitor the drive current of the payout motor MO. The current detection resistor R13 is about 0.51Ω.

  The drive control circuit 83 includes an N channel MOS transistor Q5, a bias resistor R9, and a capacitor C3. Here, the drain terminal of the MOS transistor Q5 is connected to the (−) terminal of the payout motor MO. A resistor R9 and a capacitor C3 connected in parallel are connected between the base terminal and the source terminal.

  The braking circuit 84 includes a P-channel MOS transistor Q6, voltage dividing bias resistors R11, R12, R6, and R7, a capacitor C2, a reverse current blocking diode D1, and a polyswitch RT. The source terminal and drain terminal of the P-channel MOS transistor Q6 are connected to the (+) terminal and the (-) terminal of the payout motor MO, respectively. Therefore, when the P-channel MOS transistor Q6 is turned on, the driving of the payout motor MO is prohibited.

  On the other hand, a resistor R11 is connected between the source terminal and the gate terminal of the MOS transistor Q6, and bias resistors R12, R6, and R7 are connected in series between the gate terminal and the grant. The cathode terminal of the diode D1 is connected to the connection point between the resistor R12 and the resistor R6. On the other hand, the anode terminal of the diode D1 is connected to the emitter terminal of the transistor Tr of the photocoupler PC and the resistor R8.

The polyswitch RT is connected between the drain terminal of the P-channel MOS transistor Q2 and the (+) terminal of the payout motor MO. Here, the polyswitch is a polymer-based PTC (Positive Temperature Coefficient) thermistor, and when the element temperature rises above a predetermined value, the resistance value of 1Ω or less rapidly increases in a normal state to 10 ⁴ Ω to 10 ^6. It has a characteristic of about Ω. Therefore, for example, when an excessive current flows due to a short circuit of the wiring of the payout motor MO, the DC 24V power line is opened. The polyswitch RT has a great significance at the time of trouble that the current limiting circuit 82 does not function.

  Subsequently, the operation when the main control unit 50 raises the drive pulse SG and the transistor Qa is turned on (ST18 in FIG. 7) will be described. Prior to this timing, DC5V and DC24V are already supplied (ST16), and each circuit of the medal payout control board 55 can operate stably.

  When the transistor Qa is turned on and the medal payout signal PAY becomes the ON level (L level), the ON current flows through the path of the power supply control unit 71 (DC5V) → the resistor R1 → the light emitting diode D of the photocoupler → the transistor Qa, and the photo The coupler PC is turned on. Then, the direct current passing through the transistor Tr of the photocoupler PC in the ON state flows through a path of diode D1 → resistor R6 → R7. In addition, the direct current passing through the transistor Tr also flows through a path of resistance R8 → resistance R9 → resistance R13 and a path of resistance R8 → resistance R9 → resistance R10 → R5. As a result, the transistor Q5 is turned on, the motor drive current flows through the path of the polyswitch RT → the payout motor MO → the transistor Q5, and the payout motor MO rotates.

  At this time, the current limiting circuit 82 functions as a negative feedback circuit that prevents an excessive motor driving current from flowing. That is, since the motor drive current flows through the current detection resistor R13, if the motor drive current increases greatly, the base potential of the transistor Q4 increases, and the collector current flows through the resistor R8 → diode D2 path.

  Then, since the transistor Q4 and the transistor Q3 are connected to each other with a thyristor structure, an increase in the collector current of the transistor Q4 causes an increase in the collector current of the transistor Q3, and the transistor Q4 is connected via the resistor R5. By increasing the collector current more and more, the two transistors Q3 and Q4 form a positive feedback loop for ON operation.

  On the other hand, when the collector current of the transistor Q4 increases toward the saturation current, the potential of the anode terminal of the diode D2 drops, so that a negative feedback loop is formed to turn the transistor Q5 OFF. Therefore, an excessive motor drive current is prevented from flowing based on the operation of transistor Q5, and the motor drive current is maintained in a predetermined range.

By the way, at the timing when the payout motor MO is driven, the transistor Q6 is in the OFF state. The current flows through the path of the resistor R11 → the resistor R12 → the resistor R6 → the resistor R18, and the current also flows through the path of the diode D1 → the resistor R6 → the resistor R18. This is because the saturation voltage V _CE and the forward voltage drop V _{F of the} diode are suppressed to V _CE + V _F ≈1V.

  Next, based on FIG. 9, the operation when the main control unit 50 lowers the drive pulse SG and the transistor Qa is turned off (ST14 in FIG. 7) will be described. As described above, even after the drive pulse SG has fallen, the power supply of DC 24V and DC 5V is continued for a predetermined time (ST25).

  When the transistor Qa is turned off, the photocoupler PC is turned off correspondingly, and the transistors Q3, Q4, and Q5 are not turned on. However, a current flows through the path of the resistor R11 → the resistor R12 → the resistor R6 → the resistor R7 → the ground. Here, since the voltage across the resistor R11 is set to be 24 * R11 / (R11 + R12 + R6 + R7) ≈3 V, the transistor Q6 is turned on by the voltage between the source terminal and the gate terminal.

  Since the ON operation of the transistor Q6 is executed when the photocoupler PC transitions from ON to OFF, the output current of the dispensing motor MO that functions as a generator is absorbed as a short-circuit current of the transistor Q6, and the rotation of the dispensing motor MO The brake is applied. Therefore, according to the configuration of the present embodiment, overpayment of medals due to inertial force is prevented. Thus, after the payout motor MO is suddenly stopped, the power supply of DC24V and DC5V is stopped (ST26). Thereafter, even if an illegal circuit board is mounted, medals cannot be paid out illegally. This point is the same even if the power of the gaming machine is reset, and an extremely powerful crime prevention function is exhibited.

  Although the embodiments of the present invention have been specifically described above, the specific description is not particularly intended to limit the present invention and can be appropriately changed. For example, while the slot machine has been described in the previous embodiment, the present invention is preferably applied to a ball game machine that implements a game ball payout process with a DC motor.

  Further, in the above-described embodiment, the feeding of DC5V and DC24 is started and ended in synchronization, but feeding control of only one of them may be performed. In this case, it is preferable to perform power supply control of DC24V. That is, it is easy to step down DC24V and generate DC5V in an illegal circuit, but conversely, to generate DC24V from DC5V, a DC-DC converter or the like is required. This is because it is difficult to generate enough energy to drive the payout motor MO.

  In the above embodiment, the enable pulse ENBL is raised prior to the rise of the drive pulse SG, and the enable pulse ENBL is lowered after the drive pulse SG is lowered. Absent. FIG. 10 shows an embodiment in which the enable pulse ENBL is not required, and a relatively large capacitor C4 is arranged between the power line of DC 24V and the ground. Further, if necessary, a capacitor C5 is also disposed between the DC5V power line and the ground.

  In this embodiment, power supply to DC5V and DC24V is started in synchronization with the ON operation of the transistor Qa. However, since the capacitor C4 is connected to the power line of DC24V, the capacitor C4 is charged to an appropriate level. Until this time, the ON operation of the photocoupler PC is delayed, and an abnormal transient operation is avoided. Further, since the resistor R1 is connected in series to the DC5V power supply line, the semiconductor elements D and Qa are also prevented from being damaged. The capacitor C5 is arranged as necessary.

  On the other hand, in this embodiment, the power supply of DC5V and DC24V is stopped in synchronization with the OFF operation of the transistor Qa, but the power supply to the payout motor MO is maintained until the charge of the capacitor C4 is discharged. The braking operation described above is ensured.

It is a front view of the slot machine which concerns on an Example. FIG. 2 is a right side view (a) and a plan view (b) of the slot machine of FIG. 1. It is the figure which illustrated the front panel of the slot machine from the back. It is an internal front view of the main body case of the slot machine. FIG. 2 is a block diagram showing a circuit configuration of the slot machine of FIG. 1. It is a block diagram which shows the connection part of the principal part of a main control board, and a main control board and a medal payout control board. It is drawing explaining the circuit structure and payout operation | movement of a medal payout control board. It is drawing explaining operation | movement of the medal | token payout control board at the time of payout operation | movement. It is drawing explaining operation | movement of the medal | token payout control board at the time of payout prohibition. It is drawing explaining another Example.

Explanation of symbols

MO payout motor 55 payout control unit PC interface element PAY payout signal CN4 wiring connector SL gaming machine (slot machine)
71 Power supply control circuit ST16 First means ST26 Second means

Claims (10)

A payout that receives a first power source supplied to the interface element, a second power source supplied to the payout motor, and a payout signal for turning on the interface element from another control unit via a wiring connector Having a control unit,
The payout control unit is a gaming machine that drives the payout motor to pay out valuables to a player in response to an ON operation of the interface element,
A first means for starting power feeding of the first power source and / or the second power source in response to a level change of the payout signal for turning on the interface element;
A gaming machine comprising: second means for stopping power supply of the first power source and / or the second power source in response to the return of the level of the payout signal. The payout signal is output from a signal output circuit that receives a drive signal having a pulse width corresponding to the payout number of valuables and performs a switching operation,
The gaming machine according to claim 1, wherein the signal output circuit is disposed in the other control unit.   The gaming machine according to claim 1, wherein a power supply control circuit that realizes the first means and the second means is arranged in the other control unit.   The gaming machine according to claim 1, wherein the power supply control circuit includes a first switch circuit disposed on a power supply line of the first power supply.   The gaming machine according to any one of claims 1 to 4, wherein the power supply control circuit includes a second switch circuit disposed on a power supply line of the second power supply.   5. The gaming machine according to claim 4, wherein the first switch circuit operates by receiving a control signal having the same logic level as the drive signal and a pulse width wider than that of the drive signal.   The first switch circuit includes a NOT circuit that receives the control signal and performs a logic inversion operation, and a unipolar transistor that receives an output of the NOT circuit at a control input terminal. The gaming machine described.   5. The gaming machine according to claim 4, wherein the second switch circuit operates by receiving a control signal having the same logic level as the drive signal and a pulse width wider than that of the drive signal. The second switch circuit includes a first transistor that is turned on in response to the control signal, and a second transistor that is turned on in response to the ON operation of the first transistor,
The gaming machine according to claim 8, wherein the second power source is supplied to the payout control unit in response to an ON operation of the second transistor.   The gaming machine according to claim 9, wherein the second transistor is a unipolar transistor.

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