JP5788576B2 - Magnetic detection system for gaming machines - Google Patents

Description

  The present invention relates to a magnetic detection system for a gaming machine for detecting an illegal act caused by a magnet (magnetic force) in a gaming machine such as a pachinko machine.

In conventional pachinko machines, a magnetic sensor is embedded in the vicinity of the winning hole of the game board in order to detect fraud using a magnet (magnetic force), and when abnormal magnetism is detected during a game, The detection signal is output to a hall computer.
However, in such a configuration, if the magnetic detection function is lost due to accidental or intentional disconnection between the magnetic sensor and the magnetic detection circuit, fraud using a magnet Has the disadvantage that it cannot be detected.

Therefore, for example, the following Patent Document 1 proposes an unauthorized time detection sensor that can detect not only a fraudulent act by a magnet but also a loss of a magnetic detection function due to a disconnection between the magnetic sensor and the magnetic detection circuit unit. .
This conventional apparatus has a magnetic sensor, a magnetic detection circuit unit, a connection confirmation circuit unit for detecting the connection state, and an alarm (indicator lamp). When the sensor is normal, that is, when the magnetic sensor and the magnetic detection circuit unit are connected, the indicator lamp is always lit, but when the connection is broken, the indicator lamp is turned off to turn off the magnetic sensor and the magnetic detection circuit. It is detected that the connection with the unit has been disconnected.

JP 2005-137877 A

However, in the conventional device as described above, when magnetism is detected by a plurality of magnetic sensors, a connector (connection portion) corresponding to the number of magnetic sensors is provided on a substrate (main control substrate) provided with the magnetic detection circuit portion. This is a factor that hinders the commonality of the substrate.
Furthermore, when magnetism is detected by a plurality of magnetic sensors as described above, a large number of circuit elements such as comparators (comparators) must be used for each magnetic sensor as shown in FIG. There is a problem that it becomes complicated and increases the cost and it is difficult to reduce the size and power consumption.

  FIG. 10 is a circuit configuration diagram illustrating an example of a magnetic detection circuit unit in the case where magnetism is detected by a plurality of magnetic sensors. In the figure, reference numerals C1 to C4 denote connectors provided on the main control board or the like, and detachably connect magnetic sensors made of general-purpose mechanical or magnetoresistive elements, not shown. Each of the connectors C1 to C4 is provided with a pair of magnetic detection comparators and a pair of disconnection detection comparators (a total of eight), not only when one of the magnetic sensors detects a magnetic force. When any one of the magnetic sensors is disconnected, the disconnection signal is output to the main control board (connection confirmation circuit portion thereof).

Therefore, as can be seen from this figure, the conventional devices have magnetic sensors that can be connected in advance, so in order to provide more magnetic sensors, prepare processing circuits such as connectors and comparators corresponding to the number of magnetic sensors. There is an inconvenience of having to.
Therefore, the present invention has been devised to solve such problems, and the main purpose of the present invention is to provide a magnetic machine for a novel game machine that can flexibly cope with the increase / decrease of the magnetic sensor and simplify the processing circuit. A detection system is provided.

In order to solve the above problems, the first invention
A game board provided with a winning opening through which a predetermined game ball is paid out when a game ball enters, a magnetic detection unit having a magnetic sensor module at a plurality of predetermined positions of the game board, and an output supply from the magnetic detection unit A disconnection / magnetism determination unit that determines whether there is a disconnection or magnetism of any of the magnetic sensor modules depending on the power source, and the magnetic detection unit is connected to the disconnection / magnetism determination unit when no disconnection or magnetism is detected. When a disconnection or magnetism is detected by supplying power, the disconnection / magnetism determination unit is not supplied with power, and the disconnection / magnetism determination unit is supplied with power from the magnetism detection unit. Is determined that no disconnection or magnetism is detected, and when the power supply from the magnetism detection unit is not supplied, the disconnection or magnetism is detected. A game machine magnetic detection system, characterized in that to determine that.

The second invention is
In the first invention, the magnetic sensor module is provided in the vicinity of a predetermined winning opening, and is a magnetic detection system for a gaming machine.

  According to the first aspect of the invention, since the magnetic detection unit supplies power output when no disconnection or magnetism is detected, and when the disconnection or magnetism is detected, power supply output is stopped. Can detect the disconnection of any one of the magnetic sensor modules as well as the magnetism only by detecting the presence / absence of power supply from the magnetic detection unit. In addition, a processing circuit for determining the presence of disconnection or magnetism can be simplified.

1 is an external perspective view showing an example of a pachinko gaming machine 100 according to the present invention. 2 is a front view showing an example of a game board 18. FIG. It is a block diagram which shows the internal control structure of the pachinko gaming machine 100 according to the present invention. It is a block diagram which shows 1st Embodiment of the magnetic detection part 900 which comprises the magnetic detection system which concerns on this invention. It is a circuit block diagram of the magnetic sensor module M which comprises the magnetic detection part 900 which concerns on the 1st Embodiment of this invention. It is another example of the circuit block diagram of the magnetic sensor module M which comprises the magnetic detection part 900 which concerns on the 1st Embodiment of this invention. It is a block diagram which shows 2nd Embodiment of the magnetic detection part 900 which comprises the magnetic detection system which concerns on this invention. It is a circuit block diagram of the magnetic sensor module M which comprises the magnetic detection part 900 which concerns on the 2nd Embodiment of this invention. It is a block diagram which shows the modification of 2nd Embodiment of the magnetic detection part 900 which comprises the magnetic detection system which concerns on this invention. It is a circuit block diagram which shows an example of the conventional magnetic detection apparatus.

Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the accompanying drawings.
(Basic configuration)
FIG. 1 is an external perspective view showing an embodiment of a gaming machine 100 according to the present invention.
As shown in the figure, this gaming machine 100 is a so-called “digi-pachi” pachinko machine, and can be freely opened and closed at the front upper part of an outer frame 10 having a vertically long rectangular shape and an inner frame 14 hinged by a hinge mechanism 12. A game board 18 covered with a transparent glass frame unit 16 is provided.

  A game area 22 is formed between the game board 18 and the glass frame unit 16 as a circular space defined by the guide rails 20 as shown in FIG. Then, a game ball driven into the upper portion of the game area 22 from the launch device (shooting handle) 24 via the guide rail 20 falls in the game area 22 by its own weight and is provided at the bottom of the game board 18. 26 is discharged out of the game area 22 (behind the game board 18), and a part of other game balls is awarded to various winning ports formed in the game board 18. When game balls win the various winning holes, the number of winning balls (1 to 15) according to the number of winning balls is successively paid out to the tray unit 28 provided at the lower part of the game area 22.

Further, as shown in FIG. 2, a large effect symbol display 30 comprising a liquid crystal display (LCD panel) is provided at the center of the game board 18, and a game is given to the winning device 32 provided at the lower part thereof. A predetermined effect design corresponding to a lottery (special prize) lottery result performed when the ball wins is appropriately displayed in a variable manner depending on a predetermined display mode.
The winning device 32 includes a fixed first start winning port 32a and a movable second start winning port 32b positioned below the first start winning port 32a.

That is, the winning device 32 is provided with a first start winning port 32a at the center upper portion of a fixed plate 35 fixed on the game board 18 with screws or the like, and a second start winning port 32b immediately below it. A part of the game ball falling in the vicinity thereof is guided by a nail or an accessory (not shown) or the like driven in the vicinity thereof, so that each player can appropriately win a prize.
The first start winning opening 32a is a game ball entrance that is always open upward, which is called a so-called navel as shown in the figure, and is adjusted in advance by appropriately adjusting the interval and angle between the nails located immediately above the entrance. The probability of winning (entering a ball) can be adjusted.

  On the other hand, the second start winning opening 32b is composed of an electric accessory (movable member) 36, which is called a so-called electric chew (electric tulip) or the like, and has a variable winning probability, and is provided in the vicinity of the guide rail 20. An opening / closing operation is performed in accordance with a normal symbol lottery result performed when the game ball passes through the normal symbol start gate 34 to control the winning probability of the game ball to the second start winning port 32b (winning device 32). When the second start winning opening 32b is in an inoperative state, the electric accessory (movable member) is stopped (closed), and a game ball wins the second starting winning opening 32b. I can't do it.

In addition, a large winning opening 40 is formed at the lower portion of the winning device 32 and is closed by a rectangular plate-shaped opening / closing lid 38. Then, when winning the winning game lottery in the winning device 32, the open / close lid 38 is repeatedly opened and closed a predetermined number of times to repeat the opening / closing operation within the game area 22. Capture falling game balls and win.
Also, a special symbol display 42 is provided in the vicinity of the grand prize winning opening 40, and a jackpot lottery result that is triggered by the winning of a game ball to the winning device 32 is displayed as a 7-segment LED or the like. Is displayed using numerical values or alphabets.

Further, a normal symbol display 44 and a winning hold lamp 46 are provided in the vicinity of the effect symbol display 30. The normal symbol display 44 displays the lottery result of the normal symbol performed when the game ball passes through the normal symbol start gate 34 by using a display such as a 7-segment LED. The winning hold lamp 46 displays the number of game balls to be held in the winning device 32 by, for example, blinking of a plurality of LEDs, and normally displays the number of winning balls to be held (up to 8).
In FIG. 2, reference numeral 48 denotes various winning holes through which a part of the game ball can be won, and 50 and 50 denote attachment parts for detaching the game board 18 from the inner frame 14 side. Although not shown, a large number of nails for controlling the flow of game balls falling on the game board 18 are driven on the game board 18.

On the other hand, as shown in FIG. 1, display lamps (display lamps) 52, 52 of various colors, such as light bulbs and LEDs, are provided around the glass frame unit 16 covering the game board 18. These indicator lamps (indicator lamps) 52 and 52 are lit or blinked in linkage with the effects during the game or the state of the device (for example, the device error or the open / closed state of the glass frame unit 16 or the like).
Furthermore, full-range speaker units 54 and 54 and a subwoofer unit 56 are provided at the upper left and right corners of the glass frame unit 16 and the lower center of the tray unit 28, respectively. In addition, it produces sound effects such as sound effects during demonstrations described later with powerful deep bass and high sound quality.

  Further, a game ball supplied from a ball lending device (not shown) or awarded prize ball is temporarily held in the tray unit 28 below the game board 18 and the game balls are sequentially supplied to the launching device 24. . In FIG. 1, reference numeral 58 denotes an operation button (ball lending button and card return button) for supplying a game ball from a ball rental device (not shown), and 60 is a push operation (push) by the player during the game. This is a push button that can participate in sound effects and effects displayed on the effect symbol display 30.

Next, the configuration of the control system of the gaming machine 100 of the present invention having such a configuration will be described.
FIG. 3 is a block diagram showing the configuration of the control system of the gaming machine 100 of the present invention.
As shown in the figure, the control system of the gaming machine 100 is mainly composed of two control units such as a main control unit 200 and a composite sub-control unit 300.
The main control unit 200 controls the entire game, and the composite sub-control unit 300 according to a random number generated internally based on the detection of the winning of game balls at the start winning ports 32a and 32b of the winning device 32 described above. Send a control command to In addition, the composite sub-control unit 300 controls the production symbol display unit 400 and productions such as sound effects in combination in accordance with the control command transmitted from the main control unit 200.

The main control unit 200 mainly includes a CPU 210, a ROM 220, a RAM 230, a timer 240, an input port 250 and an output port 260, and various game control programs and various control data stored in the ROM 220.
The input port 250 has a start winning port switch 251 for detecting the winning of the game ball to each of the starting winning ports 32a and 32b of the winning device 32 and the big winning for detecting the winning of the game ball to the big winning port 40. The mouth switch 252 and various winning port switches 253 for detecting the winning of game balls to the various winning ports 48 are connected, and the main control unit 200 inputs detection signals from these switches and processes them. .

  The input port 250 is connected to a magnetic detection unit 900 that constitutes a magnetic detection system according to the present invention, and inputs a magnetic detection signal, which will be described in detail later, to the main control unit 210. The input port 250 is a connector connection system, and various winning port switches 251, 252, and 253 and the magnetic detection unit 900 are connected to a connector (not shown) provided in advance on a board constituting the main control unit 200. Each connection terminal is detachably connected.

On the other hand, in addition to this composite sub-control unit 300, the output port 260 includes the special symbol display 42, the normal symbol display 44, the prize ball payout control device 500, the big prize opening solenoid 600, and the hall computer. 700 and the like are connected, and the main control unit 200 directly controls them according to a predetermined control program.
In addition to the program for controlling the pachinko machine executed by the CPU 210 as described above, the ROM 220 can read various control data such as various control commands for controlling the composite sub-control unit 300 and the like. Remembered / retained. In particular, the present embodiment also includes a control program for determining the detection of magnetism and the presence or absence of disconnection of the magnetic detection unit 900 based on the presence or absence of an input signal from the magnetic detection unit 900.

The RAM 230 temporarily stores input / output data for the main control unit 200, data for arithmetic processing, various counters including a random number counter related to games, and a holding memory for storing information of each holding ball. Have.
The main control unit 200 controls the composite sub-control unit 300 by mainly transmitting a production control command to the composite sub-control unit 300.

The main control unit 200 is connected to a power supply circuit 800 for supplying power. When the power supply circuit 800 detects that the voltage of the power supply line supplied to the entire main control unit 200 has become equal to or lower than a predetermined voltage value, the power supply circuit 800 generates a power-off detection signal indicating that the power supply has been cut off. Output to. Then, when the power cut is detected, the power line supplied to the entire main controller 200 is switched to the power line directly connected to the CPU 210 when the power is cut. Thereby, since power is supplied to the RAM 230 from the power supply line directly connected to the CPU 210, information can be retained even if a power failure occurs.
Similar to the main control unit 200, the composite sub-control unit 300 includes a CPU, a ROM, a RAM, an input port, and an output port (not shown), and provides control commands for effect control transmitted from the main control unit 200. In response to this, the control command for effect display is generated according to the control command, and the generated control command is transmitted to the effect symbol control unit 400 to control the effect symbol display 30.

  In addition, the composite sub-control unit 300 lights up the audio control unit 320 that has at least two channels and performs audio control for outputting the synthesized sound of each channel from the speakers 54 and 56, and the illumination lamp 52. And a lamp control unit 310 that performs lamp control, and controls a predetermined sound effect and electrical decoration in combination with a display pattern of the effect symbol displayed on the effect symbol display 30.

(First embodiment)
4 to 6 show a first embodiment of a magnetic detection system applied to such a gaming machine 100. FIG.
(Constitution)
As shown in the figure, this magnetic detection system determines the presence or absence of disconnection or magnetism based on the magnetic detection unit 900 having a plurality of magnetic sensor modules M (M1, M2,... MN) and the voltage output from the magnetic detection unit 900. This is mainly composed of a disconnection / magnetic determination unit 950.
First, the magnetic detection unit 900 is formed by connecting at least two or more magnetic sensor modules M1, M2,... MN in a multistage connection (cascade connection). It is detachably connected to the disconnection / magnetic determination unit 950 on the main control board 200 side via the input port 250).

FIG. 5 shows the circuit configuration of each of the magnetic sensor modules M1, M2,... MN, and the circuit configurations are the same.
The magnetic sensor module M mainly includes a magnetic sensor 910, a first transistor TR1, a second transistor TR2, and a constant voltage circuit 920.
The magnetic sensor 910 is composed of, for example, a magnetoresistive element, and outputs a predetermined voltage (for example, 5 V) when it does not detect magnetism above a predetermined value, and does not output a voltage when magnetism above a predetermined value is detected. (0V). Specifically, a constant voltage output type high-accuracy magnetic sensor employed in the HGDFPA series manufactured by Alps Electric Co., Ltd. can be used.

The first transistor TR1 is composed of an NPN transistor whose base is connected to the output terminal of the magnetic sensor 910. When a predetermined voltage is output from the magnetic sensor 910 to the base, the first transistor TR1 is turned on and the collector Current flows from the emitter to the emitter side (GND), and when the output voltage from the magnetic sensor 910 stops, it is turned off to stop the current flow.
The second transistor TR2 is composed of a PNP transistor whose base is connected to the collector side of the first transistor TR1, whose emitter is connected to the voltage source (≈VDD), and whose collector is open (VOUT). When the first transistor TR1 is turned on, it is turned on to supply an approximately power supply voltage (≈VDD) to the VOUT side, and when the first transistor TR1 is turned off, it is turned off and the substantially power supply voltage (≈ (VDD) output supply is cut off. Here, the substantially power supply voltage (≈VDD) is a value obtained by subtracting the voltage between the emitter and the collector of the second transistor TR2 from VDD, and is generally about VDD-0.2V.

  The constant voltage circuit 920 is a known circuit including a Zener diode ZD1, a resistor R1, a transistor TR3, a capacitor, and the like. For example, when the power supply voltage (VDD) is 12V, the constant voltage circuit 920 is transformed to 5V at which the magnetic sensor 910 operates. Output to the magnetic sensor 910. The constant voltage circuit 920 may have a simple configuration including a Zener diode ZD1 and a resistor R1 as shown in FIG. A general three-terminal regulator may be used.

On the other hand, the disconnection / magnetism determination unit 950 includes a photocoupler PC including a light emitting diode LED (light emitting element) and a phototransistor TR4 (light receiving element) provided on the main control board 200 side via the connector C, and a main control board. The CPU 210 is configured by the CPU 210 and the like, and the CPU 210 determines whether the magnetic detection unit 900 is disconnected and whether there is magnetism by turning on and off the output signal from the photocoupler PC.
Here, the specific installation location of each of the magnetic sensor modules M1, M2,... MN with respect to the gaming machine 100 is not particularly limited, but for example, a prize provided at the center of the gaming board 18 as described above. The device 32 is installed in the vicinity of the first start winning port 32a and the second start winning port 32b, in the vicinity of the various winning ports 48 and the big winning port 40, respectively. Of these magnetic sensor modules M1, M2,... MN, a short protection resistor may be inserted into the power supply of the first stage magnetic sensor module M1.

(Operation)
Next, the operation of the magnetic detection system according to the present invention having such a configuration will be described.
First, in a normal state, that is, in a state where a disconnection of a plurality of magnetic sensor modules M constituting the magnetic detection unit 900 and a magnetism exceeding a predetermined value are not detected, the power supply voltage (VDD) supplied from the first stage side of the magnetic detection unit 900 Are output and supplied sequentially from the output terminal (VOUT) of the magnetic sensor module M to the power supply of the magnetic sensor module M at the next stage. The power supplied from the final stage magnetic sensor module MN is output to the photocoupler PC via the connector C to cause the light emitting diode LED to emit light.
As a result, since the received signal from the photocoupler PC is always output to the CPU 210, the disconnection / magnetism determination unit 950 on the main control board 200 side has a plurality of magnetic sensor modules M1, M2, ... MN is determined to be in a normal state in which disconnection and magnetism above a predetermined value are not detected.

  On the other hand, when an abnormality is detected, that is, when any one of the plurality of magnetic sensor modules M1, M2,... No power is supplied from the output terminal (VOUT), and the light emitting diode LED of the photocoupler PC is turned off. For example, when a player or the like brings a magnet or the like near the winning opening of the game board 18 for an illegal purpose during the game, the magnetic sensor 910 detects this and stops the voltage output to the first transistor TR1. Therefore, no power is supplied from VOUT. Further, even when any one of the magnetic sensor modules M is accidentally or intentionally disconnected, the power supply is not supplied to the lower magnetic sensor module M.

As a result, the on-state input signal from the photocoupler PC to the CPU 210 is interrupted, so that the disconnection / magnetism determination unit 950 on the main control board 200 side has a plurality of magnetic sensor modules M1, M2,. It is determined that an abnormal state is detected in which one of the above is disconnected or magnetism of a predetermined value or more is detected.
When the disconnection / magnetism determination unit 950 determines that such an abnormal state is present, the disconnection / magnetic determination unit 950 outputs a signal to that effect to the hall computer 700 or the like via the output port 260 or generates an alarm sound. Or appropriate processing such as interrupting the game.

  As described above, in the magnetic detection system of the present invention, the magnetic detection unit 900 outputs and supplies a voltage of VDD−0.2 × N during normal time (normal time), and the voltage is detected when disconnection occurs or magnetism is detected. Therefore, the disconnection / magnetism determination unit 950 can detect the disconnection of any one of the magnetic sensor modules M as well as the magnetism only by detecting the presence / absence of voltage output from the magnetism detection unit. Further, the processing circuit for determining the presence / absence of disconnection and magnetism can be simplified.

Further, according to the present embodiment, the magnetic detection unit 900 is formed by connecting a plurality of magnetic sensor modules M in series and connecting the final stage magnetic sensor module MN to the disconnection / magnetic determination unit 950. Regardless of the number of the magnetic sensor modules M, in principle, only one connecting portion (connector C) between the magnetic sensor modules M and the disconnection / magnetic determining portion 950 is required. As a result, it is not necessary to prepare connectors C for each number of magnetic sensor modules M, so that costs can be reduced and substrates can be shared. In addition, it is possible to accurately cope with increase / decrease of the magnetic sensor 910.
In this embodiment, when multistage connection is performed (for example, N stages), the voltage supplied to the output of the final stage is VDD-VCE (TR2) × N, and a voltage drop of VCE of TR2 for N stages occurs. As long as this is a range in which the constant voltage unit 90 and the disconnection / magnetic detection unit 900 are normally operated, multistage connection is possible within the range.

(Second Embodiment)
Next, FIG. 7 and FIG. 8 show a second embodiment of the magnetic detection system according to the present invention.
(Constitution)
This embodiment is different from the configuration of the first embodiment as the magnetic detection unit 900 described above, and as shown in FIG. 7, a plurality of open collector type magnetic sensor modules M1, M2,. And a transistor TR5 that is turned on when one of the magnetic sensor modules M1, M2,..., MN is turned off and stops outputting the power supply voltage to the disconnection / magnetism determining unit 950. .

FIG. 8 shows the circuit configuration of these open collector type magnetic sensor modules M.
As in the first embodiment, the magnetic sensor module M mainly includes a constant power output type magnetic sensor 910 made up of a magnetoresistive effect element, a transistor TR6, and a constant voltage circuit 920.
The transistor TR6 is composed of an NPN transistor whose base is connected to the output terminal of the magnetic sensor 910. When a predetermined voltage is output from the magnetic sensor 910 to the base, the transistor TR6 is turned on and is connected to the emitter side (GND). And when the output voltage from the magnetic sensor 910 stops, it is turned off to stop the current flow.

The collector of the transistor TR6 is open (VOUT) and is connected to the power supply voltage (VDD) side via the resistor R1 as shown in FIG.
Further, an abnormality monitoring LED and a backflow prevention diode D are connected to the collector side of the transistor TR6, and the end of the diode D is joined together with another diode D to form a diode OR circuit. Are connected to the base of the transistor TR5.
The transistor TR5 is connected between VDD and GND so that its collector and emitter bypass the connector C, respectively.

(Operation)
Next, the operation of the magnetic detection unit 900 having such a configuration will be described.
First, in a normal state, that is, in a state where a plurality of magnetic sensor modules M1, M2,... MN constituting the magnetic detection unit 900 are not disconnected and magnetism exceeding a predetermined value is not detected, each magnetic sensor module M1, M2, ... because the transistor TR6 of MN is turned on by the output voltage from the magnetic sensor 910, the current that has passed through the resistor R flows from the collector to the emitter side. As a result, since the voltage on the LED or diode D side for abnormality monitoring becomes 0 V, no voltage is input to the base of the transistor TR5, and the transistor TR5 is turned off. Accordingly, the power supply voltage (VDD) is output as it is to the photocoupler PC via the connector C to cause the light emitting diode LED to emit light.

As a result, since the received signal is always output to the CPU 210 from the photocoupler PC, the disconnection / magnetism determination unit 950 on the main control board 200 side detects the disconnection of the plurality of magnetic sensor modules M in the magnetic detection unit 900. It is determined that a normal state is detected in which magnetism of a predetermined value or more is not detected.
On the other hand, when an abnormality is detected, that is, when any one of the plurality of magnetic sensor modules M1, M2,..., MN constituting the magnetic detection unit 900 is disconnected or a magnetism exceeding a predetermined value is detected, magnetism is applied to the transistor TR6. Since the output voltage from the sensor 910 disappears and it is turned off, the current that has passed through the resistor R flows to the LED or diode D side for abnormality monitoring. Then, a voltage is applied to the base of the transistor TR5 to turn it on, and the power supply voltage (VDD) on the connector C side bypasses the connector C and flows to the transistor TR5 side.

As a result, the light emitting diode LED of the photocoupler PC is turned off, and the input signal from the photocoupler PC to the CPU 210 is interrupted. Therefore, the disconnection / magnetism determination unit 950 on the main control board 200 side uses a plurality of magnets in the magnetic detection unit 900. It is determined that any of the sensor modules M is in an abnormal state in which disconnection or magnetism of a predetermined value or more is detected.
When the disconnection / magnetism determination unit 950 determines that such an abnormal state is present, a signal to that effect is sent to the hall computer 700 or the like via the output port 260 as in the first embodiment. Perform reasonable processing such as output.

  Thus, also in the present embodiment, as in the first embodiment, the magnetic detection unit 900 outputs a voltage when any of the magnetic sensor modules M does not detect disconnection or magnetism (ON operation). ) Since no voltage is output when disconnection or magnetism is detected (off operation), the disconnection / magnetism determination unit 950 detects only the presence or absence of voltage output from the magnetic detection unit. The disconnection of the magnetic sensor module M can also be reliably detected. Further, the processing circuit for determining the presence / absence of disconnection and magnetism can be simplified.

In addition, since the magnetic detection unit 900 is formed by connecting a plurality of magnetic sensor modules M in parallel, in principle, there is one connection portion (connector C) between the magnetic sensor module M and the disconnection / magnetic determination unit 950. It will be over. As a result, it is not necessary to prepare a connector for each number of magnetic sensor modules M, so that costs can be reduced and substrates can be shared. In addition, it is possible to accurately cope with increase / decrease of the magnetic sensor 910.
Further, in this embodiment, since the magnetic sensor modules M1, M2,..., MN are connected in parallel, a voltage drop as in the case of connecting them in series is hardly observed. It is possible to provide more magnetic sensor modules M1, M2,.

In the present embodiment, the light emitting diode LED on the collector side of each magnetic sensor module M1, M2,..., MN can be omitted. However, if such a light emitting diode LED is provided, this is usually the case. Since it is turned off and light is emitted when disconnection or magnetism is detected, it is possible to grasp at a glance which magnetic sensor module M has an abnormality simply by viewing the light emission state.
Further, since a general-purpose (commercially available) open collector type magnetic sensor can be used as the magnetic sensor module M, the manufacturing cost of the entire system can be kept low.

In this embodiment, a diode D is provided for each magnetic sensor module M1, M2,..., MN and one transistor TR5 is provided. However, a plurality of transistors TR5 may be provided. In this case, a plurality of collector sides may be directly OR-connected at the same position as the collector of the conventional transistor TR5. This facilitates the design of circuit constants when the number of magnetic sensor modules M increases.
Furthermore, as shown in FIG. 9, a transistor may be arranged for each magnetic sensor module M1, M2,. Thus, by arranging one transistor as a pair in one magnetic sensor module M, a diode becomes unnecessary, and a transistor OR (the logic viewed from the transistor is a NOR) circuit instead of a diode OR.
In this way, as shown in FIG. 9, a transistor array (TR array) IC in which a plurality of transistors are combined into one package can be used, the circuit configuration is clear, and the number of components can be reduced.

DESCRIPTION OF SYMBOLS 100 ... Game machine 900 ... Magnetic detection part 910 ... Magnetic sensor 920 ... Constant voltage circuit 950 ... Disconnection and magnetism determination part TR1 ... 1st transistor (NPN)
TR2 ... Second transistor (PNP)
TR3 ... Transistor TR4 ... Phototransistor TR5, TR6 ... Transistor PC ... Photocoupler LED ... Light emitting diode ZD1 ... Zener diode C ... Connector D ... Diode

Claims (2)

A game board provided with a winning opening through which a predetermined game ball is paid out by entering a game ball;
A magnetic detection unit having a magnetic sensor module at a plurality of predetermined locations of the game board;
A disconnection / magnetism determination unit for determining the presence or absence of magnetism or disconnection of any one of the magnetic sensor modules by the power supplied from the magnetic detection unit;
The magnetic detection unit outputs power to the disconnection / magnetism determination unit when no disconnection or magnetism is detected, and does not supply power to the disconnection / magnetism determination unit when disconnection or magnetism is detected. And
The disconnection / magnetism determination unit determines that disconnection or magnetism is not detected when power is supplied from the magnetism detection unit, and disconnects when power is not supplied from the magnetism detection unit. Alternatively, a magnetic detection system for a gaming machine, wherein it is determined that magnetism is detected. In the gaming machine magnetic detection system according to claim 1,
A magnetic detection system for a gaming machine, wherein the magnetic sensor module is provided in the vicinity of a predetermined winning opening.

Images