JP2012245024A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine capable of preventing fraudulence in an radio-wave hopper.SOLUTION: A hopper device 60 includes: a tank 61 in which a plurality of tokens can be stored; a discharge device 63 for discharging the tokens inside the tank 61 from an outlet 64; and two discharge sensors for detecting discharged tokens from the outlet 64. The voltage level of a signal of a first discharge sensor 81 is low and the voltage level of a signal of a second discharge sensor 82 is high while the operation of the discharge device 63 is stopped. The voltage level of the signal of the first discharge sensor 81 becomes high and the voltage level of the signal of the second discharge sensor 82 becomes low whenever one token is discharged from the outlet 64 according to the operation of the discharge device 63. If a state in which the voltage levels of signals of both the first discharge sensor 81 and the second discharge sensor 82 are high continues for a prescribed period of time, it is determined that an abnormality occurs in the hopper device 60.

Description

  The present invention relates to a gaming machine including a hopper device for paying out medals.

2. Description of the Related Art Conventionally, a hopper device that pays out medals is installed in a gaming machine such as a slot machine that uses medals as game media. This hopper device is provided with a tank capable of storing a plurality of medals and a discharge device for discharging medals in the tank.
The discharge device includes a disk rotor that sends out the medal in the tank to the discharge port, a count arm that swings as the medal moves to the discharge port, and a discharge sensor that detects the swing of the count arm. . When the count arm swings and is detected by the discharge sensor, the voltage level of the signal output from the discharge sensor switches from high to low, and when the count arm returns to the normal state, the voltage level of the signal from the discharge sensor also decreases. Return to high. As a result, it was determined that one medal was paid out.

However, an illegal act of paying out a large number of medals may be performed by intruding an illegal instrument into the discharge device to prevent the counting arm from swinging and making it impossible to count the number of medals paid out. It was.
Therefore, a technique for preventing the above-mentioned fraudulent activity by making it difficult for the unauthorized device to reach the count arm has been disclosed (see Patent Documents 1 and 2).

JP 2001-276317 A JP 2009-233303 A

However, when a strong electromagnetic wave is irradiated to the discharge device, the voltage level of the signal output from the discharge sensor is forced to rise from low to high. And, while fixing the voltage level of the signal output by the discharge sensor to high and disabling counting of the number of medals to be paid out, the fraudulent act (hereinafter referred to as “Radio Hopper Goto”) ) Was sometimes performed.
However, in the conventional popper device, it was possible to prevent an illegal act of inserting a fraudulent instrument and hindering the swing of the count arm, but it was not possible to prevent a radio wave hopper goto that erroneously detected the discharge sensor by electromagnetic waves.

  Then, this invention makes it a subject to provide the game machine which can prevent a radio wave hopper goto.

(1) 1st invention In order to solve the said subject, 1st invention among this invention,
A gaming machine equipped with a hopper device (60) for paying out medals,
The hopper device (60)
A tank (61) capable of storing a plurality of medals,
A discharge device (63) for discharging the medal in the tank (61) from the discharge port (64);
Two discharge sensors for detecting the discharge of medals from the discharge port (64),
When the operation of the discharge device (63) is stopped, the voltage level of the signal output from one of the two discharge sensors (hereinafter referred to as “first discharge sensor (81)”) is low, and the other ( Hereinafter, the voltage level of the signal output from the “second discharge sensor (82)” is high,
The voltage level of the signal output from the first discharge sensor (81) becomes high each time one medal is discharged from the discharge port (64) by the operation of the discharge device (63). It is formed so that the voltage level of the signal output from the second discharge sensor (82) is low,
An abnormality occurs in the hopper device (60) when the voltage levels of the signals output from the first discharge sensor (81) and the second discharge sensor (82) are both high for a predetermined time. It is characterized by judging that it was done.

(2) Second invention In order to solve the above-mentioned problems, the second invention of the present invention is characterized in that in addition to the features of the first invention,
The discharge device (63) includes a count arm (75) that swings between a first position and a second position,
The first discharge sensor (81) detects that the count arm (75) is located at the first position,
The second discharge sensor (82) detects that the count arm (75) is located at the second position,
The count arm (75) is located at the first position when the operation of the discharge device (63) is stopped, and one medal is discharged from the discharge port (64) by the operation of the discharge device (63). It is characterized by reciprocating from the first position to the second position every time.

(3) Third invention In order to solve the above-mentioned problem, the third invention of the present invention is characterized in addition to the features of the second invention,
A discharge sensor monitoring timer (140) for starting timing when the voltage level of the signal output from the first discharge sensor (81) rises from low to high;
After the discharge sensor monitoring timer (140) starts timing, the discharge sensor monitoring timer (140) counts while the voltage level of the signal output from the second discharge sensor (82) remains high. When the time reaches a predetermined time, it is determined that an abnormality has occurred in the hopper device (60),
The discharge sensor monitoring timer (140) resets the time and starts counting again when the voltage level of the signal output from the second discharge sensor (82) falls from high to low. ,
After the discharge sensor monitoring timer (140) resets the time and starts counting again, the discharge sensor is maintained while the voltage level of the signal output from the first discharge sensor (81) remains high. When the time measured by the monitoring timer (140) reaches a predetermined time, it is determined that an abnormality has occurred in the hopper device (60).

(First or second invention)
According to the first or second invention of the present invention, the following effects are combined.
That is, when the voltage levels of the signals of the first discharge sensor and the second discharge sensor are both high for a predetermined time, it is determined that an abnormality has occurred in the hopper device.
Therefore, when the discharge device is irradiated with strong electromagnetic waves and the signals of the first discharge sensor and the second discharge sensor are forcibly fixed at a high level, this can be detected as an abnormality of the hopper device, and the discharge By stopping the operation of the device or notifying the occurrence of an abnormality, it is possible to prevent radio wave hopper goto.

(Third invention)
According to the third aspect of the present invention, in addition to the effects of the first or second aspect, the following effects can be obtained.
That is, the discharge sensor monitoring timer starts timing when the voltage level of the signal of the first discharge sensor rises from low to high. When the time measured by the discharge sensor monitoring timer reaches a predetermined time while the voltage level of the signal of the second discharge sensor remains high, it is determined that an abnormality has occurred in the hopper device.
In addition, when the voltage level of the signal of the second discharge sensor falls from high to low, the time measurement of the discharge sensor monitoring timer is reset and time measurement is started again. When the time measured by the discharge sensor monitoring timer reaches a predetermined time while the voltage level of the signal of the first discharge sensor remains high, it is determined that an abnormality has occurred in the hopper device.

  Therefore, when the discharge device is irradiated with strong electromagnetic waves and the signals of the first discharge sensor and the second discharge sensor are forcibly fixed at a high level, this can be detected as an abnormality of the hopper device, and the discharge By stopping the operation of the device or notifying the occurrence of an abnormality, it is possible to prevent radio wave hopper goto.

It is a front view showing the slot machine according to the present embodiment. It is a front view which shows the state which opened the front door in the slot machine which concerns on this Embodiment. It is a perspective view which shows the hopper apparatus which concerns on this Embodiment. It is a disassembled perspective view which shows the hopper apparatus which concerns on this Embodiment. It is a top view which fractures | ruptures and shows the discharge apparatus which concerns on this Embodiment. It is a top view which shows a mode that a count arm rock | fluctuates in the discharge device which concerns on this Embodiment. It is a top view which shows a mode that a count arm rock | fluctuates in the discharge device which concerns on this Embodiment. It is a top view which shows a mode that a count arm rock | fluctuates in the discharge device which concerns on this Embodiment. 6 is a timing chart showing voltage level transitions of the first discharge sensor and the second discharge sensor in the slot machine according to the present embodiment. It is a block diagram which shows the outline of the control system of the slot machine which concerns on this Embodiment. 10 is a flowchart showing a medal discharge control process in the slot machine according to the present embodiment.

DESCRIPTION OF EMBODIMENTS Embodiments for carrying out the present invention will be described with reference to the drawings.
The “front” refers to a surface in the slot machine S that faces when a player plays a game. “Right side” means the right side when viewed from the player facing the front of the slot machine S, and “left side” means the left side when viewed from the player facing the front of the slot machine S.
(Slot Machine S)
The slot machine S according to the present embodiment is played using medals as game media.

As shown in FIG. 2, the slot machine S includes a box-shaped housing 1 having a front opening 11 that opens to the front side. Further, a front door 3 that closes the front opening 11 of the housing 1 so as to be openable and closable is provided on the front surface of the housing 1.
(Case 1)
As shown in FIG. 2, the housing 1 is formed in a box shape opened to the front side including a bottom plate 15, left and right side plates 16 </ b> B and 16 </ b> A, a top plate 17 and a back plate 18. In addition, an intermediate plate 12 is provided substantially horizontally at a position in the center of the housing 1 in the height direction.
On the upper surface of the bottom plate 15, a power supply unit 4 incorporating a power supply device for supplying power to each component is fixed. On the front of the power supply unit 4, a power switch for switching on / off the power, a setting key switch for switching setting on / off, and a setting change switch for changing setting values A reset switch or the like for canceling the error is provided.

Further, a hopper device 60 for paying out medals is installed on the upper surface of the bottom plate 15. The hopper device 60 includes a tank 61 that can store a plurality of medals, and a delivery device that sends out the medals in the tank 61 one by one.
A main control board unit 24 is provided on the back plate 18. The main control board unit 24 is obtained by storing a main control board 100 including electronic components such as a CPU, ROM, RAM, and I / O in a board case. The main control board 100 controls the progress of the game of the slot machine S, the lottery of the combination, and the like.
The intermediate plate 12 is provided with a reel unit 22. The reel unit 22 includes three rotation reels 23 and three stepping motors that rotate the rotation reels 23. Each rotary reel 23 includes a rotary drum made of synthetic resin and a tape-like reel tape attached around the rotary drum. A plurality of (for example, 21) symbols are displayed on the outer peripheral surface of the reel tape.

(Front door 3)
The front door 3 is a door for closing the front opening 11 of the housing 1 so that it can be opened and closed. The front door 3 is rotatably attached to the left side plate 16B of the housing 1 by a hinge.
As shown in FIG. 1, a symbol display window 31 is provided at a substantially central position of the front door 3 so that the symbols of the rotary reels 23 can be seen from the front side. The symbol display window 31 is formed so that three symbols of each rotary reel 23 can be displayed.
A bet number display section 36 for displaying the bet number is provided at a position on the left side of the symbol display window 31 in the front door 3. Further, a credit number display section 37 for displaying the number of credits is provided at a position below the symbol display window 31 in the front door 3.

An image display device 34 such as a liquid crystal display or a CRT is provided on the upper part of the front door 3. The image display device 34 displays an image of information such as the symbol arrangement and game history of each winning combination, an image for informing the game state and the lottery result of the winning combination, and the like. A lamp 33 is provided around the image display device 34 in the front door 3. The lamp 33 blinks in various blinking patterns, and can increase the game.
A bet switch 51 for reducing the number of credited medals and replacing them with the insertion of medals, a settlement switch 52 for paying out the credited medals, and a game start at a position substantially in the center of the front door 3 in the height direction. A start switch 53, a stop switch 54 for stopping the rotation of the rotary reel 23, and a medal insertion slot 42 for inserting medals one by one are provided.

A medal payout opening 41 for discharging medals from the slot machine S and a tray 43 for storing medals discharged from the medal payout opening 41 are formed at the lower part of the front door 3.
As shown in FIG. 2, a medal selector 6 is provided at a position substantially in the center in the height direction on the back surface of the front door 3 to guide the medals inserted from the medal insertion slot 42 while selecting them in earnest. . Further, on the back surface of the front door 3, a medal discharge portion 44 that opens below the medal selector 6 and communicates with the medal payout port 41 is provided. In addition, two speakers 35 for outputting various sounds are provided at the upper and lower portions of the rear surface of the front door 3, respectively.
A sub-control board unit 25 is provided on the upper rear surface of the front door 3. The sub control board unit 25 is a board case in which a sub control board 200 including electronic components such as a CPU, ROM, RAM, and I / O is stored in a board case. The sub control board 200 controls effects such as sound output of the speaker 35 and lighting of the lamp 33. The main control board 100 and the sub control board 200 are connected by a wire harness (not shown).

(Hopper device 60)
As shown in FIG. 3, the hopper device 60 includes a tank 61 capable of storing a plurality of medals, and a discharge device 63 attached to the lower portion of the tank 61. Further, the hopper device 60 includes a pedestal 62 placed on the bottom plate 15 of the housing 1, and a discharge device 63 is fixed to the upper part of the pedestal 62. The discharge device 63 can discharge medals in the tank 61 one by one from the discharge port 64. The medals sent out from the tank 61 by the discharging device 63 are paid out to the receiving tray 43 through the medal discharging unit 44.
As shown in FIG. 4, the discharge device 63 includes a base 65 in which a disk-shaped recess 66 is formed, a disk-type disk rotor 71 rotatably attached to the recess 66, and a motor 68 that rotationally drives the disk rotor 71. (Refer to FIG. 10).

The disk rotor 71 is located at the bottom of the tank 61. The disk rotor 71 is formed with a plurality of intake holes 72 in the thickness direction for receiving medals in the tank 61 one by one. As shown in FIG. 5, an impeller 73 having the same number of blades 74 as the intake holes 72 is formed at a position on the lower surface side of the disk rotor 71. The medal that has entered the take-in hole 72 of the disk rotor 71 falls into the recess 66 of the base 65 and is pushed toward the discharge port 64 by the blades 74 of the rotating disk rotor 71.
At a position on the lower surface side of the base 65, a count arm 75 that swings whenever a medal is discharged from the discharge port 64 is provided. The count arm 75 is pivotally supported by the base 65 and swings between the first position and the second position. Further, the count arm 75 is biased by a spring (not shown) so that the first position is in a normal state. A columnar contact portion 76 is formed at one end of the count arm 75, and this contact portion 76 is inserted into the through hole 67 of the base 65 and exposed to the upper surface side. Further, at the other end of the count arm 75, a detected piece 77 that is detected by a discharge sensor described later is formed.

Two discharge sensors that detect discharge of medals from the discharge port 64 are provided at a position on the lower surface side of the base 65. In the present embodiment, a light transmission type sensor is used as the discharge sensor.
One of the two discharge sensors (hereinafter referred to as “first discharge sensor 81”) is configured such that when the count arm 75 is located at the first position, the detected piece 77 is the light emitting element and the light receiving element of the first discharge sensor 81. And the light is blocked to detect that the count arm 75 is located at the first position. The other of the two discharge sensors (hereinafter referred to as “second discharge sensor 82”) is configured such that the detected piece 77 is a light emitting element of the second discharge sensor 82 when the count arm 75 is located at the second position. When the light enters the light receiving element and blocks the light, it is detected that the count arm 75 is located at the second position.

When the detected piece 77 of the count arm 75 enters between the light emitting element and the light receiving element and blocks the light, the two discharge sensors output a signal having a low voltage level. When the detected piece 77 comes out between the light emitting element and the light receiving element and the light receiving element captures light, a signal having a high voltage level is output.
Next, how the count arm 75 swings when the disc rotor 71 sends out medals and the transition of the voltage levels of the first discharge sensor 81 and the second discharge sensor 82 will be described with reference to FIGS. To do.
When the disk rotor 71 rotates and the blades 74 push and move the medal M, the medal M comes into contact with the contact portion 76 of the count arm 75 located at the first position (see FIG. 6). At this time, since the detected piece 77 of the count arm 75 enters only between the light emitting element and the light receiving element of the first discharge sensor 81, the voltage level of the signal output from the first discharge sensor 81 is low. Yes, the voltage level of the signal output from the second discharge sensor 82 is high (see FIG. 9A).

When the disk rotor 71 further rotates and the blades 74 push and move the medal M, the count arm 75 is pushed by the medal M and swings toward the second position, and the detected piece 77 is moved to the first discharge sensor 81. The light exits from between the light emitting element and the light receiving element (see FIG. 7). Therefore, the voltage level of the signal output from the first discharge sensor 81 is high, and the voltage level of the signal output from the second discharge sensor 82 is also high (see FIG. 9B).
When the disc rotor 71 further rotates and the blades 74 push the medal M toward the discharge port 64, the count arm 75 reaches the second position (see FIG. 8). At this time, since the detected piece 77 of the count arm 75 enters only between the light emitting element and the light receiving element of the second discharge sensor 82, the voltage level of the signal output from the first discharge sensor 81 is high, The voltage level of the signal output from the second discharge sensor 82 is low (see FIG. 9C).

  When the disc rotor 71 further rotates, the count arm 75 swings toward the first position by the biasing force of the spring, and the detected piece 77 comes out between the light emitting element and the light receiving element of the second discharge sensor 82. . Therefore, the voltage level of the signal output from the first discharge sensor 81 is high, and the voltage level of the signal output from the second discharge sensor 82 is also high (see FIG. 9D). Then, the count arm 75 reaches the first position by the biasing force of the spring, and the detected piece 77 enters only between the light emitting element and the light receiving element of the first discharge sensor 81. Therefore, the voltage level of the signal output from the first discharge sensor 81 is low, and the voltage level of the signal output from the second discharge sensor 82 is high (see FIG. 9E).

(Main control board 100)
As shown in FIG. 10, the main control board 100 includes a bet switch 51, a checkout switch 52, a start switch 53, a stop switch 54, a reel unit 22, a medal selector 6, a hopper device 60, a bet number display section 36, a credit number. Parts such as the display unit 37 are connected.
In addition, the main control board 100 allows the CPU to execute a program stored in the ROM so that the medal discharge control unit 110, the motor drive monitoring timer 120, the discharge error determination unit 130, the discharge sensor monitoring timer 140, the discharge sensor error determination It functions as the means 150 or the like.

In addition, parts such as a lamp 33, an image display device 34, and speakers 35 and 45 are connected to the sub-control board 200.
(Lottery of roles)
The ROM of the main control board 100 stores a plurality of winning determination tables in which each random number generated by the random number generator is assigned to which role is won or lost.
In addition, when a medal is betted by inserting a medal from the medal slot 42 or pressing the bet switch 51, or when a replay is won in the previous game, a random number generator is triggered by the operation of the start switch 53. One numerical value is extracted from the random number generated by. The extracted numerical data is compared with the winning area of the winning combination in the winning determination table selected according to the gaming state or the like, and if the numerical data belongs to any winning area, the role corresponding to the winning area is selected. When winning is determined and the numerical data does not belong to any winning area, “losing” is determined. Further, the main control board 100 is configured to transmit a signal related to the winning lottery result to the sub-control board.

Also, the rotation of the three rotary reels 23 is started almost simultaneously with the lottery of the combination. Thereafter, when any one of the three stop switches 54 is operated, the rotation of the rotary reel 23 corresponding to the stop switch 54 is stopped. Therefore, when all the three stop switches 54 are operated, the rotation of all the three rotary reels 23 is stopped. At this time, if a combination of symbols related to the combination is arranged on the effective line of the symbol display window 31, a winning combination corresponding to the combination of the symbol is won, a predetermined number of medals are paid, a transition to a special game, etc. A predetermined profit is given to the player.
(Medal discharge control means 110)
The medal discharge control means 110 controls the discharge of medals by the discharge device 63.

In the present embodiment, the medal discharge control means 110 controls the driving of the motor 68 of the discharge device 63.
Specifically, when a medal is paid out by winning a winning combination, or when a medal credited by operating the settlement switch 52 is paid out, the medal discharge control means 110 outputs a motor drive signal. When the motor 68 is driven in response to this motor drive signal, the disk rotor 71 rotates.
(Motor drive monitoring timer 120)
The motor drive monitoring timer 120 measures the time for which the motor 68 is driven when one medal is ejected by the ejecting device 63.

Specifically, when paying out medals by winning a winning combination or paying out medals credited by operating the settlement switch 52, the motor drive monitoring timer 120 is set to Tm seconds and countdown is started. Then, the medal discharge control means 110 outputs a motor drive signal, and the motor 68 starts driving.
When the discharging device 63 discharges one medal, when further discharging the medal, in other words, when the driving of the motor 68 of the discharging device 63 is continued, the motor drive monitoring timer 120 resets the time count. Then start timing again. That is, Tm seconds are reset in the motor drive monitoring timer 120, and the countdown is started again.

(Discharge error judgment means 130)
The discharge error determination means 130 determines whether or not an abnormality has occurred in the hopper device 60 based on the time measured by the motor drive monitoring timer 120. In this case, the abnormality of the hopper device 60 (hereinafter referred to as “discharge error”) specifically means that there are no medals in the tank 61 or a small amount of medals, or there are medals at the discharge port 64 of the discharge device 63. It may be clogged.
In the present embodiment, the discharge error determination means 130 determines that a discharge error has occurred when it is determined that the time measured by the motor drive monitoring timer 120 has reached “0”. In response to this, the medal discharge control means 110 stops outputting the motor drive signal. Therefore, the motor 68 stops driving, and the disk rotor 71 also stops rotating.

(Discharge sensor monitoring timer 140)
The discharge sensor monitoring timer 140 starts measuring a predetermined time when the voltage level of the signal output from the first discharge sensor 81 rises from low to high.
Specifically, when the voltage level of the signal output from the first discharge sensor 81 rises from low to high, the discharge sensor monitoring timer 140 is set to Ts seconds (Ts <Tm) and starts counting down. To do.
Then, the discharge sensor monitoring timer 140 resets the time count and starts timing again when the voltage level of the signal output from the second discharge sensor 82 falls from high to low. That is, Ts seconds are reset in the discharge sensor monitoring timer 140, and the countdown is started again.

(Discharge sensor error judgment means 150)
The discharge sensor error determination means 150 determines whether or not an abnormality has occurred in the hopper device 60 based on the time measured by the discharge sensor monitoring timer 140. In this case, the abnormality of the hopper device 60 (hereinafter referred to as “discharge sensor error”) specifically refers to the fact that the discharge sensor is malfunctioning due to irradiation of strong electromagnetic waves, and that the counter arm 75 is It is conceivable that the rocking is hindered or the discharge sensor or the count arm 75 is broken.
In the present embodiment, the discharge sensor error determination means 150 determines that a discharge sensor error has occurred when it is determined that the time measured by the discharge sensor monitoring timer 140 has reached “0”. In response to this, the medal discharge control means 110 stops outputting the motor drive signal. Therefore, the motor 68 stops driving, and the disk rotor 71 also stops rotating.

(Medal discharge control process)
Next, the medal discharge control process will be described with reference to FIG.
In the medal discharge control process, the following process is executed when a medal is paid out by winning a winning combination or when a medal credited by operating the settlement switch 52 is paid out.
In step 101, an error display request command for a discharge error is set. Then, the process proceeds to Step 102.
In step 102, Tm seconds are set in the motor drive monitoring timer 120 and countdown is started. Then, the process proceeds to Step 103.

In step 103, the medal discharge control means 110 outputs a motor drive signal. When the motor 68 is driven in response to this motor drive signal, the disk rotor 71 rotates. Then, the process proceeds to Step 104.
In step 104, it is determined whether or not the time measured by the motor drive monitoring timer 120 is “0”. If it is determined that the time measured by the motor drive monitoring timer 120 is not “0”, the process proceeds to step 105. If it is determined that the time measured by the motor drive monitoring timer 120 is “0”, the process proceeds to step 118.
In step 105, it is determined whether or not the voltage level of the signal output from the first discharge sensor 81 is “high”. If it is determined that the voltage level of the signal output from the first discharge sensor 81 is “high”, the process proceeds to step 106. If it is determined that the voltage level of the signal output from the first discharge sensor 81 is “low”, the process returns to step 104.

In step 106, the discharge sensor monitoring timer 140 is set to Ts seconds and starts counting down. Then, the process proceeds to Step 107.
In step 107, it is determined whether or not the time measured by the discharge sensor monitoring timer 140 is “0”. If it is determined that the time measured by the discharge sensor monitoring timer 140 is not “0”, the process proceeds to step 108. If it is determined that the time measured by the discharge sensor monitoring timer 140 is “0”, the process proceeds to step 117.
In step 108, it is determined whether or not the voltage level of the signal output from the first discharge sensor 81 is “high”. If it is determined that the voltage level of the signal output from the first discharge sensor 81 is “high”, the process proceeds to step 109. If it is determined that the voltage level of the signal output from the first discharge sensor 81 is “low”, the process returns to step 104.

In step 109, it is determined whether or not the voltage level of the signal output from the second discharge sensor 82 is “low”. When it is determined that the voltage level of the signal output from the second discharge sensor 82 is “low”, the process proceeds to step 110. If it is determined that the voltage level of the signal output from the second discharge sensor 82 is “high”, the process returns to step 107.
In step 110, Ts seconds are set in the discharge sensor monitoring timer 140, and the countdown is started again. Then, the process proceeds to Step 111.
In step 111, it is determined whether or not the time measured by the discharge sensor monitoring timer 140 is “0”. If it is determined that the time measured by the discharge sensor monitoring timer 140 is not “0”, the process proceeds to step 112. If it is determined that the time measured by the discharge sensor monitoring timer 140 is “0”, the process proceeds to step 117.

In step 112, it is determined whether the voltage level of the signal output from the second discharge sensor 82 is “high”. When it is determined that the voltage level of the signal output from the second discharge sensor 82 is “high”, the process proceeds to step 113. If it is determined that the voltage level of the signal output from the second discharge sensor 82 is “low”, the process returns to step 111.
In step 113, it is determined whether or not the voltage level of the signal output from the first discharge sensor 81 is “low”. If it is determined that the voltage level of the signal output from the first discharge sensor 81 is “low”, the process proceeds to step 114. If it is determined that the voltage level of the signal output from the first discharge sensor 81 is “high”, the process returns to step 111.

In step 114, it is determined that one medal has been discharged from the discharge port 64 of the discharging device 63, that is, it is determined that one medal has been paid out. Then, the process proceeds to step 115.
In step 115, it is determined whether or not the predetermined number of medals has been paid out. If it is determined that the predetermined number of medals has not been paid out, the process proceeds to step 116. If it is determined that a predetermined number of medals have been paid out, the process proceeds to step 119.
In step 116, Tm seconds are set in the motor drive monitoring timer 120 and countdown is started. Then, the process returns to step 104.
In step 117, the command for requesting error display for discharge error is rewritten to a command for requesting error display for discharge sensor error. Then, the process proceeds to Step 118.

In step 118, an error display corresponding to the set error display request command is displayed on the display device (for example, the image display device 34 or the credit amount display unit 37). Then, the process proceeds to Step 119.
In step 119, the medal discharge control means 110 stops outputting the motor drive signal. Therefore, the motor 68 stops driving, and the disk rotor 71 also stops rotating. Then, this process ends.
As described above, according to the present embodiment, when the voltage levels of the signals of the first discharge sensor 81 and the second discharge sensor 82 are both high for Ts seconds, an abnormality has occurred in the hopper device 60. It comes to judge.

Specifically, the discharge sensor monitoring timer 140 sets Ts seconds and starts counting down when the voltage level of the signal of the first discharge sensor 81 rises from low to high. Then, when the time measured by the discharge sensor monitoring timer 140 reaches “0” while the voltage level of the signal of the second discharge sensor 82 remains high, it is determined that an abnormality has occurred in the hopper device 60. (See Steps 105 to 109 and Steps 117 to 119 in FIG. 11).
In response to the voltage level of the signal from the second discharge sensor 82 falling from high to low, the time measured by the discharge sensor monitoring timer 140 is reset to Ts seconds and the countdown is started again. When the time measured by the discharge sensor monitoring timer 140 reaches “0” while the voltage level of the signal of the first discharge sensor 81 is high, it is determined that an abnormality has occurred in the hopper device 60. (See Steps 109 to 113 and Steps 117 to 119 in FIG. 11).

Therefore, when the discharge device 63 is irradiated with a strong electromagnetic wave and the signals of the first discharge sensor 81 and the second discharge sensor 82 are forcibly fixed at a high level, this is detected as an abnormality of the hopper device 60. Can do. Then, by stopping the driving of the motor 68 of the discharge device 63 or notifying the display device or the like of the occurrence of an abnormality, it is possible to prevent radio wave hopper goto.
In response to the voltage level of the signal from the second discharge sensor 82 falling from high to low, the time measured by the discharge sensor monitoring timer 140 is reset to Ts seconds and the countdown is started again. When the time measured by the discharge sensor monitoring timer 140 reaches “0” while the voltage level of the signal of the second discharge sensor 82 is low, it is determined that an abnormality has occurred in the hopper device 60. (See Steps 109 to 113 and Steps 117 to 119 in FIG. 11).

Therefore, when an illegal instrument is inserted into the discharge device 63 and the count arm 75 is fixed at the second position, this can be detected as an abnormality of the hopper device 60. Then, by stopping the driving of the motor 68 of the discharge device 63 or notifying the display device or the like of the occurrence of an abnormality, this illegal act can be prevented.
In addition, this invention is not limited to embodiment mentioned above, The deformation | transformation and improvement in the range which can achieve the objective of this invention are also included.

60 Hopper device 61 Tank
62 Pedestal 63 Discharge device
64 Discharge port 65 Base
66 Recess 67 Through hole
68 motor
71 Disc rotor 72 Fitting hole
73 impeller 74 blades
75 Count arm 76 Contact part
77 Detected piece
81 First discharge sensor 82 Second discharge sensor
82 Panel plate 83 Panel frame
84 Opening 85 Panel protrusion
86 Projection piece 87 Projection
88 Boss
100 Main control board 110 Medal discharge control means
120 Motor drive monitoring timer 130 Discharge error judgment means
140 Discharge sensor monitoring timer 150 Discharge sensor error judgment means

Claims (3)

A gaming machine equipped with a hopper device for paying out medals,
The hopper device is
A tank capable of storing multiple medals,
A discharge device for discharging the medal in the tank from the discharge port;
Two discharge sensors for detecting the discharge of medals from the discharge port,
When the operation of the discharge device is stopped, the voltage level of a signal output from one of the two discharge sensors (hereinafter referred to as “first discharge sensor”) is low, and the other (hereinafter referred to as “second discharge sensor”). The voltage level of the signal output from “) is high,
Each time one medal is discharged from the discharge port by the operation of the discharge device, the voltage level of the signal output from the first discharge sensor becomes high and the signal output from the second discharge sensor Is formed so that the voltage level is low,
When the voltage levels of the signals output from the first discharge sensor and the second discharge sensor are both high for a predetermined time, it is determined that an abnormality has occurred in the hopper device. Gaming machine. The discharge device includes a count arm that swings between a first position and a second position;
The first discharge sensor detects that the count arm is located at a first position;
The second discharge sensor detects that the count arm is located at a second position;
The count arm is located at the first position when the operation of the discharge device is stopped, and reciprocates from the first position to the second position every time one medal is discharged from the discharge port by the operation of the discharge device. The gaming machine according to claim 1. A discharge sensor monitoring timer that starts timing when the voltage level of the signal output from the first discharge sensor rises from low to high;
After the discharge sensor monitoring timer starts timing, when the time measured by the discharge sensor monitoring timer reaches a predetermined time while the voltage level of the signal output from the second discharge sensor continues to be high. Determining that an abnormality has occurred in the hopper device,
The discharge sensor monitoring timer resets the clock time and starts counting again when the voltage level of the signal output from the second discharge sensor falls from high to low.
After the discharge sensor monitoring timer resets the time and starts counting again, the time measured by the discharge sensor monitoring timer is maintained while the voltage level of the signal output from the first discharge sensor remains high. 3. The gaming machine according to claim 2, wherein when the predetermined time is reached, it is determined that an abnormality has occurred in the hopper device.

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