JP2006068342A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent wrongdoing using an illegal tool, with respect to a game machine. <P>SOLUTION: The game machine 10 comprises: a token passage 61 for guiding a token thrown into a token throw-in port 41 in a fixed direction; a first photo-sensor 66 arranged in the middle of the token passage 61; and a second photo-sensor 67 arranged at the downstream side of the first photo-sensor 66 which is arranged in the middle of the token passage 61. The first and second photo-sensors 66, 67 respectively comprises a light emitting part for emitting light and a light receiving part for receiving the light emitted from the light emitting part. At least one of the first and second photo-sensors 66, 67 can stop the light emission of the light emitting part in a state in which the light receiving part can detect the light. The game machine 10 comprises: a light emission control means 150 for controlling the light emission of the light emitting part; and an abnormality determining means 160 for determining an abnormality when the light receiving part corresponding to the light emitting part detects the light when light emission of the light emitting part is stopped by the light emission control means 150. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a gaming machine, and more particularly to a gaming machine in which a medal inserted from a medal slot is detected by two photo sensors provided in the middle of a medal passage.

2. Description of the Related Art Conventionally, gaming machines that play games by inserting medals as gaming media have been provided.
An example of such a gaming machine is a slot machine.
Also, in the slot machine, if the start switch is operated on condition that a predetermined number of medals are inserted, rotation of all three rotary reels starts, and if the stop switch is operated, rotation of the rotary reel corresponding to the stop switch is performed. Is a game machine in which a predetermined number of medals are paid out when a predetermined symbol is aligned on an effective winning line when all three rotating reels stop rotating. .
Also, in the slot machine, when the start switch is operated, the number of inserted medals is fixed, the number of winning lines corresponding to the number of inserted medals becomes valid, and the winning probability corresponding to the number of inserted medals is selected. A lottery of the winning combination is performed, and the stop control of the rotating reel is performed based on the result of the lottery of the winning combination.

  Specifically, a medal passage for guiding a medal inserted into the medal slot downward is provided in the slot machine. In addition, the medal passage communicates with the medal tank of the hopper unit. In addition, a medal return passage is branched from the middle of the medal passage. In addition, the medal return passage communicates with the medal return port. In addition, a medal selector is provided at a branch portion where the medal return passage branches from the medal passage. The medal selector selects non-standard medals and guides them to the medal return passage, and guides medals inserted from the medal insertion slot to the medal return passage when the medal insertion is disabled. It is. In addition, a medal sensor is provided in the middle of the medal path and downstream of the medal selector. The medal sensor is for detecting the passage of medals and outputting a medal detection signal. Further, the control device of the slot machine includes medal counting means for counting the number of medals inserted from the medal insertion slot based on the medal detection signal.

Then, when a medal inserted from the medal insertion slot flows down the medal passage, passes through the medal selector, and passes through the medal sensor, a medal detection signal is output. The medal counting means performs a counting operation based on the medal detection signal, whereby the number of medals inserted from the medal insertion slot is counted. The medal that has passed the medal sensor further flows down the medal passage and is stored in the medal tank of the hopper unit.
On the other hand, a start switch that outputs a start signal by an operation is provided on the front surface of the slot machine. Further, the control device of the slot machine includes a combination lottery means for performing combination lottery and a game control unit for controlling a game. In addition, the game control means establishes the number of inserted medals with the input of the start signal, and validates the number of winning lines corresponding to the number of inserted medals. Further, the combination lottery means obtains a combination lottery table corresponding to the number of inserted medals when the start signal is input, and draws a combination using the acquired combination lottery table. In addition, the game control means starts the rotation of the rotating reel in response to the input of the start signal, and based on the result of the lottery of the combination and the rotating position of the rotating reel when the stop switch is operated, Perform stop control. Then, when the rotation of all the rotating reels is stopped, if the predetermined symbols are aligned on the valid winning line, it is determined that the winning is made, and the hopper unit is driven to pay a predetermined number of medals according to the winning mode. put out.

  Here, in the slot machine, a credit function is provided in order to release the player from the burden of inserting medals. The credit function is as follows. Prior to the start of the game, when a certain number of medals are previously inserted into the medal slot, these medals are detected by the medal sensor, and based on the medal detection signal output at this time, the credit medal counting means Performs the counting operation. That is, medals are credited. The count value of the credit medal counting means is displayed on a 7-segment LED provided on the front surface of the slot machine. If the bet switch provided on the front of the slot machine is operated while the medal is credited, the credited medal is inserted and the credit is inserted instead of the medal insertion from the medal insertion slot. The count value of the credit medal counting means is subtracted by the amount of inserted medal. In addition, the 7-segment LED displays the count value after subtraction. When a credited medal is inserted, a game can be performed in the same manner as when a medal is inserted from the medal slot. Further, when it is desired to finish the game before the count value of the credit medal counting means becomes 0, the settlement switch provided on the front surface of the slot machine is operated. Then, the credited medal is paid out, and the count value of the credit medal counting means becomes zero.

Here, the medal sensor is composed of two photo sensors provided in parallel along the medal path direction. The first photosensor is provided on the upstream side of the medal passage, and the second photosensor is provided on the downstream side. If the optical path of the first photosensor is interrupted first, and then the optical path of the second photosensor is interrupted immediately thereafter, the advancing direction of the medal is normal, but the optical path of the second photosensor is interrupted first and immediately thereafter If the optical path of the first photosensor is interrupted, the direction of movement of the medal is abnormal.
In this way, in the slot machine, the medal sensor is constituted by two photo sensors, so that not only the medal passing but also the medal advancing direction can be detected. Then, the medal with the thread tied is inserted from the medal insertion slot, and the medal moves back and forth between the medal sensors by manipulating the thread to prevent the act of illegally adding the count value of the credit medal counting means. (See Patent Document 1).
Japanese Patent Laid-Open No. 7-108081

However, in recent years, the counter value of the credit medal counting means has been illegally used by using a fraudulent instrument in which a plurality of LEDs emitting light of the same quality as the light emitted from the light emitting portion of the photosensor are arranged near the tip of the elongated plate-like member The act of adding was discovered.
Specifically, each photosensor has a light emitting unit that emits light and a light receiving unit that receives light emitted from the light emitting unit. It is misunderstood as emitted light and causes each photosensor to malfunction. The method of using this illegal instrument is as follows. First, in the state where each LED is made to emit light, the vicinity of the tip of the plate-like member is inserted into the medal passage from the medal insertion slot, and is positioned between the light emitting portion and the light receiving portion of each photosensor. At this time, each LED is directed toward the light receiving portion of each photosensor so that the light emitted from each LED reaches the light receiving portion of each photosensor. Then, although a foreign object that blocks light is inserted between the light emitting unit and the light receiving unit of each photosensor, each photosensor misidentifies that there is no light blocking between the light emitting unit and the light receiving unit. . In this state, the LEDs are temporarily turned off in order from the upstream one. Then, first, neither the light emitted from the light emitting unit nor the light emitted from the LED reaches the light receiving unit of the first photosensor, and immediately after that, the light emitted from the light emitting unit also enters the light receiving unit of the second photosensor. The light emitted from the LED will not reach. Then, the light emitted from the LED reaches both the light receiving part of the first photosensor and the light receiving part of the second photosensor by causing the LEDs to emit light again in order from the upstream side. As a result, a state is created as if a medal has passed from the upstream side toward the downstream side, and the count value of the credit medal counting means is added illegally.

And there is an urgent need for prevention of fraudulent activity using this fraudulent instrument.
(Claim 1)
Therefore, the invention according to claim 1 stops the light emission of the light emitting unit and enables the light emitting unit to emit light while allowing the light detection unit to detect light with respect to either the first photo sensor or the second photo sensor. An object of the present invention is to provide a gaming machine capable of preventing fraud using a fraudulent instrument by determining that an abnormality occurs when the light receiving unit corresponding to the light emitting unit detects light when the light is stopped. .
(Claim 2)
In addition to the object of the invention described in claim 1, the invention described in claim 2 emits light when the light emitting portion of either the first photosensor or the second photosensor is stopped. When the light receiving unit corresponding to the light emitting unit stops detecting light, the light emitting unit that has stopped emitting light is emitted immediately or within a predetermined time. At this time, the light receiving unit corresponding to the light emitting unit detects light. By judging whether it is abnormal or not based on whether or not it is, it was possible to prevent fraudulent acts using fraudulent equipment and fraudulent acts that illegally increase the number of credits with a medal tied with a thread. An object is to provide a gaming machine.

(Claim 3)
According to a third aspect of the invention, in addition to the object of the second aspect of the invention, when the light emission of the light emitting portion of the first photosensor is stopped, the light receiving portion of the second photosensor stops detecting light. With a relatively simple configuration, the light emitting unit of the first photosensor emits light immediately or within a predetermined time, and at this time, when the light receiving unit of the first photosensor detects light, it is determined as abnormal, It is an object of the present invention to provide a gaming machine that can prevent the above two illegal acts simultaneously.
(Claim 4)
According to a fourth aspect of the present invention, in addition to the object of the third aspect of the invention, the light emitting portion of the first photosensor is stopped and the light emitting portion of the second photosensor is turned on from the medal slot. It is an object of the present invention to provide a gaming machine capable of reducing the burden on the control device while preventing illegal acts by constantly executing the control for waiting for the insertion of the medal.

(Claim 5)
In addition to the object of the invention according to claim 5, the invention according to claim 5 is configured so that the light emission portion of the first photosensor is stopped and the light emission portion of the second photosensor is turned on from the medal insertion slot. The game is executed once for either the control for waiting for the insertion of a medal or the control for waiting for the insertion of a medal from the medal insertion slot in a state where the light emitting portions of both the first photosensor and the second photosensor are lit. It is difficult to synchronize the light emission or extinguishing pattern of the light emitting unit of the first photosensor with the light emitting or extinguishing pattern of the LED of the unauthorized device by performing selection and execution based on a random value each time it is performed. Thus, an object of the present invention is to provide a gaming machine that further prevents fraud.

(Claim 6)
According to a sixth aspect of the invention, in addition to the object of the third aspect of the invention, the light emitting portion of the first photosensor is stopped and the light emitting portion of the second photosensor is turned on from the medal slot. One medal is detected: control for waiting for the insertion of a medal and control for waiting for the insertion of a medal from the medal insertion slot in a state where the light emitting portions of both the first photosensor and the second photosensor are caused to emit light. By alternately switching and executing each time, it becomes difficult to synchronize the light emission or extinction pattern of the light emitting part of the first photosensor and the light emission or extinction pattern of the LED of the fraudulent instrument. An object of the present invention is to provide a gaming machine with further prevention.

(Claim 7)
According to a seventh aspect of the invention, in addition to the object of the third aspect of the invention, the light emitting portion of the first photosensor is stopped and the light emitting portion of the second photosensor is turned on from the medal slot. Control for waiting for the insertion of a medal and control for waiting for the insertion of a medal from the medal insertion slot in a state in which the light emitting portions of both the first photosensor and the second photosensor are caused to emit light. By alternately switching and executing at intervals shorter than the time, it is difficult to synchronize the light emission or extinction pattern of the light emitting part of the first photosensor and the light emission or extinction pattern of the LED of the unauthorized device, It is an object of the present invention to provide a gaming machine that further prevents fraud.

(Claim 1)
The invention described in claim 1 includes a medal passage 61 for guiding a medal inserted into the medal insertion slot 41 in a certain direction, a first photo sensor 66 provided at a predetermined position in the middle of the medal passage 61, and a medal passage. A gaming machine 10 including a second photosensor 67 provided at a predetermined position downstream of the first photosensor 66 in the middle of 61, wherein the first photosensor 66 and the second photosensor 67 are respectively The light emitting unit that emits light and the light receiving unit that receives the light emitted from the light emitting unit are formed so that the optical path from the light emitting unit to the light receiving unit is blocked by the medal passing through the medal passage 61. At least one of the sensor 66 and the second photosensor 67 is formed to be able to stop the light emission of the light emitting unit while allowing the light detection by the light receiving unit, and the gaming machine 10 controls the light emission of the light emitting unit. Light emission control means 150 and an abnormality determination means 160 that determines that an abnormality is detected when the light receiving section corresponding to the light emission section detects light when the light emission control means 150 stops light emission. It is characterized by.

Here, the “medal passage 61” is for guiding a medal inserted into the medal insertion slot 41 in a certain direction. The medal insertion port 41 side of the medal passage 61 is the upstream side, and the opposite side of the medal passage 61 from the medal insertion port 41 is the downstream side. The medal passage 61 is formed so as to guide the medal inserted into the medal insertion port 41 in a certain direction from the upstream side toward the downstream side. Further, the medal passage 61 may be formed so as to incline in a straight line obliquely downward from the medal insertion slot 41, and bends appropriately in the middle and is directed to a relatively gently inclined portion or in a horizontal direction. You may form so that it may have a flat part.
Further, the “first photo sensor 66” is provided at a predetermined position in the middle of the medal passage 61.

The “second photosensor 67” is provided at a predetermined position downstream of the first photosensor 66 in the middle of the medal passage 61.
Thereby, the medal passing through the medal passage 61 from the upstream side toward the downstream side first passes through the first photo sensor 66 and then passes through the second photo sensor 67.
The first photosensor 66 includes a light emitting unit that emits light and a light receiving unit that receives the light emitted from the light emitting unit.
Similarly, the second photosensor 67 includes a light emitting unit and a light receiving unit.
Further, the first photo sensor 66 blocks the optical path from the light emitting unit to the light receiving unit by a medal passing through the medal passage 61. For example, the medal path 61 is sandwiched between the light emitting unit and the light receiving unit. Then, the medals passing through the medal passage 61 are allowed to pass between the light emitting unit and the light receiving unit. Then, the optical path from the light emitting unit to the light receiving unit is blocked by the medal passing through the medal passage 61.

Similarly, in the second photosensor 67, the optical path from the light emitting unit to the light receiving unit is blocked by the medal passing through the medal passage 61.
In addition, at least one of the first photosensor 66 and the second photosensor 67 is formed so that light emission of the light emitting unit can be stopped while light detection by the light receiving unit is possible.
Since it is “at least one”, only the first photosensor 66 may be formed so that light emission from the light emitting unit can be stopped while light detection by the light receiving unit is possible. Only for 67, it may be formed so that light emission from the light emitting part can be stopped while light detection by the light receiving part is possible, and both the first photo sensor 66 and the second photo sensor 67 receive light. You may form so that light emission of a light emission part can be stopped, enabling the detection of the light by a part.

In addition, “it is possible to stop the light emission of the light emitting unit” means that the light of the light emitting unit can be turned off. In other words, the light emitting unit can be turned off or the function of the light emitting unit can be turned off. This means that it can be turned off.
In addition, “It is possible to stop the light emission of the light emitting part while making the light detection by the light receiving part possible” means that the light of the light emitting part can be turned off while the light receiving part continues to detect the light. In other words, it is possible to stop the function of the light emitting unit while keeping the function of the light receiving unit, or to turn off the function of the light emitting unit while keeping the function of the light receiving unit ON. Means that it is possible.

The “light emission control means 150” is for controlling the light emission of the light emitting unit.
For example, when only the first photosensor 66 is configured to stop the light emission of the light emitting unit, the light emission control unit 150 causes the light emission unit of the first photosensor 66 to emit light or stops the light emission. Or
Further, for example, when only the second photosensor 67 is formed so as to stop the light emission of the light emitting unit, the light emission control unit 150 causes the light emission unit of the second photosensor 67 to emit light or emit light only. Or stop.
In addition, for example, when both the first photosensor 66 and the second photosensor 67 are formed so as to stop the light emission of the light emitting unit, the light emission control unit 150 is configured for the light emitting unit of the first photosensor 66. The light emission is stopped or stopped, and the light emitting portion of the second photosensor 67 is also turned on or off. However, in this case, the light emission control means 150 causes the light emission part of the second photosensor 67 to emit light when stopping the light emission of the light emission part of the first photosensor 66, and when stopping light emission of the light emission part of the second photosensor 67, The light emitting part of the first photosensor 66 emits light. That is, when the light emission control unit 150 stops light emission of one light emitting unit, the other light emitting unit emits light. Therefore, the light emission control unit 150 does not stop the light emission of the light emitting unit of the first photosensor 66 and the light emission of the light emitting unit of the second photosensor 67 at the same time. That is, the light emission control means 150 does not turn off the lights of both light emitting units simultaneously.

In addition, the light emission control unit 150 can randomly determine whether the light emitting unit emits light or stops light emission of the light emitting unit, for example, by lottery using a random number. The light emission control unit 150 may alternately switch light emission and light emission stop every time a medal is inserted, and each time a game is played, The light emission and the light emission stop may be switched alternately, and the light emission of the light emitting unit and the light emission stop may be alternately switched every predetermined time. Note that the light emission stop of the light emitting unit means that the light emission of the light emitting unit is stopped.
In addition, the light emission control unit 150 can randomly determine which light emission unit of the first photosensor 66 or the second photosensor 67 is to be stopped, for example, by lottery using a random number. In addition, the light emission control unit 150 may alternately switch the light emission stop of the light emission unit of the first photosensor 66 and the light emission stop of the light emission unit of the second photosensor 67 every time a medal is inserted. In addition, every time a game is played, the light emission stop of the light emission part of the first photosensor 66 and the light emission stop of the light emission part of the second photosensor 67 may be switched alternately, or at predetermined time intervals. Alternatively, the light emission stop of the light emitting unit of the first photosensor 66 and the light emission stop of the light emitting unit of the second photosensor 67 may be switched alternately.

Further, the “abnormality determination unit 160” is used to determine that an abnormality is detected when the light receiving unit corresponding to the light emitting unit detects light when the light emission control unit 150 stops light emission.
Here, in the present invention, “abnormality” is not limited to failure or error, but also includes “a state in which an unauthorized device is inserted into the medal passage 61 from the medal insertion slot 41”. In other words, in the present invention, the abnormality determining means 160 determines that “the state in which the unauthorized device is inserted into the medal passage 61 from the medal insertion slot 41” is also “abnormal”.
For example, when the light emission control unit 150 stops the light emission of the light emitting unit of the first photosensor 66 and the light receiving unit of the first photosensor 66 detects light, the abnormality determination unit 160 determines that there is an abnormality.

For example, when the light emission control unit 150 stops the light emission of the light emitting unit of the second photosensor 67 and the light receiving unit of the second photosensor 67 detects light, the abnormality determination unit 160 determines that there is an abnormality. .
That is, when the light emission of the light emitting portion of the first photosensor 66 is stopped, the light receiving portion of the first photosensor 66 should not detect light normally, and the light receiving portion of the first photosensor 66 is light. Is detected, it is abnormal. Then, when the light receiving unit of the first photosensor 66 detects light when the light emitting unit of the first photosensor 66 is stopped, the abnormality determination unit 160 performs an illegal act using an unauthorized instrument. It is determined as abnormal.

The same applies to the case where the light emitting unit of the second photosensor 67 is turned off.
In addition, when the light emitting unit of the first photosensor 66 is stopped emitting light and the light emitting unit of the second photosensor 67 is emitting light, the first photosensor 66 detects an illegal act using an unauthorized device. In addition, the second photo sensor 67 can detect passage of medals.
Further, when the light emitting portion of the first photosensor 66 emits light and the light emitting portion of the second photosensor 67 is stopped from emitting light, the first photosensor 66 can detect the passage of medals. The second photo sensor 67 can detect an illegal act using an illegal instrument.

  When both the first photosensor 66 and the second photosensor 67 emit light, the first photosensor 66 and the second photosensor 67 detect the passage of medals as in the conventional case. It is possible to detect the advancing direction of medals. That is, if the light receiving part of the first photosensor 66 is shielded from the light from the light emitting part first, and immediately after that, the light receiving part of the second photosensor 67 is shielded from the light from the light emitting part, the direction of movement of the medal is normal. It is. The medal counting means 170 or the credit medal counting means 180 is such that the light receiving part of the first photosensor 66 blocks the light from the light emitting part first, and immediately after that, the light receiving part of the second photosensor 67 is removed from the light emitting part. When the light is blocked, one count value is added assuming that one medal passes in the normal traveling direction. At this time, it is not possible to detect fraudulent acts by unauthorized equipment.

For example, the light emission of the first photosensor 66 is stopped, the light emission of the second photosensor 67 is turned on, the light emission of the first photosensor 66 is emitted, and the second photo By switching between the state in which the light emitting unit of the sensor 67 stops emitting light and the state in which both the light emitting unit of the first photosensor 66 and the light emitting unit of the second photosensor 67 emit light are switched randomly or in a predetermined pattern. In addition, it is possible to prevent a fraudulent act using a fraudulent instrument while detecting the passage of a medal, and it is also possible to prevent a fraudulent act that illegally increases the number of credits with a medal with a thread tied.
In addition, when the abnormality determination unit 160 determines that there is an abnormality, for example, an abnormality detection signal is output. Based on the abnormality detection signal, for example, the abnormality notification unit 165 can notify the abnormality by sounding an alarm sound from the speaker 36 or blinking the lamp 35. Further, for example, the game control means 110 can prevent the cheating from being continued by stopping the game based on the abnormality detection signal. Further, based on the abnormality detection signal, for example, the payout control unit can prevent the medal from being paid out by stopping the driving of the hopper unit 70. In addition, by sending an abnormality detection signal to the hall computer, it is possible to notify the administrator of the gaming machine 10 of an illegal act.

In addition, when the abnormality determination means 160 determines that an abnormality has occurred, the abnormality determination means 160 sounds an alarm sound from the speaker 36 or flashes the lamp 35 to notify the abnormality or stop the game so that the illegal action is continued. May be prevented, or the driving of the hopper unit 70 may be stopped to prevent the medal from being paid out.
As described above, when the light emitting unit of either the first photosensor 66 or the second photosensor 67 is turned off, and the light receiving unit corresponding to the light emitting unit detects light, it is determined as abnormal. As with the conventional gaming machine 10, even if the hardware configuration is two of the first photo sensor 66 and the second photo sensor 67, it is possible to prevent fraud using a fraudulent instrument mainly by software control. .

(Claim 2)
The invention according to claim 2 limits the invention according to claim 1, and is an optical path from the light emitting part to the light receiving part of the first photosensor 66 and from the light emitting part to the light receiving part of the second photosensor 67. The light path is formed so that it can be blocked simultaneously by one medal passing through the medal path 61, and the light emission control means 150 emits light from either the first photo sensor 66 or the second photo sensor 67. When the light receiving unit corresponding to the light emitting unit that emits light stops detecting light, the light emitting unit that has stopped emitting light is emitted immediately or within a predetermined time. When the light emission control unit 150 causes the light emitting unit that has stopped emitting light to emit light, it is determined whether or not there is an abnormality based on whether or not the light receiving unit corresponding to the light emitting unit detects light. And

  Here, for example, control for waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emission of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is turned on, By switching the control to wait for the insertion of medals from the medal insertion slot 41 in a state in which the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 are lit, the medal is switched randomly or in a predetermined pattern. Can detect fraudulent activities while using a fraudulent instrument, and can also prevent fraudulent acts that illegally increase the number of credits with a medal tied with a thread. It is not possible to simultaneously detect fraudulent acts that illegally increase the number of credits with medals tied with a thread.

  Further, for example, a control for waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emission of the second photosensor 67 is stopped and the light emission unit of the first photosensor 66 is turned on, By switching the control for waiting for the insertion of medals from the medal insertion slot 41 in a state where both the photosensor 66 and the second photosensor 67 emit light, randomly or in a predetermined pattern, While detecting passing, it is possible to prevent fraudulent acts using fraudulent instruments, and furthermore, fraudulent acts that illegally increase the number of credits with medals tied with strings can be prevented. It is not possible to simultaneously detect fraudulent acts that illegally increase the number of credits with medals tied with a thread.

Therefore, in the present invention, when light emission of one of the first photosensor 66 or the second photosensor 67 is stopped, the light receiving unit corresponding to the light emitting unit that emits light does not detect light. The light emitting unit that has stopped emitting light is emitted immediately or within a predetermined time, and at this time, it is determined whether or not there is an abnormality based on whether or not the light receiving unit corresponding to the light emitting unit detects light By doing so, it is possible to simultaneously prevent fraudulent acts using fraudulent devices and fraudulent acts that illegally increase the number of credits with medals tied with a thread.
Here, an optical path from the light emitting unit to the light receiving unit of the first photosensor 66 is referred to as a “first optical path”, and an optical path from the light emitting unit to the light receiving unit of the second photosensor 67 is referred to as a “second optical path”.

  The first photo sensor 66 and the second photo sensor 67 are arranged by shifting the positions of the first optical path and the second optical path from the position where the center of the medal in the medal path 61 passes. Thus, for example, even when three medals are continuously inserted from the medal insertion slot 41 and these three medals continuously flow down the medal passage 61, one inserted medal is inserted. Therefore, it is possible to correctly detect that the number is three without misidentifying that the number is. In other words, since the medals are circular, when the positions of the first optical path and the second optical path coincide with the positions through which the centers of the medals pass, when a plurality of medals continuously flow down the medal path 61, Although the first optical path and the second optical path remain blocked, and it is mistaken that there is only one inserted medal, the positions of the first optical path and the second optical path from the position where the center of the medal passes. By shifting, even if a plurality of medals flow continuously through the medal passage 61, the first optical path and the second optical path do not remain blocked, and it can be correctly detected that there are a plurality of medals. is there.

  Further, the first photo sensor 66 and the second photo sensor 67 are arranged close to each other, so that the first optical path and the second optical path are simultaneously blocked by one medal passing through the medal path 61. I have to. It should be noted that the distance between the first optical path and the second optical path is set to be smaller than the diameter of the medal, but as described above, the positions of the first optical path and the second optical path are determined by the medal. Since the center is shifted from the position through which the center passes, the amount of the shift is set in consideration. Specifically, for example, when the radius of the medal is “r” and the positions of the first optical path and the second optical path are shifted by “(½) × r” from the position through which the center of the medal passes, The distance to the second optical path is set to be smaller than “(√3) × r”.

In addition, the light emission control unit 150 detects light when the light emission unit corresponding to the light emission unit emits light when the light emission unit of either the first photosensor 66 or the second photosensor 67 is stopped. If it stops, the light emission part which stopped light emission will be light-emitted immediately or within predetermined time.
Specifically, the light emission control means 150 immediately or within a predetermined time if the light receiving unit of the second photosensor 67 stops detecting light when the light emitting unit of the first photosensor 66 is stopped. The light emitting portion of the first photo sensor 66 that has stopped emitting light is caused to emit light.
The light emission control means 150 emits light immediately or within a predetermined time if the light receiving portion of the first photo sensor 66 stops detecting light when the light emitting portion of the second photo sensor 67 is stopped. The light emitting part of the second photosensor 67 that has been stopped is caused to emit light.

  In addition, the “predetermined time” is when the light emitted from the light emitting unit of the first photosensor 66 is stopped after the medal guided from the upstream side to the downstream side of the medal path 61 begins to block the second optical path. This is the time until the first optical path is blocked. That is, the medal guided from the upstream side to the downstream side of the medal path 61 starts to block the first optical path, and then starts blocking the second optical path while continuing to block the first optical path, and then for a while In the meantime, both the first optical path and the second optical path are continuously blocked, and then the first optical path is completely blocked, but the second optical path is continuously blocked, and then the second optical path is completely blocked. The predetermined time is from the start of blocking the second optical path to the end of blocking the first optical path. In other words, the medal guided toward the medal path 61 from the upstream side toward the downstream side blocks the first optical path and does not block the second optical path, and blocks the first optical path and the second optical path. And a state where the first optical path is not blocked and the second optical path is blocked. The duration of the state in which the first optical path is blocked and the second optical path is also blocked is a predetermined time.

In addition, the “predetermined time” is to stop the light emission of the light emitting unit of the second photosensor 67 after the medal guided from the upstream side to the downstream side of the medal path 61 begins to block the first optical path. This is the time until immediately before the second optical path is interrupted. That is, the predetermined time is from the start of blocking the first optical path to the start of blocking the second optical path. In other words, the duration of the state where the first optical path is blocked and the second optical path is not blocked is a predetermined time.
In any case, the predetermined time varies depending on various conditions such as the inclination angle of the medal passage 61, the size of the medal, and the mounting positions of the first photosensor 66 and the second photosensor 67.

Further, the abnormality determination unit 160 determines whether or not there is an abnormality based on whether or not the light receiving unit corresponding to the light emitting unit detects light when the light emission control unit 150 switches the light emitting unit to light emission. To do.
Specifically, the abnormality determination unit 160 detects that the light receiving unit of the first photosensor 66 detects light when the light emission control unit 150 causes the light emitting unit of the first photosensor 66 that has stopped emitting light to emit light. Determined as abnormal.
In addition, the abnormality determination unit 160 is configured to detect an abnormality if the light receiving unit of the second photosensor 67 does not detect light when the light emission control unit 150 causes the light emitting unit of the second photosensor 67 that has stopped emitting light to emit light. It is determined.

  That is, if the medal guided from the upstream side toward the downstream side of the medal path 61 starts to block the second optical path, the light emission control unit 150 causes the light emission part of the first photosensor 66 to emit light from the stop of light emission. When the switch is made, the medal is before the first optical path is blocked, so the light receiving portion of the first photo sensor 66 should not detect light, and the light receiving portion of the first photo sensor 66 detects light. Then it is abnormal. Then, when the light emitting unit of the first photosensor 66 detects light when the light emitting unit of the first photosensor 66 is switched from the light emission stop to the light emission, the abnormality determination unit 160 detects a medal with a thread tied. It is determined that the medal passage 61 is abnormal because it is guided upward.

  Further, if the medal guided from the upstream side to the downstream side of the medal passage 61 blocks the first optical path, the light emission control unit 150 causes the light emission unit of the second photosensor 67 to change from light emission stop to light emission. At the time of switching, since the medal is before blocking the second optical path, the light receiving portion of the second photosensor 67 should detect light, and the light receiving portion of the second photosensor 67 must detect no light. It is abnormal. Then, when the light emitting unit of the second photosensor 67 is switched from the light emission stop to the light emission when the light receiving unit of the second photosensor 67 does not detect the light, the abnormality determining unit 160 Is determined to be abnormal, for example, because the medal passage 61 is guided upward.

In this way, when the light receiving unit corresponding to the light emitting unit emitting light stops detecting light when the light emitting unit of either the first photosensor 66 or the second photosensor 67 is stopped, Immediately or within a predetermined time, the light emitting unit that has stopped emitting light is caused to emit light, and at this time, it is determined whether or not there is an abnormality based on whether or not the light receiving unit corresponding to the light emitting unit detects light. Thus, it is possible to simultaneously prevent an illegal act using an illegal instrument and an illegal act that illegally increases the number of credits with a medal tied with a thread.
That is, if the light receiving unit of the second photosensor 67 stops detecting light when the light emitting unit of the first photosensor 66 is stopped, the light emitting unit of the first photosensor 66 is immediately or within a predetermined time. At this time, if the light receiving unit of the first photosensor 66 detects light, it is determined that there is an abnormality, so that the hardware configuration is the same as that of the conventional gaming machine 10, the first photosensor 66 and the second photosensor 66. Even with the two photosensors 67, it is possible to simultaneously prevent fraudulent acts using fraudulent instruments and fraudulent acts that illegally increase the number of credits with medals tied with strings.

If the light receiving unit of the first photo sensor 66 stops detecting light when the light emitting unit of the second photo sensor 67 is stopped, the light emitting unit of the second photo sensor 67 is immediately or within a predetermined time. At this time, if the light receiving unit of the second photosensor 67 does not detect the light, it is determined that there is an abnormality, so that the hardware configuration is the same as that of the conventional gaming machine 10, the first photosensor 66 and the second photosensor Even with the two photosensors 67, it is possible to simultaneously prevent an illegal act using an illegal instrument and an illegal act of illegally increasing the number of credits with a medal with a thread tied, mainly by software control.
(Claim 3)
The invention according to claim 3 limits the invention according to claim 2, and the light emission control means 150 is configured such that when the light emission of the light emitting portion of the first photosensor 66 is stopped, the second photosensor 67. When the light receiving unit stops detecting light, the light emitting unit of the first photosensor 66 that has stopped emitting light is emitted immediately or within a predetermined time, and the abnormality determining unit 160 is configured to stop the light emission by the light emission control unit 150. In addition, when the light emitting unit of the first photosensor 66 emits light, if the light receiving unit of the first photosensor 66 detects light, it is determined that there is an abnormality.

That is, the invention described in claim 3 is limited to the control in the case of stopping the light emission of the light emitting portion of the first photosensor 66 in the invention described in claim 2.
As described above, when the light receiving unit of the second photosensor 67 stops detecting light when the light emitting unit of the first photosensor 66 is stopped, the first photosensor 66 is immediately or within a predetermined time. By causing the light emitting portion to emit light and detecting the light by the light receiving portion of the first photosensor 66 at this time, it is possible to prevent the above two fraudulent acts at the same time with a relatively simple configuration by determining that it is abnormal.
That is, when the light emission of the light emitting portion of the first photosensor 66 is stopped, the first photosensor 66 mainly plays a role of detecting fraud, and the second photosensor 67 mainly plays a role of counting the number of medals. It will bear. Then, when the medal flows down the medal passage 61 from the upstream side toward the downstream side, first, it is confirmed mainly by the signal of the first photosensor 66 that the medal is not fraudulent, and then mainly by the signal of the second photosensor 67. Since the number of medals can be counted, the number of medals inserted from the medal insertion slot 41 can be counted while simultaneously preventing the above two illegal acts without requiring complicated control and configuration.

(Claim 4)
The invention according to claim 4 limits the invention according to claim 3, wherein the light emission control means 150 stops the light emission of the light emitting part of the first photosensor 66 and the light emission part of the second photosensor 67. Control that waits for the insertion of a medal from the medal insertion slot 41 in a light-emitting state is always executed.
That is, in the slot machine as the gaming machine 10, a medal can be inserted until one start of the game after the end of one game. In addition, a state where the medal insertion is enabled and a state where the medal is inserted from the medal insertion port 41 is a medal insertion waiting state. In the present invention, in the medal insertion waiting state, the light emitting portion of the first photosensor 66 is not always emitting light, and the light emitting portion of the second photosensor 67 is always emitting light. Of course, when a medal is inserted from the medal insertion port 41, the second optical path is blocked by the medal, and the light receiving unit of the second photosensor 67 no longer detects light, as described above, The light emitting part emits light.

In this way, the control of waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emission of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is turned on is always performed. By executing this, the burden on the control device can be reduced while preventing fraud.
(Claim 5)
The invention according to claim 5 limits the invention according to claim 3, and the light emission control means 150 stops the light emission of the light emitting part of the first photosensor 66 and the light emission part of the second photosensor 67. Control that waits for the insertion of a medal from the medal insertion slot 41 with the light emitted, or insertion of a medal from the medal insertion slot 41 with the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 illuminated. Either one of the controls for waiting for is selected and executed based on a random value every time a game is played.

That is, according to the present invention, in the medal insertion waiting state, the medal from the medal insertion slot 41 is stopped in a state where the light emission portion of the first photosensor 66 is stopped and the light emission portion of the second photosensor 67 is emitted. And control for waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emitting portions of both the first photosensor 66 and the second photosensor 67 emit light. In the present invention, any one of these two controls is selected and executed based on a random value every time a game is played.
For example, when one game is finished and the medal can be inserted, one of the two controls is selected based on the random value. At this time, for example, the control of waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emission of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is emitted is selected. Suppose. Then, this control continues until the start switch 43 is operated to set the medal insertion impossible. Thereafter, when the game started by the operation of the start switch 43 ends and the medal insertion is set to be possible, one of the two controls is selected again based on the random number value. At this time, for example, it is assumed that the control for waiting for the insertion of a medal from the medal insertion slot 41 is selected in a state where both the first photosensor 66 and the second photosensor 67 emit light. Then, this control continues until the start switch 43 is operated to set the medal insertion impossible.

In this way, the control of waiting for the insertion of a medal from the medal insertion slot 41 in the state where the light emission of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is turned on, or the first Each time a game is played, one of the controls for waiting for the insertion of medals from the medal insertion slot 41 with the light emitting portions of both the photo sensor 66 and the second photo sensor 67 being lit is a random value. Therefore, it is difficult to synchronize the light emission or extinction pattern of the light emitting unit of the first photosensor 66 with the light emission or extinction pattern of the LED of the unauthorized device. Thereby, further prevention of fraud can be achieved.
(Claim 6)
The invention according to claim 6 limits the invention according to claim 3, and the light emission control means 150 stops the light emission of the light emitting part of the first photosensor 66 and the light emission part of the second photosensor 67. Control that waits for the medal insertion from the medal insertion slot 41 with the light emitted, and insertion of the medal from the medal insertion slot 41 with the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 illuminated. The control of waiting for the time is executed by alternately switching each time one medal is detected.

That is, even in the present invention, in the medal insertion waiting state, the medal from the medal insertion slot 41 is stopped in a state where the light emission part of the first photosensor 66 is stopped and the light emission part of the second photosensor 67 is emitted. And control for waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emitting portions of both the first photosensor 66 and the second photosensor 67 emit light. In the present invention, these two controls are executed by alternately switching each time one medal is detected.
For example, it is assumed that a single medal is detected in a state where the light emission unit of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is emitted. Then, the medal to be inserted next is detected in a state where the light emitting portions of both the first photosensor 66 and the second photosensor 67 are caused to emit light.

For example, if ten medals are inserted between the time when the medal insertion is enabled and the medal insertion waiting state is started and the start switch 43 is operated until the game is started, the above two controls are performed. It is switched 10 times alternately.
In this way, control for waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emission of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is turned on, The control of waiting for the insertion of a medal from the medal insertion slot 41 while the light emitting portions of both the photo sensor 66 and the second photo sensor 67 are lit is alternately switched every time a medal is detected. By executing this, it becomes difficult to synchronize the light emission or extinction pattern of the light emitting section of the first photosensor 66 with the light emission or extinction pattern of the LED of the unauthorized device. Thereby, further prevention of fraud can be achieved.

(Claim 7)
The invention described in claim 7 limits the invention described in claim 3, and the light emission control means 150 stops the light emission of the light emitting part of the first photosensor 66 and the light emission part of the second photosensor 67. Control that waits for the medal insertion from the medal insertion slot 41 with the light emitted, and insertion of the medal from the medal insertion slot 41 with the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 illuminated. The control of waiting for the medals is performed by alternately switching at intervals shorter than the time required for detecting one medal.
That is, even in the present invention, in the medal insertion waiting state, the medal from the medal insertion slot 41 is stopped in a state where the light emission part of the first photosensor 66 is stopped and the light emission part of the second photosensor 67 is emitted. And control for waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emitting portions of both the first photosensor 66 and the second photosensor 67 emit light. In the present invention, these two controls are executed alternately at intervals shorter than the time required for detecting one medal.

For example, the light emitted from the light emitting portion of the first photosensor 66 is stopped and the second photo is also emitted until the medal inserted from the medal insertion slot 41 flows down the medal passage 61 and reaches the medal selector 63. Control that waits for the insertion of a medal from the medal insertion slot 41 with the light emitting portion of the sensor 67 lit, and the medal with the light emitting portions of both the first photosensor 66 and the second photosensor 67 being lit. The control of waiting for the insertion of a medal from the insertion slot 41 is switched alternately many times.
In this way, the control for waiting for the insertion of a medal from the medal insertion slot 41 in the state where the light emission of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is turned on, Control that waits for the insertion of a medal from the medal insertion slot 41 with the light emitting portions of both the photo sensor 66 and the second photo sensor 67 being emitted at an interval shorter than the time required to detect one medal, By performing the switching alternately, it becomes difficult to synchronize the light emission or extinction pattern of the light emitting unit of the first photosensor 66 with the light emission or extinction pattern of the LED of the unauthorized device. Thereby, further prevention of fraud can be achieved.

(Claim 1)
According to the first aspect of the present invention, when the light emitting unit of either the first photosensor or the second photosensor stops emitting light, the light receiving unit corresponding to the light emitting unit that stopped emitting light detects light. By determining as abnormal, it is possible to provide a gaming machine that can prevent fraud using a fraudulent instrument.
(Claim 2)
According to the second aspect of the present invention, when the light emitting part of either the first photosensor or the second photosensor is stopped, the light receiving part corresponding to the light emitting part emitting light detects the light. If it stops, the light emitting unit that has stopped emitting light is emitted immediately or within a predetermined time, and at this time, whether or not there is an abnormality based on whether or not the light receiving unit corresponding to the light emitting unit detects light Therefore, it is possible to provide a gaming machine that can simultaneously prevent an illegal act using an illegal instrument and an illegal act that illegally increases the number of credits with a medal tied with a thread.

(Claim 3)
According to the invention of claim 3, when the light receiving unit of the second photosensor stops detecting light when the light emitting unit of the first photosensor is stopped, immediately or within a predetermined time, By causing the light emitting part of the first photosensor to emit light and detecting the light at the light receiving part of the first photosensor at this time, it is possible to prevent the above two fraudulent acts with a relatively simple configuration by determining an abnormality. A gaming machine can be provided.
(Claim 4)
According to the invention of claim 4, the control of waiting for the insertion of a medal from the medal insertion slot in a state where the light emission of the first photosensor is stopped and the light emission portion of the second photosensor is made to emit light, Since it is always executed, it is possible to provide a gaming machine capable of reducing the burden on the control device while preventing fraud.

(Claim 5)
According to the fifth aspect of the present invention, the control for waiting for the insertion of a medal from the medal insertion slot in a state where the light emission of the first photosensor is stopped and the light emission unit of the second photosensor is turned on, or Either one of the controls for waiting for the insertion of medals from the medal insertion slot in the state where the light emitting portions of both the first photo sensor and the second photo sensor are lit is based on a random value every time a game is played. Since it is difficult to synchronize the light emission or extinguishing pattern of the light emitting unit of the first photosensor and the light emission or extinguishing pattern of the LED of the fraudulent instrument. Can be provided.

(Claim 6)
According to the invention of claim 6, control for waiting for the insertion of a medal from the medal insertion slot with the light emission of the first photosensor stopped and the light emission of the second photosensor emitted. The control of waiting for the insertion of a medal from the medal insertion slot while the light emitting portions of both the first photo sensor and the second photo sensor are lit is alternately performed every time a medal is detected. Therefore, since it becomes difficult to synchronize the light emission or extinction pattern of the light emitting unit of the first photosensor and the light emission or extinction pattern of the LED of the fraudulent instrument, a gaming machine that can further prevent fraud Can be provided.

(Claim 7)
According to the seventh aspect of the present invention, the control of waiting for the insertion of a medal from the medal insertion slot in a state where the light emission of the first photosensor is stopped and the light emission unit of the second photosensor is made to emit light, The control of waiting for the insertion of a medal from the medal insertion slot while the light emitting portions of both the first photosensor and the second photosensor are lit is alternately performed at an interval shorter than the time required for detecting one medal. Since switching is executed, it becomes difficult to synchronize the light emission or extinguishing pattern of the light emitting unit of the first photosensor and the LED light emitting or extinguishing pattern of the fraudulent instrument, thereby further preventing fraud. A game machine can be provided.

(First embodiment)
(Explanation of drawings)
1 to 8 show a first embodiment of the present invention.
1 is a block diagram of the gaming machine 10, FIG. 2 is a front view of the gaming machine 10, FIG. 3 is a front view of the medal processing unit 60, and FIG. 5 is a first photo sensor 66 and a second photo sensor that are medals. FIG. 6 is a time chart of medal detection signals, and FIGS. 7 and 8 are flowcharts of medal detection processing.
(Game machine 10)
As shown in FIG. 2, the gaming machine 10 according to the present embodiment is a slot machine.

As shown in FIG. 2, the slot machine includes a box-shaped housing 20 having an opening on the front surface. A front door 30 that closes the opening is provided on the front surface of the housing 20. In addition, the housing 20 includes a reel unit 50 in which three rotating reels 51 are provided side by side. In addition, a symbol see-through window 31 through which the symbol attached to the periphery of each rotary reel 51 can be seen is provided in the approximate center of the front door 30.
In addition, the symbol see-through window 31 is located in front of each rotating reel 51, and when all three rotating reels 51 stop rotating, a total of nine symbols arranged in three columns and three rows in a row. Is formed so as to be transparent. In addition, the symbol arrangement of 3 columns × 3 rows that can be seen through the symbol see-through window 31 is called “out”.

Further, in the present embodiment, the three symbols that can be seen through the symbol see-through window 31 when the rotation of the left rotating reel 51 is stopped in order from the top are “left reel upper symbol” and “left reel middle symbol”, respectively. The “left reel lower symbol” and the three symbols that can be seen through the symbol see-through window 31 when the rotation of the central rotating reel 51 is stopped are shown as “middle reel upper symbol” and “middle reel middle”. The three symbols that can be seen through the symbol see-through window 31 when the rotation of the right rotating reel 51 is stopped are shown as “right reel upper symbol” and “right reel”, respectively. “Reel middle design” “Right reel lower design”.
In the present embodiment, five pay lines from first to fifth are provided. Specifically, the first winning line passes through the left reel middle symbol, the middle reel middle symbol, and the right reel middle symbol, and the left reel upper symbol, middle reel upper symbol, and right reel upper symbol The second winning line passes through the left reel, the middle reel lower symbol and the right reel lower symbol passes the third winning line, and the left reel lower symbol. The "fourth winning line" passes through the middle reel middle symbol and the right reel upper symbol, and the fifth reel winning line passes through the left reel upper symbol, middle reel middle symbol, and right reel lower symbol. It is.

  As shown in FIG. 2, an operation unit 40 that protrudes forward from the front surface of the front door 30 is provided below the symbol see-through window 31. A medal insertion port 41 for inserting medals is provided on the upper right side of the operation unit 40, and a bet switch 42 for inserting credited medals is provided on the upper left side of the operation unit 40. Further, a settlement switch 45 for paying out a credited medal is provided on the front right side of the operation unit 40, and rotation of the rotary reel 51 is started on the left side of the front surface of the operation unit 40. A start switch 43 is provided, and three stop switches 44 for stopping the rotation of the rotary reel 51 are provided side by side in the center of the front surface of the operation unit 40.

In addition, a medal payout port 32 for paying out medals and a medal return port 33 for returning medals are provided in the lower center of the front door 30, and below these are discharged from these. A medal tray 34 is provided for receiving and storing received medals.
In addition, a lamp 35 used for production and the like is provided at the upper part of the front door 30, and speakers 36 for sounding sound effects are provided on both sides of the medal payout port 32 and the medal return port 33. Yes.
In addition, a medal processing unit 60 for processing medals inserted into the medal insertion slot 41 is provided on the back side of the front door 30, and inside the housing 20 is for controlling the gaming machine 10. A control device 100 and a hopper unit 70 for paying out medals are provided.

(Control device 100)
The control device 100 is for controlling the gaming machine 10.
The control device 100 is configured using a microcomputer including a CPU, a RAM, a ROM, an I / O, and the like.
As shown in FIG. 1, a start switch 43, a stop switch 44, a bet switch 42, a settlement switch 45, a medal sensor 65, and the like are connected as input means of the control device 100.
As shown in FIG. 1, as an output means of the control device 100, a reel unit 50, a hopper unit 70, a medal processing unit 60, and the like are connected.

In addition, the control device 100 causes the CPU to execute a predetermined program stored in the ROM, so that the light emission control means 150, the abnormality determination means 160, the abnormality notification means 165, the medal count means 170, the credit medal count means 180, the game It functions as the control means 110, the role lottery means 120, the stop control means 130, the winning determination means 140, and the like.
(Start switch 43)
The start switch 43 is for starting the rotation of the rotary reel 51, and is provided on the left side of the front surface of the operation unit 40 as shown in FIG.
The start switch 43 is configured using a lever-type switch, and a start signal is output when the tip of the lever is pushed down. When the start signal is output, the rotation of each rotary reel 51 is started.

(Stop switch 44)
The stop switch 44 is for stopping the rotation of the rotary reel 51, and is provided in the center of the front surface of the operation unit 40 as shown in FIG. The stop switch 44 is provided corresponding to each rotary reel 51. That is, three stop switches 44 are provided, and the three stop switches 44 are provided side by side in the center of the front surface of the operation unit 40.
Each stop switch 44 is configured by using a push button type switch. When a button provided on the left stop switch 44 is pressed, a left stop signal is output, and the center stop switch 44 is When a button provided is pressed, a middle stop signal is output, and when a button provided on the right stop switch 44 is pressed, a right stop signal is output. When the left stop signal is output, the rotation of the left rotating reel 51 is stopped. When the middle stop signal is output, the rotation of the central rotating reel 51 is stopped, and the right stop signal is output. When output, the rotation of the right rotating reel 51 stops.

(Bet switch 42)
The bet switch 42 is used to insert a credited medal, and is provided on the upper left side of the operation unit 40 as shown in FIG.
In the present embodiment, as the bet switch 42, a single bet switch 42a and a max bet switch 42b are provided. As shown in FIG. 2, the single bet switch 42 a and the max bet switch 42 b are provided side by side on the upper left side of the operation unit 40.
The single bet switch 42a is configured by using a push button type switch, and a single bet signal is output when the button is pressed. When the button is pressed once, a single bet signal is output once, and one credited medal is inserted. When the button is pressed twice, a single bet signal is output twice. When two credited medals are inserted and the button is pressed three times, a one-bet signal is output three times, and three credited medals are inserted.

Further, the max bet switch 42b is also configured by using a push button type switch, like the single bet switch 42a. However, the max bet switch 42b is configured to output a max bet signal when the button is pressed. When the maximum bet signal is output, the maximum number of medals that can be credited (three in the present embodiment) can be inserted per game.
(Checkout switch 45)
The settlement switch 45 is for paying out a credited medal, and is provided on the front right side of the operation unit 40 as shown in FIG.

Further, the settlement switch 45 is configured using a push button type switch, and a settlement signal is output when the button is pressed. When the settlement signal is output, all credited medals are paid out from the medal payout opening 32.
(Medal slot 41)
As shown in FIG. 2, the medal slot 41 is provided on the upper right side of the operation unit 40.
(Medal payout exit 32)
As shown in FIG. 2, the medal payout opening 32 is provided at the lower center of the front door 30.
(Medal return port 33)
As shown in FIG. 2, the medal return port 33 is provided at the lower center of the front door 30.

In the present embodiment, the medal payout port 32 and the medal return port 33 are shared.
(Medal tray 34)
The medal tray 34 is for receiving and storing medals discharged from the medal payout port 32 and the medal return port 33, and is provided below the medal payout port 32 and the medal return port 33 as shown in FIG. Is provided.
(Reel unit 50)
The reel unit 50 includes a frame, three stepping motors fixed to the frame side by side, and three rotary reels 51 fixed to the output shaft of each stepping motor.

In addition, around each rotating reel 51, a total of 21 symbols of a plurality of types such as “7”, “BAR”, “Bell”, “Watermelon”, “Cherry”, and “R” are attached in a predetermined arrangement.
In the present embodiment, the symbol “7” is a symbol corresponding to the big bonus award (BB award), and the symbol “BAR” is a symbol corresponding to the regular bonus award (RB award). The “Bell” symbol is a symbol corresponding to the Bell prize, the “Watermelon” symbol is a symbol corresponding to the watermelon award, and the “Cherry” symbol is a cherry award. The symbol “R” is a symbol corresponding to the replay winning.

(Hopper unit 70)
The hopper unit 70 is for paying out medals from the medal payout opening 32, and is provided inside the housing 20.
Although not shown, the hopper unit 70 includes a medal tank for storing medals and a sending mechanism for sending out medals stored in the medal tank. The medals delivered by the delivery mechanism are discharged from the medal payout opening 32.
(Medal processing unit 60)
The medal processing unit 60 is for processing medals inserted into the medal insertion slot 41, and is provided on the back side of the front door 30.

As shown in FIG. 3, the medal processing unit 60 includes a medal passage 61 for guiding a medal inserted into the medal insertion slot 41 in a certain direction, and a medal return passage 62 branching from the middle of the medal passage 61. The medal selector 63 provided at the branch portion where the medal return passage 62 branches from the medal passage 61 and the medal sensor 65 provided in the middle of the medal passage 61 and downstream of the medal selector 63 are provided.
(Medal passage 61)
The medal passage 61 is for guiding a medal inserted into the medal insertion slot 41 in a certain direction.

  As shown in FIG. 3, one end of the medal passage 61 communicates with the medal insertion port 41. Although not shown, the other end of the medal passage 61 is located above the medal tank. Further, the medal insertion port 41 side of the medal passage 61 is the upstream side, and the medal tank side of the medal passage 61 is the downstream side. The medal passage 61 is formed such that the height gradually decreases from the medal insertion port 41 side toward the medal tank side, that is, from the upstream side toward the downstream side. Thereby, the medal passage 61 guides the medal inserted into the medal insertion port 41 in a certain direction from the upstream side toward the downstream side. Further, the medal passage 61 is formed in an almost L shape by bending in the middle, and the vertical portion 61a that goes vertically downward from the medal insertion port 41 is compared with the lower end of the vertical portion 61a obliquely downward. A gently inclined portion 61b that is gently inclined, and a bent portion 61c that smoothly connects the vertical portion 61a and the gently inclined portion 61b. The medal return passage 62 is branched from the middle of the gentle slope portion 61b of the medal passage 61, and the medal selector 63 and the medal sensor 65 are provided at predetermined positions of the gentle slope portion 61b of the medal passage 61. Yes. In addition, in the gently sloping portion 61b of the medal passage 61, the medal flow speed is relatively slow. In the present embodiment, even if the medal is inserted so as to be pushed into the medal passage 61 from the medal insertion port 41 vigorously, the smoothly bent portion 61c and the subsequent gently inclined portion 61b The flow rate of medals falls within a predetermined range suitable for medal detection by the medal sensor 63. As described above, the bent portion 61c and the gently inclined portion 61b are provided in a part of the medal passage 61 so that the medal flows down at a relatively slow speed in the gently inclined portion 61b, and the medal selector is connected to the gently inclined portion 61b. By providing 63 and the medal sensor 65, it is possible to surely select medals with the medal selector 63 and detect medals with the medal sensor 65, and further, it is possible to perform control for preventing an illegal act described later. .

(Medal return passage 62)
The medal return passage 62 is a passage that branches from the middle of the medal passage 61.
As shown in FIG. 3, one end of the medal return passage 62 communicates with the medal passage 61. Although not shown, the other end of the medal return passage 62 is located above the medal return port 33. Further, the medal return passage 62 extends vertically downward from the middle of the gently inclined portion 61b of the medal passage 61. Thereby, the medal guided from the medal passage 61 to the medal return passage 62 is guided downward by its own weight and discharged from the medal return port 33.
(Medal selector 63)
The medal selector 63 selects non-standard medals and guides them to the medal return passage 62, and guides medals inserted from the medal insertion port 41 to the medal return passage 62 when the medal insertion is disabled. belongs to.

As shown in FIG. 3, the medal selector 63 is provided at a branch portion where the medal return path 62 branches from the medal path 61.
The medal selector 63 guides a medal that conforms to the standard to the downstream side of the branch portion of the medal passage 61, and guides a medal that is out of the standard to the medal return passage 62. In other words, the medal selector 63 sets the course of medals that conforms to the standard to the downstream side of the branch portion of the medal path 61, and sets the path of the non-standard medals to the medal return path 62.
All medals inserted into the medal insertion slot 41 reach the medal selector 63. Medals that conform to the standard are guided downstream from the branch of the medal passage 61 by the medal selector 63 and further flow down the medal passage 61, but non-standard medals are guided to the medal return passage 62 by the medal selector 63. Is done. Then, the medal guided to the medal return passage 62 flows down the medal return passage 62 by its own weight and is discharged from the medal return port 33.

More specifically, as shown in FIG. 4, the medal passage 61 is not only inclined obliquely downward from the upstream side to the downstream side, but is inclined so that the upper edge is inclined forward of the gaming machine 10. ing. Thereby, the medal flows down the medal passage 61 from the upstream side toward the downstream side with the upper side inclined to the front of the gaming machine 10. In addition, the medal selector 63 includes an upper engagement collar 63a that engages with the upper edge of the medal that conforms to the standard, a lower engagement collar 63b that engages with the lower edge of the medal, and an upper engagement. There is a dropout opening 63c formed between the hook part 63a and the lower engagement hook part 63b for dropping off a non-standard medal.
Of the medals that have been inserted into the medal insertion slot 41, passed through the medal passage 61, and reached the medal selector 63, the medal that conforms to the standard is engaged with the upper engagement hook 63a at the upper edge thereof, The lower edge engages with the lower engagement collar 63b, so that it passes through the medal selector 63 without dropping from the drop opening 63c, and is guided downstream from the branch portion of the medal passage 61. The On the other hand, the medal whose diameter is smaller than the standard is not engaged with the upper engaging collar 63a at the upper edge thereof, so that the medal is dropped from the drop opening 63c and guided to the medal return passage 62.

Further, the medal selector 63 includes a path switching mechanism for switching the path of medals that conforms to the standard to either the medal tank direction or the medal return path 62 direction.
In addition, when the path switching mechanism is set to allow the medal insertion, the path of the medal inserted from the medal insertion port 41 is set to the downstream side of the branch portion of the medal path 61 while the medal insertion is disabled. When the medals are inserted, the path of medals inserted from the medal insertion slot 41 is switched to the medal return path 62 direction. In other words, when the medal insertion mechanism is set to allow medal insertion, the medal inserted from the medal insertion port 41 is guided downstream from the branch portion of the medal passage 61, and the medal insertion is disabled. When there is, the medal inserted from the medal slot 41 is guided to the medal return passage 62.

All medals inserted into the medal insertion slot 41 reach the medal selector 63. The medal inserted into the medal insertion slot 41 when the medal insertion is set is guided to the downstream side of the branch portion of the medal passage 61 by the route switching mechanism provided in the medal selector 63, and further passed through the medal passage 61. The medal inserted into the medal slot 41 when it is set to be unable to insert a medal, even if it conforms to the standard, is moved to the medal return path 62 by the course switching mechanism provided in the medal selector 63. Be guided. Then, the medal guided to the medal return passage 62 flows down the medal return passage 62 by its own weight and is discharged from the medal return port 33.
More specifically, as shown in FIG. 4, the path switching mechanism includes a swing arm 63d having a substantially L-shaped cross section, a spring 63e that biases the swing arm 63d in a predetermined direction, and an attachment of the spring 63e. The cancel coil 63f moves the swing arm 63d against the force.

Further, the upper piece of the swing arm 63d is pivotally supported so that the upper end of the swing arm 63d can be rotated, and the lower piece of the swing arm 63d constitutes a part of the lower edge of the medal passage 61. ing.
When the cancel coil 63f is energized, as shown in FIG. 4A, the iron core of the cancel coil 63f attracts the upper piece of the swing arm 63d against the urging force of the spring 63e. In the state where the upper piece of the swing arm 63d is attracted to and contacted the iron core of the cancel coil 63f, the distance between the upper edge and the lower edge of the medal passage 61 is larger than the diameter of the medal conforming to the standard. Is slightly larger. As a result, the medal conforming to the standard has its upper edge engaged with the upper engagement collar 63a, and its lower edge engaged with the lower engagement collar 63b, so that the dropout opening 63c Pass through the medal selector 63 without dropping off.

On the other hand, when the cancel coil 63f is not energized, as shown in FIG. 4B, the upper piece of the swing arm 63d is biased by the spring 63e without being attracted to the iron core of the cancel coil 63f. When the upper piece of the swing arm 63d is separated from the iron core of the cancel coil 63f and is urged by the spring 63e, the distance between the upper edge and the lower edge of the medal path 61 conforms to the standard. The size is sufficiently larger than the diameter of the medal. As a result, even if a medal conforms to the standard, the upper edge thereof does not engage with the upper engaging collar 63a, and is thereby dropped from the dropout opening 63c and guided to the medal return passage 62.
Here, in the gaming machine 10 according to the present embodiment, the medal can not be inserted from the operation of the start switch 43 until the game started by the operation of the start switch 43 ends. The medal can be inserted until the start switch 43 is operated after the game is finished.

Then, the path switching mechanism energizes the cancel coil 63f when the medal insertion is enabled. As a result, the swing arm 63d is attracted against the urging force of the spring 63e to obtain the state shown in FIG. Then, a medal that conforms to the standard has its upper edge engaged with the upper engagement collar 63a, and its lower edge engaged with the lower engagement collar 63b, from the dropout opening 63c. Pass the medal selector 63 without dropping out.
On the other hand, the path switching mechanism does not energize the cancel coil 63f when the medal insertion is disabled. Thus, the swing arm 63d is urged by the spring 63e, and the state shown in FIG. Then, even if the medal conforms to the standard, the upper edge thereof does not engage with the upper engaging collar 63a, and thus the medal is dropped from the dropout opening 63c and guided to the medal return passage 62.

(Medal sensor 65)
The medal sensor 65 is provided in the middle of the medal passage 61, and detects the passage of medals and outputs a medal detection signal.
As shown in FIG. 3, in the present embodiment, the medal sensor 65 is composed of two photosensors provided in parallel along the direction of travel of the medal. The first photo sensor 66 is provided on the upstream side of the medal passage 61, and the second photo sensor 67 is provided on the downstream side.
The first photo sensor 66 is provided at a predetermined position downstream of the medal selector 63 in the middle of the medal passage 61.

The second photosensor 67 is provided at a predetermined position downstream of the first photosensor 66 in the middle of the medal passage 61.
The first photosensor 66 includes a light emitting unit that emits light and a light receiving unit that receives light emitted from the light emitting unit. The first photo sensor 66 is provided at a predetermined position in the middle of the medal path 61 so that the medal path 61 is sandwiched between the light emitting unit and the light receiving unit. The medal passing through the medal passage 61 passes between the light emitting unit and the light receiving unit of the first photosensor 66. Accordingly, the first photo sensor 66 is configured to block the optical path from the light emitting unit to the light receiving unit by the medal passing through the medal passage 61.

Further, the first photo sensor 66 continues to output a Hi level signal from the output terminal when the light emitted from the light emitting part reaches the light receiving part without being interrupted in the middle, while being emitted from the light emitting part. When the received light is blocked on the way and does not reach the light receiving unit, the Lo level signal is continuously output from the output terminal.
That is, when the light receiving unit detects light emitted from the light emitting unit, the first photosensor 66 continues to output a Hi level signal from the output terminal, while the light emitted from the light emitting unit is received by the light receiving unit. Is not detected, the Lo level signal is continuously output from the output terminal.
Further, the first photo sensor 66 is formed so as to be able to stop the light emission of the light emitting part while allowing the light detection by the light receiving part.

In addition, “it is possible to stop the light emission of the light emitting unit” means that the light of the light emitting unit can be turned off. In other words, the light emitting unit can be turned off or the function of the light emitting unit can be turned off. This means that it can be turned off.
In addition, “It is possible to stop the light emission of the light emitting part while making the light detection by the light receiving part possible” means that the light of the light emitting part can be turned off while the light receiving part continues to detect the light. In other words, it is possible to stop the function of the light emitting unit while keeping the function of the light receiving unit, or to turn off the function of the light emitting unit while keeping the function of the light receiving unit ON. Means that it is possible.

Thus, even when the first photosensor 66 stops the light emission of the light emitting unit, when the light receiving unit detects light of the same quality as the light emitted by the light emitting unit, the first photosensor 66 outputs a Hi level signal from the output terminal. The Hi level signal is continuously output from the output terminal while the light receiving unit detects light of the same quality as the light emitted from the light emitting unit.
Similarly to the first photosensor 66, the second photosensor 67 also includes a light emitting portion and a light receiving portion, and the optical path from the light emitting portion to the light receiving portion is blocked by a medal passing through the medal passage 61. Furthermore, when the light emitted from the light emitting part reaches the light receiving part without being interrupted, the Hi level signal is continuously output from the output terminal, while the light emitted from the light emitting part is halfway. When it is blocked by and does not reach the light receiving section, it continues to output a Lo level signal from the output terminal.

However, in the present embodiment, the second photosensor 67 cannot stop the light emission of the light emitting unit while allowing the light receiving unit to detect the light. In other words, in the present embodiment, the second photosensor 67 has the function of the light receiving unit turned on when the function of the light emitting unit is turned on, and the function of the light receiving unit when the function of the light emitting unit is turned off. Is also turned off.
In the present embodiment, the optical path from the light emitting unit to the light receiving unit of the first photosensor 66 and the optical path from the light emitting unit to the light receiving unit of the second photosensor 67 are based on one medal passing through the medal path 61. It can be blocked at the same time.
Here, an optical path from the light emitting unit to the light receiving unit of the first photosensor 66 is referred to as a “first optical path”, and an optical path from the light emitting unit to the light receiving unit of the second photosensor 67 is referred to as a “second optical path”.

  In the present embodiment, the first photo sensor 66 and the second photo sensor 67 are arranged by shifting the positions of the first optical path and the second optical path from the position where the center of the medal in the medal path 61 passes. Thus, for example, even when three medals are continuously inserted from the medal insertion slot 41 and these three medals continuously flow down the medal passage 61, one inserted medal is inserted. Therefore, it is possible to correctly detect that the number is three without misidentifying that the number is. In other words, since the medals are circular, when the positions of the first optical path and the second optical path coincide with the positions through which the centers of the medals pass, when a plurality of medals continuously flow down the medal path 61, Although the first optical path and the second optical path remain blocked, and it is mistaken that there is only one inserted medal, the positions of the first optical path and the second optical path from the position where the center of the medal passes. By shifting, even if a plurality of medals flow continuously through the medal passage 61, the first optical path and the second optical path do not remain blocked, and it can be correctly detected that there are a plurality of medals. is there.

In the present embodiment, the first photosensor 66 and the second optical path are arranged such that the distance between the first optical path and the second optical path is smaller than the width of the medal at a position where the first optical path and the second optical path are present. 2 photo sensors 67 are arranged. The first optical path and the second optical path can be simultaneously blocked by one medal passing through the medal path 61.
In the present embodiment, the medal guided downward in the medal path 61 starts to block the first optical path, and then starts to block the second optical path while continuing to block the first optical path. In the meantime, both the first optical path and the second optical path continue to be blocked, and then the first optical path is completely blocked, but the second optical path is continuously blocked, and then the second optical path is completely blocked.

Further, the black circles in FIG. 5 indicate the optical center 68, that is, the positions of the first optical path and the second optical path.
Further, the medal in FIG. 5A is at a position where the first optical path has started to be blocked, and the medal in FIG. 5B starts to block the second optical path while continuing to block the first optical path. Further, the medal in FIG. 5C is in a position where the first optical path has been blocked while continuing to block the second optical path, and the medal in FIG. It is in the position where the two light paths have been blocked.
In the present embodiment, the medal guided downward in the medal path 61 includes a state before the first optical path and the second optical path are blocked, a state before the first optical path is blocked and the second optical path is blocked, A state where both the first optical path and the second optical path are blocked, a state where the first optical path is blocked and the second optical path is blocked, and a state where both the first optical path and the second optical path are blocked are created.

  In the present embodiment, the medal inserted into the medal slot 41 flows down the medal passage 61 at a speed of about 300 mm / sec. In the present embodiment, the distance between the first optical path and the second optical path is 6 mm. For this reason, in the present embodiment, the time required for the medal inserted into the medal insertion slot 41 to move from the position where it starts to block the first optical path to the position where it starts to block the second optical path is about 20 milliseconds. is there. In this embodiment, the control device 100 monitors the first photosensor 66 and the second photosensor 67 at intervals of 1 millisecond. That is, the control device 100 checks whether the signal output from each output terminal of the first photosensor 66 and the second photosensor 67 is a Hi level signal or a Lo level signal every 1 millisecond. is doing. The result of this check is reflected in medal detection processing, abnormality determination processing, and the like.

In the present embodiment, Lo level signals output from the output terminals of the first photosensor 66 and the second photosensor 67 are used as medal detection signals.
The medals that have passed through the first photo sensor 66 and the second photo sensor 67 further flow down the medal passage 61 and are stored in the medal tank of the hopper unit 70.
(Light emission control means 150)
The light emission control means 150 is for controlling light emission of the light emitting unit.
In the present embodiment, the light emission control unit 150 controls the light emission of the light emitting unit of the first photosensor 66. That is, the light emission control unit 150 causes the light emitting unit of the first photosensor 66 to emit light or stops light emission.

Further, in the present embodiment, the light emission control means 150 stops the light emission of the first photosensor 66 in the medal insertion waiting state.
The “medal insertion waiting state” means a state waiting for a medal to be inserted into the medal insertion slot 41.
In the present embodiment, the light emission control means 150 emits light within a predetermined time if the light receiving unit of the second photosensor 67 stops detecting light when the light emission of the first photosensor 66 is stopped. The light emitting portion of the first photo sensor 66 that has stopped the light is emitted.
In the present embodiment, the “predetermined time” is the time from when the medal guided downward in the medal passage 61 starts to block the second optical path until it completes blocking the first optical path.

That is, in the present embodiment, the duration of the state where the medal guided downward through the medal path 61 blocks both the first optical path and the second optical path is a predetermined time.
In the present embodiment, once the light emission control unit 150 emits light from the first photo sensor 66, the light emission unit of the first photo sensor 66 continues to emit light until the medal one count process is completed. In addition, when the medal one count process is finished, a medal insertion waiting state is entered. Then, the light emission control unit 150 stops the light emission of the light emitting unit of the first photosensor 66.
(Abnormality determination means 160)
The abnormality determining means 160 is for determining that an abnormality is detected when the light receiving section corresponding to the light emitting section detects light when the light emission control section 150 stops light emission.

In the present embodiment, the abnormality determination unit 160 detects an abnormality when the light receiving unit of the first photosensor 66 detects light while the light emission control unit 150 stops light emission of the first photosensor 66. judge.
That is, when the light emission of the light emitting part of the first photosensor 66 is stopped, the light receiving part of the first photosensor 66 should not detect light normally, and the light receiving part of the first photosensor 66 is light. Is detected, it is abnormal. Then, when the light emitting unit of the first photosensor 66 is stopped from emitting light, the abnormality determination unit 160 performs an illegal act using an unauthorized instrument when the light receiving unit of the first photosensor 66 detects light. It is determined as abnormal.

More specifically, in the present embodiment, when the light emission of the light emitting unit of the first photosensor 66 is stopped, a Lo level signal should continue to be output from the output terminal of the first photosensor 66. If a Hi level signal is output, it is abnormal. Then, the abnormality determination means 160, when a Hi level signal is output from the output terminal of the first photosensor 66 when the light emitting portion of the first photosensor 66 is stopped, the first photosensor 66. If the light receiving unit detects light, and it is determined that an illegal act using a fraudulent instrument is being performed, it is determined as abnormal.
In the present embodiment, the abnormality determination unit 160 causes the light receiving unit of the first photosensor 66 to emit light when the light emission control unit 150 causes the light emitting unit of the first photosensor 66 that has stopped emitting light to emit light. If detected, it is determined as abnormal.

  That is, in the present embodiment, when the medal guided downward in the medal path 61 starts to block the second optical path, the first optical path should also be blocked. Further, if the medal guided downward through the medal passage 61 blocks the second optical path, the light emission control unit 150 detects that the light receiving unit of the second photosensor 67 does not detect light. The light emitting unit emits light. At this time, since the medal should be before the first optical path is blocked, the light receiving unit of the first photosensor 66 should not detect light. At this time, the first photosensor If the light receiving part 66 detects light, it is abnormal. Then, when the light-emitting unit of the first photosensor 66 emits light and the light-receiving unit of the first photosensor 66 detects light, the abnormality determination unit 160 causes the medal with the thread tied up the medal path 61. It is determined to be abnormal, for example, because it is being directed toward.

  More specifically, in the present embodiment, when a medal guided downward through the medal path 61 blocks the second optical path, the signal output from the output terminal of the second photosensor 67 changes from the Hi level to Lo. When the level is reached, the light emission control means 150 causes the light emitting portion of the first photosensor 66 to emit light. At this time, the medal should be before the first optical path is blocked, so the output terminal of the first photosensor 66 From this point, a Lo level signal should continue to be output, and if a Hi level signal is output, it is abnormal. Then, when the Hi-level signal is output from the output terminal of the first photosensor 66 when the light emitting unit of the first photosensor 66 emits light, the abnormality determination unit 160 causes the light receiving unit of the first photosensor 66 to Assuming that light is detected, it is determined that there is an abnormality, for example, because a medal with a thread tied is guided upward in the medal passage 61.

In the present embodiment, the abnormality determining means 160 outputs an abnormality detection signal when it is determined as abnormal. In this embodiment, based on the abnormality detection signal, the abnormality notification unit 165 sounds an alarm sound from the speaker 36 or flashes the lamp 35 to notify the abnormality, or the game control unit 110 Or the payout control means stops the driving of the hopper unit 70.
(Medal counting means 170)
The medal counting means 170 is for counting the number of medals based on the medal detection signal.

When a medal inserted into the medal insertion slot 41 flows down the medal passage 61, passes through the medal selector 63 and the medal canceller 64, and passes through the medal sensor 65, a medal detection signal is output. At this time, a medal detection signal having a pattern as shown in FIG. 6 is output. Then, the medal counting means 170 performs a counting operation. Specifically, the medal count unit 170 adds one count value each time a medal detection signal having a pattern as shown in FIG. 6 is output once. In this way, the number of medals inserted into the medal insertion slot 41 is counted.
In addition, an upper limit value is set for the count value of the medal counting means 170. In the present embodiment, the upper limit value of the count value of the medal counting means 170 is set to “3”. In other words, the upper limit value of the count value of the medal counting means 170 is the maximum number that can be inserted per game.

When the count value of the medal counting unit 170 reaches “3”, medals inserted from the medal insertion port 41 thereafter are counted by the credit medal counting unit 180. That is, when four or more medals are inserted into the medal insertion slot 41, the fourth and subsequent medals are counted as credits by the credit medal counting means 180.
(Credit medal counting means 180)
The credit medal counting means 180 is for counting the number of medals that are credited.
In the present embodiment, the maximum number of medals inserted is 3 per game. Therefore, when four or more medals are inserted into the medal insertion slot 41, the fourth and subsequent medals are counted as credits by the credit medal counting means 180.

The medal count is the same as that of the medal counting means 170. That is, when a medal inserted into the medal insertion slot 41 passes the medal sensor 65, a medal detection signal having a pattern as shown in FIG. 6 is output. Each time a medal detection signal having a pattern as shown in FIG. 6 is output once, the credit medal counting means 180 adds one count value.
In the present embodiment, the maximum number of medal credits is 50. For this reason, when the count value of the medal count means 170 reaches “3” and the count value of the credit medal count means 180 reaches “50”, the medal insertion is disabled, and the path switching mechanism of the medal selector 63 is activated. By switching the direction of the medals in the direction of the medal return passage 62, medals that are subsequently inserted into the medal insertion port 41 are guided to the medal return passage 62 and discharged from the medal return port 33.

Further, in this embodiment, credit may be given instead of paying out medals, and in this case, the credit medal counting means 180 adds the count value by the amount replaced with credit.
In the present embodiment, the bet switch 42 can be operated to reduce the number of credited medals and replace it with the insertion of medals. In this case, the credit medal counting means 180 is used for the insertion of medals. The count value is subtracted by the replaced amount.
(Game control means 110)
The game control means 110 is for controlling a game.

Hereinafter, the game in the present embodiment will be described.
When medals are inserted, the number of winning lines corresponding to the number of medals inserted becomes valid. Specifically, the maximum number of inserted medals is 3 per game. When the number of inserted medals is 1, only the first pay line is valid, and the number of inserted medals is When there are two, the three pay lines from the first to the third are valid, and when the number of medals is three, all the five pay lines from the first to the fifth are valid. Become.
The medal can be inserted into a medal from the medal slot 41 and a medal that has been credited. In addition, insertion of a credited medal is performed by operating the bet switch.

Further, when the start switch 43 is operated on condition that a medal is inserted, a start signal is output. In addition, triggered by the input of the start signal, a lottery (winning lottery) of whether one of a plurality of winning combinations is won or lost is performed, and rotation of all three rotating reels 51 is started. In the winning lottery, the winning probability of the winning combination is changed according to the number of inserted medals.
Thereafter, when one of the three stop switches 44 is operated, the rotation of the rotary reel 51 corresponding to the stop switch 44 is stopped. When all the three stop switches 44 are operated, the rotation of all the three rotary reels 51 is stopped. At this time, when predetermined symbols are arranged in a predetermined arrangement on an effective winning line, a predetermined winning combination is won, and the number of medals corresponding to the winning mode is paid out. The medal payout includes a medal payout from the medal payout opening 32 and a medal payout by credit. In addition, instead of paying out medals or along with paying out medals, a predetermined profit may be given to the player.

In addition, the prize includes a big bonus prize (BB prize) related to the transition to the big bonus game (BB game), a regular bonus prize (RB prize) related to the transition to the regular bonus game (RB game), and a predetermined number (For example, 12) Bell prize for paying out medals, watermelon prize for paying out fewer medals (for example, 8) than medal, and less than watermelon (for example, 2 or 4) There are a cherry prize related to the payout of the medal and a replay prize related to the execution of the replay.
(Role lottery means 120)
The role lottery means 120 is for performing a lottery (role lottery) of winning or losing one of a plurality of roles.

In the present embodiment, the result of the role lottery includes the big bonus winning (BB winning) related to the allocation of the BB winning, the regular bonus winning (RB winning) relating to the allocation of the RB winning, and the bell related to the allocation of the Bell winning. There are a winner, a watermelon winner relating to the allocation of a watermelon winner, a cherry winner relating to the allocation of a cherry winner, a replay winner relating to the allocation of a replay winner, and a loss.
Further, although not shown, the role lottery means 120 includes a random number generation means, a random number extraction means, a role lottery table, and a role lottery determination means.
The random number generation means is for generating a random number for winning lottery within a predetermined range (for example, 0 to 16383 in decimal number).

The random number generation means can be constituted by, for example, an oscillation circuit and a counter circuit that counts clock signals generated by the oscillation circuit (so-called hard random number).
Further, the random number generating means can be constituted by means for generating random numbers by the average sampling method, or means for generating random numbers by adding prime numbers, for example. Further, these means can be configured, for example, by causing a CPU to execute a predetermined program (so-called soft random number).
The random number extraction means is for extracting a random number generated by the random number generation means with a predetermined trigger (for example, operation of the start switch 43).

Since the random number generating means is constituted by a counter circuit or the like, the numerical value generated by the random number generating means is not strictly a random number. However, since the timing at which the start switch 43 is operated is considered to be random, the numerical value extracted by the random number extraction means can be practically handled as a random number.
In addition, in the role lottery table, for each random number within the range generated by the random number generating means, BB winning, RB winning, bell winning, watermelon winning, cherry winning, Whether to win the replay or lose is predetermined.
In addition, the combination lottery table includes a one-unit combination lottery table used when the number of inserted medals is one, a two-unit combination lottery table used when the number of inserted medals is two, and the number of inserted medals. A three-piece winning lottery table used for three is provided. That is, the winning lottery table is provided for each inserted number of medals. The single winning lottery table determines the winning probability of the winning combination with a predetermined probability. The double winning lottery table determines the winning probability of the winning combination with a predetermined probability higher than that of the single winning lottery table. The winning combination lottery table defines the winning probability of winning with a predetermined probability higher than that of the double winning lottery table. As a result, the winning probability of the combination varies depending on the number of inserted medals.

The role lottery determination means is for comparing the random number extracted by the random number extraction means with the role lottery table to determine the lottery result.
In addition, the role lottery determination means collates the random number extracted by the random number extraction means with the role lottery table, and determines whether it is BB winning, RB winning, Bell winning, watermelon winning, cherry winning, replay winning, Alternatively, it is determined whether or not it is lost.
(Stop table)
The stop table is for determining the stop position of each rotary reel 51, and the sliding table of each rotary reel 51 is determined according to the rotation position of the corresponding rotary reel 51 when each stop switch 44 is operated. The number is predetermined.

Further, in the present embodiment, a plurality of types of stop tables are provided corresponding to the lottery results of the combination lottery means 120 and the like.
In the present embodiment, each stop table defines the number of sliding symbols of each rotary reel 51 within a range of 0 to 4.
In addition, the stop table corresponding to any of the combinations is such that three symbols corresponding to the combination can be arranged on any effective winning line, and any effective winning combination is made for the symbols other than the combination. The number of sliding frames of each rotating reel 51 is determined so that three are not arranged on the line.
Specifically, for example, in the stop table corresponding to “BB winning”, three symbols “7” can be arranged on any valid winning line, and symbols other than “7” The number of sliding frames of each rotary reel 51 is determined so that three are not arranged on any valid winning line. As a result, the stop table corresponding to the “BB prize” can accept a BB prize and cannot accept a prize other than the BB prize. The same applies to the stop tables corresponding to “RB winning”, “Bel winning”, “Watermelon winning” and “Replay winning”.

Further, for example, the stop table corresponding to “cherry winning” is such that the symbol “cherry” attached to the left rotating reel 51 stops on any valid winning line, and “cherry” For the other symbols, the number of sliding symbols of each rotary reel 51 is determined so that three symbols are not arranged on any valid winning line. As a result, the stop table corresponding to the “cherry prize” can receive a cherry prize and cannot receive a prize other than the cherry prize.
In addition, the stop table corresponding to “no win” has a “cherry” attached to the left rotating reel 51 so that three symbols of the same type are not arranged on any valid pay line. The number of sliding symbols of each rotary reel 51 is determined so that the symbol does not stop on any valid winning line.

(Stop control means 130)
The stop control means 130 is for performing stop control of each rotary reel 51.
Further, the stop control means 130 performs stop control of each rotary reel 51 based on the stop table and the rotation position of the corresponding rotary reel 51 when each stop switch 44 is operated.
Further, the stop control of each rotary reel 51 is performed as follows.
First, one stop table is selected from among a plurality of stop tables based on the result of the winning lottery. For example, when the result of the lottery is “Bell Winning”, the stop table corresponding to “Bell Winning” is selected, and when the result of the role lottery is “BB Winning”, “BB Winning” The corresponding stop table is selected.

Next, the number of sliding symbols of each rotary reel 51 is determined from the selected one stop table and the rotation position of the corresponding rotary reel 51 when each stop switch 44 is operated.
Here, when the number of sliding symbols is determined to be “0”, the stop control means 130 uses the symbol located immediately before the upper part of the symbol see-through window 31 when the stop switch 44 is operated as the upper part of the symbol see-through window 31. Thus, the rotation of the rotary reel 51 is stopped.
When the number of sliding symbols is determined to be “1”, the stop control means 130 moves the symbol located immediately before the upper stage of the symbol see-through window 31 when the stop switch 44 is operated in the rotation direction of the rotary reel 51. The rotation of the rotary reel 51 is stopped by moving it so that it slides one frame and stopping it at the middle stage of the symbol see-through window 31.

When the number of sliding symbols is determined to be “2”, the stop control means 130 moves the symbol located immediately before the upper stage of the symbol see-through window 31 when the stop switch 44 is operated in the rotation direction of the rotary reel 51. The rotation of the rotary reel 51 is stopped by moving it so that it slides two frames and stopping it at the lower stage of the symbol see-through window 31.
Note that the stop control of the rotating reel 51 as described above is a control using a stop table, and is therefore called “table control” or the like.
(Winning determination means 140)
The winning determination means 140 is used to determine whether or not there is a winning combination based on the symbol arrangement on each winning line when the rotation of all the rotating reels 51 is stopped. It is.

Further, the winning determination means 140 determines that a predetermined winning combination has been won if a predetermined symbol is aligned in a predetermined arrangement on any effective winning line when the rotation of all the rotary reels 51 is stopped. .
Specifically, the winning determination means 140 determines “BB winning” when all of the symbols “7” are aligned on any valid winning line when the rotation of all the rotating reels 51 is stopped. To do.
Further, the winning determination means 140 determines “RB winning” when all of the “BAR” symbols are aligned on any valid winning line when the rotation of all the rotating reels 51 is stopped.
Further, the winning determination means 140 determines “bell winning” when three “bell” symbols are aligned on any valid winning line when the rotation of all the rotating reels 51 is stopped.

Further, the winning determination means 140 determines “watermelon winning” when three “watermelon” symbols are arranged on any valid winning line when the rotation of all the rotary reels 51 is stopped.
In addition, the winning determination means 140, when the rotation of all the rotating reels 51 is stopped, when the symbol “cherry” attached to the left rotating reel 51 stops on any valid winning line, Regardless of the stop position of the symbols attached to the rotating reel 51 and the right rotating reel 51, it is determined that the cherry prize is won.
Further, the winning determination means 140 determines “replay winning” when all three “R” symbols are aligned on any valid winning line when the rotation of all the rotating reels 51 is stopped.

In addition, the winning determination means 140 is attached to the left rotating reel 51 when all of the rotating reels 51 are stopped and the same type of three symbols are not arranged on any effective winning line. If the “Cherry” symbol is not stopped on any valid winning line, it is determined that there is no winning.
(Medal detection signal)
The medal detection signal in the present embodiment will be described based on the time chart shown in FIG.
In the medal insertion waiting state, a Lo level signal is normally output from the output terminal of the first photosensor 66 and a Hi level signal is continuously output from the output terminal of the second photosensor 67 (in FIG. 6). Before a).

In the present embodiment, until the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level, the light emission of the light emitting portion of the first photosensor 66 is stopped. Even when the flowing medal starts to block the first optical path, a Lo level signal is normally output from the output terminal of the first photosensor 66 and a Hi level signal is output from the output terminal of the second photosensor 67. The output continues (a in FIG. 6). This state normally continues until just before the medal flowing down the medal passage 61 blocks the second optical path (between a and b in FIG. 6).
When a medal flowing down the medal passage 61 begins to block the second optical path, the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level. Then, the light emission control unit 150 causes the light emitting unit of the first photosensor 66 to emit light. At this time, since the medal is usually before the first optical path has been blocked, the Lo-level signal continues to be output from the output terminal of the first photosensor 66 (b in FIG. 6). This state continues until just before the medal flowing down the medal passage 61 finishes blocking the first optical path (between bc in FIG. 6).

When the medal flowing down the medal passage 61 finishes blocking the first optical path, the signal output from the output terminal of the first photosensor 66 changes from the Lo level to the Hi level. At this time, since the medal is usually before the second optical path has been blocked, the Lo-level signal continues to be output from the output terminal of the second photosensor 67 (c in FIG. 6). This state continues until immediately before the medal flowing down the medal passage 61 finishes blocking the second optical path (between cd in FIG. 6).
When the medal flowing down the medal passage 61 finishes blocking the second optical path, the signal output from the output terminal of the second photosensor 67 changes from the Lo level to the Hi level. At this time, since the medal is usually after blocking the first optical path, a Hi level signal continues to be output from the output terminal of the first photosensor 66 (d in FIG. 6). This state continues until the medal one count process is completed (after d in FIG. 6).

If a medal detection signal with a pattern other than that shown in FIG. 6 is output, it is abnormal, and the abnormality determining means 160 determines that it is abnormal.
(Medal detection process)
The medal detection process in the present embodiment will be described based on the flowcharts shown in FIGS.
In the present embodiment, in the waiting state for inserting a medal, the light receiving unit of the second photosensor 67 stops detecting light by stopping the light emission of the light emitting unit of the first photosensor 66 and inserting the medal. The light emitting part of the first photo sensor 66 is made to emit light.

  In step 100, the medal can be inserted. As described above, in the gaming machine 10 according to the present embodiment, a medal can be inserted after one game is completed until the start switch 43 is operated next time. In addition, when the medal can be inserted, energization to the cancel coil 63f is started. Then, the iron core of the cancel coil 63f pulls the upper piece of the swing arm 63d against the urging force of the spring 63e. As a result, the state shown in FIG. That is, the path of medals inserted from the medal insertion slot 41 is in the downstream direction with respect to the branch portion of the medal path 61. Then, the medal inserted from the medal insertion slot 41 passes through the medal selector 63 and the medal sensor 65 and reaches the medal tank of the hopper unit 70. When the medal insertion is set to be possible, the medal sensor 65 can detect the medal. In addition, from the time when the medal insertion is permitted until the medal is inserted, there is a waiting state for medal insertion. Then, when the medal insertion is permitted, the process proceeds to step 101.

In step 101, the light emission of the light emitting unit of the first photosensor 66 is stopped. Then, the process proceeds to Step 102.
In step 102, 0 is set in the medal passage limit time detection timer TM. Here, the medal passage limit time detection timer TM confirms that the medal flowing down the medal passage 61 is passing through the first photosensor 66 and the second photosensor 67, and the first photo within a predetermined time. This is for confirming whether the sensor 66 and the second photosensor 67 pass. Here, the fact that 0 is set in the medal passage limit time detection timer TM means that the medal is not passing through the medal passage 61. When 0 is set in the medal passage limit time detection timer TM, the process proceeds to step 103.

  In step 103, after waiting for a certain period of time, it is confirmed whether the signals output from the output terminals of the first photosensor 66 and the second photosensor 67 are Hi level or Lo level. To be compared. Specifically, in the RAM of the control device 100, the previous output information storage area for storing information related to the output before waiting for a predetermined time, and the current output for storing information related to the output after waiting for the predetermined time And an information storage area. Then, the control device 100 first moves information related to the output stored in the current output information storage area to the previous output information storage area, then waits for a certain time, and then waits for the first photo sensor 66. And the signal output from the output terminal of the second photosensor 67 is confirmed, and the information related to the output signal is stored in the current output information storage area. For each of the first photosensor 66 and the second photosensor 67, if the output signal is at the Hi level, information indicating that it is at the Hi level is stored, and the output signal is at the Lo level. If there is, information indicating the Lo level is stored. Then, the control device 100 compares the information stored in the previous output information storage area with the information stored in the current output information storage area. As a result, before and after waiting for a certain time, whether the signal output from the output terminal of the first photosensor 66 does not change at the Hi level, changes from the Hi level to the Lo level, or does not change at the Lo level. Or, it can be seen whether the Lo level has changed to the Hi level. Similarly, whether the signal output from the output terminal of the second photosensor 67 remains at the Hi level, changes from the Hi level to the Lo level, or remains at the Lo level before and after waiting for a certain time. Or, it can be seen whether the Lo level has changed to the Hi level. Then, the process proceeds to Step 104.

  In step 104, it is determined whether or not the signal output from the output terminal of the first photosensor 66 is at the Lo level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is not at the Lo level (ie, at the Hi level), that is, the light receiving unit of the first photosensor 66 detects the light. If it is determined, the process proceeds to step 105. On the other hand, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Lo level, that is, when it is determined that the light receiving unit of the first photosensor 66 is not detecting light, Proceed to step 106.

  In step 105, abnormality determination processing is performed. Specifically, when the light emission of the light emitting unit of the first photosensor 66 is stopped, a Lo level signal should continue to be output from the output terminal, and when a Hi level signal is output, It is abnormal. That is, it is abnormal if the light receiving unit detects light when the light emission of the light emitting unit of the first photosensor 66 is stopped. Then, when the Hi-level signal is output from the output terminal when the light emitting unit of the first photosensor 66 is stopped, the abnormality determining unit 160 detects that the light receiving unit detects light. It is determined that there is an abnormality because an illegal act using an illegal instrument is being performed. Moreover, the abnormality determination means 160 outputs an abnormality detection signal when determining that there is an abnormality. Based on the abnormality detection signal, the abnormality notification unit 165 sounds an alarm sound from the speaker 36, flashes the lamp 35 to notify the abnormality, or the game control unit 110 stops the progress of the game. The payout control means stops the driving of the hopper unit 70. Then, the abnormality determination process ends.

  In step 106, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level before and after waiting for a predetermined time in Step 103. Further, the determination as to whether or not the change has occurred is made based on the result of the confirmation and comparison in step 103. If it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level, the process proceeds to step 107. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Hi level to the Lo level, the routine proceeds to step 121.

In step 107, the light emitting unit of the first photosensor 66 is caused to emit light, and a predetermined time is waited. In addition, since it takes a certain time to shift the light emitting unit of the first photosensor 66 from the extinguished state to the light emitting state, the signal output from the output terminal of the first photosensor 66 in the next step 108 is Lo level. In order to prevent malfunction from occurring in determining whether or not, it is decided to wait for a certain time here. Then, the process proceeds to Step 108.
In step 108, it is determined whether or not the signal output from the output terminal of the first photosensor 66 is at the Lo level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is not at the Lo level (ie, at the Hi level), that is, the light receiving unit of the first photosensor 66 detects the light. If it is determined, the process proceeds to step 109. On the other hand, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Lo level, that is, when it is determined that the light receiving unit of the first photosensor 66 is not detecting light, Proceed to step 110.

  In step 109, abnormality determination processing is performed. Specifically, when the medal guided downward in the medal path 61 blocks the second optical path, and the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level, the light emission control means 150 causes the light emitting portion of the first photosensor 66 to emit light. At this time, since the medal should be before the first optical path has been blocked, the Lo level signal should continue to be output from the output terminal of the first photosensor 66, and when the Hi level signal is output, It is abnormal. That is, at this time, since the medal should be before the first optical path has been blocked, the light receiving portion of the first photosensor 66 should not detect light, and it is abnormal when the light receiving portion detects light. Then, when a Hi level signal is output from the output terminal of the first photosensor 66 when the light emitting unit of the first photosensor 66 emits light, that is, when the light receiving unit detects light, the abnormality determining means 160 Determines that the medal with the thread tied is guided abnormally with the medal passage 61 directed upward. Further, the operation after the abnormality determination is as described above. Then, the abnormality determination process ends.

  In step 110, a predetermined value is set in the medal passage limit time detection timer TM. Here, a predetermined value being set in the medal passage limit time detection timer TM means that the medal is passing through the medal passage 61 and that it is within a predetermined time. is there. In the present embodiment, a predetermined and sufficient time is required for a medal that has started to block the second optical path to finish blocking the second optical path. That is, if there is a predetermined time set here, a medal that has started to block the second optical path should finish blocking the second optical path. Also, if it is within the predetermined time set here, the medal should be in the middle of blocking the second optical path. When a predetermined value is set in the medal passage limit time detection timer TM, the process proceeds to step 111.

In step 111, after waiting for a certain period of time, it is confirmed whether the signals output from the output terminals of the first photosensor 66 and the second photosensor 67 are Hi level or Lo level. To be compared. The confirmation and comparison operations are the same as in step 103. Further, the fixed time waiting in step 111 is approximately one unit time in the medal passage limit time detection timer TM. Then, the process proceeds to step 112.
In step 112, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level. Specifically, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level before and after waiting for a certain time in step 111. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 111. If it is determined that the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level, the process proceeds to step 113. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 has not changed from the Lo level to the Hi level, the process proceeds to step 115.

  In step 113, it is determined whether or not the signal output from the output terminal of the second photosensor 67 is at the Lo level. That is, it is determined whether or not the light receiving unit of the second photosensor 67 has detected light. Here, if it is determined that the signal output from the output terminal of the second photosensor 67 is not at the Lo level (that is, the Hi level), that is, the light receiving unit of the second photosensor 67 detects the light. If it is determined, the process proceeds to step 114. On the other hand, when it is determined that the signal output from the output terminal of the second photosensor 67 is at the Lo level, that is, when it is determined that the light receiving unit of the second photosensor 67 is not detecting light, Return to step 111.

  In step 114, abnormality determination processing is performed. Specifically, when the medal guided downward in the medal path 61 has blocked the first optical path and the signal output from the output terminal of the first photosensor 66 changes from Lo level to Hi level, Since the medal should be before the second optical path has been blocked, the Lo-level signal should continue to be output from the output terminal of the second photosensor 67, and abnormal when the Hi-level signal is output. . That is, the medal guided downward through the medal path 61 should continue to block the second optical path at the moment when the first optical path is blocked, and when the light receiving unit of the second photosensor 67 detects light, It is abnormal. Then, the abnormality determination means 160 outputs a Hi level signal from the output terminal of the second photosensor 67 when the signal output from the output terminal of the first photosensor 66 changes from the Lo level to the Hi level. That is, when the light receiving unit of the second photosensor 67 detects light, it is determined as abnormal. Further, the operation after the abnormality determination is as described above. Then, the abnormality determination process ends.

  In step 115, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level before and after waiting for a predetermined time in Step 111. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 111. If it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level, the process proceeds to step 116. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Lo level to the Hi level, the process proceeds to step 118.

  In step 116, it is determined whether or not the signal output from the output terminal of the first photosensor 66 is at the Hi level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 is detecting light. Here, if it is determined that the signal output from the output terminal of the first photosensor 66 is not Hi level (Lo level), that is, the light receiving unit of the first photosensor 66 is detecting light. If it is determined that there is not, the routine proceeds to step 120. On the other hand, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Hi level, that is, when it is determined that the light receiving unit of the first photosensor 66 is detecting light, Proceed to step 117.

In step 117, a medal one count process is performed. Specifically, when proceeding to step 117, a medal detection signal having a pattern as shown in FIG. 6 is output. Then, the medal counting means 170 adds one count value. When the count value of the medal count means 170 reaches the upper limit “3”, the credit medal count means 180 adds one count value. Then, the medal one-count process ends.
In step 118, 1 is subtracted from the value of the medal passage limit time detection timer TM. Then, the process proceeds to Step 119.

In step 119, it is determined whether or not the value of the medal passage limit time detection timer TM after the subtraction in step 118 is greater than zero. Here, even if the value of the medal passage limit time detection timer TM is decremented by 1 in step 118, if it is determined that the value of the medal passage limit time detection timer TM is greater than 0, the process returns to step 111. On the other hand, if it is determined that the value of the medal passage limit time detection timer TM becomes 0 as a result of subtracting 1 from the value of the medal passage limit time detection timer TM in step 118, the process proceeds to step 120.
In step 120, abnormality determination processing is performed. Specifically, when the medal guided downward through the medal path 61 has blocked the second optical path and the signal output from the output terminal of the second photosensor 67 changes from Lo level to Hi level, Since the medal should have already blocked the first optical path, a Hi level signal should continue to be output from the output terminal of the first photosensor 66, and it is abnormal if a Lo level signal is output. . That is, when the medal guided downward in the medal path 61 has completely blocked the second optical path and the light receiving unit of the second photosensor 67 detects light again, the light receiving unit of the first photosensor 66 It should be detecting light, and it is abnormal if light is not detected. Then, the abnormality determination means 160 outputs a Lo level signal from the output terminal of the first photosensor 66 when the signal output from the output terminal of the second photosensor 67 changes from the Lo level to the Hi level. And determined to be abnormal. That is, when the light receiving unit of the second photosensor 67 detects light again, if the light receiving unit of the first photosensor 66 does not detect light, the abnormality determining unit 160 determines that there is an abnormality. . When the value of the medal passage limit time detection timer TM becomes 0, the time is over. Then, when the value of the medal passage limit time detection timer TM becomes 0, the abnormality determination unit 160 determines that the term is over and determines that there is an abnormality. Further, the operation after the abnormality determination is as described above. Then, the abnormality determination process ends.

In step 121, it is determined whether a start signal has been output. Here, if it is determined that the start signal has been output, the routine proceeds to step 122. On the other hand, if it is determined that the start signal is not output, the process returns to step 103.
In step 122, the medal cannot be inserted. Further, when the medal insertion is disabled, the energization to the cancel coil 63f is stopped, and the swing arm 63d is in the state shown in FIG. 4B. That is, the path of medals inserted from the medal insertion slot 41 is in the direction of the medal return path 62. Then, the medals inserted from the medal insertion slot 41 are guided to the medal return passage 62 and discharged from the medal return slot 33. If the medal insertion is disabled, the medal sensor 65 cannot detect the medal. Then, the medal detection process ends.

As described above, in the present embodiment, the first photosensor 66 is stopped when light emission from the light emitting unit is stopped and light emission from the light emitting unit is stopped while light detection by the light receiving unit is enabled. When the light receiving unit detects light, it is determined as abnormal. Thereby, the fraud using a fraudulent instrument can be prevented.
In the present embodiment, when the light receiving unit of the second photosensor 67 stops detecting light when the light emitting unit of the first photosensor 66 is stopped, the first photosensor is detected within a predetermined time. If the light emitting unit 66 emits light and the light receiving unit of the first photosensor 66 detects light at this time, it is determined that there is an abnormality. As a result, it is possible to simultaneously prevent an illegal act using an illegal instrument and an illegal act that illegally increases the number of credits with a medal tied with a thread.

  In the present embodiment, since the light emission of the light emitting portion of the first photosensor 66 is stopped, the first photosensor 66 mainly plays a role of detecting fraud and the second photosensor 67 mainly plays the number of medals. It will play the role of counting. Then, when the medal flows down the medal passage 61 from the upstream side to the downstream side, it is first confirmed that it is not an illegal act mainly by the signal of the first photosensor 66, and then mainly by the signal of the second photosensor 67. Since the number of medals is counted, it is possible to count the number of medals inserted from the medal insertion slot 41 while preventing the above two illegal acts simultaneously without requiring complicated control and configuration.

  In the present embodiment, the light emission control unit 150 stops the light emission of the light emitting unit of the first photosensor 66 and the light emitting unit of the second photosensor 67 emits light from the medal insertion slot 41. Control to wait for the insertion of medals is always executed. That is, in the present embodiment, in the medal insertion waiting state, the light emitting unit of the first photosensor 66 does not always emit light, and the light emitting unit of the second photosensor 67 always emits light. Yes. Of course, when a medal is inserted from the medal insertion port 41, the second optical path is blocked by the medal, and the light receiving unit of the second photosensor 67 no longer detects light, as described above, The light emitting part emits light. In this way, the control of waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emission of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is turned on is always performed. By executing this, the burden on the control device can be reduced while preventing fraud.

(Second Embodiment)
(Explanation of drawings)
FIG. 9 is a time chart of medal detection signals in the second embodiment, and FIGS. 10 to 12 are flowcharts of medal detection processing in the second embodiment.
(Game machine 10)
The gaming machine 10 according to the second embodiment has the same hardware configuration as the gaming machine 10 according to the first embodiment.
The gaming machine 10 according to the second embodiment stops the light emission of the light emitting part of the first photosensor 66 and the medal from the medal insertion slot 41 with the light emitting part of the second photosensor 67 emitted. Either one of the control of waiting for the insertion or the control of waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 emit light is performed once by the game. Each time it is performed, it is selected and executed based on a random value.

(Medal detection signal)
The medal detection signal in a state where the light emitting portions of both the first photosensor 66 and the second photosensor 67 are caused to emit light will be described based on the time chart shown in FIG.
In the medal insertion waiting state, normally, the Hi level signal continues to be output from the output terminal of the first photosensor 66, and the Hi level signal continues to be output from the output terminal of the second photosensor 67 (FIG. 9). Before a inside).
When a medal flowing down the medal passage 61 begins to block the first optical path, the signal output from the output terminal of the first photosensor 66 changes from the Hi level to the Lo level. At this time, the signal output from the output terminal of the second photosensor 67 is at the Hi level (a in FIG. 9). Further, a state where the Lo level signal continues to be output from the output terminal of the first photosensor 66 and the Hi level signal continues to be output from the output terminal of the second photosensor 67 flows down the medal path 61. The medal continues until just before blocking the second optical path (between a and b in FIG. 9).

When a medal flowing down the medal passage 61 begins to block the second optical path, the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level. At this time, since the medal is usually before the first optical path is completely blocked, the signal output from the output terminal of the first photosensor 66 is at the Lo level (b in FIG. 9). In addition, when the Lo level signal continues to be output from the output terminal of the first photosensor 66 and the Lo level signal continues to be output from the output terminal of the second photosensor 67, the medal path 61 flows down. The medal to continue continues until just before the first optical path is blocked (between bc in FIG. 9).
When the medal flowing down the medal passage 61 finishes blocking the first optical path, the signal output from the output terminal of the first photosensor 66 changes from the Lo level to the Hi level. At this time, since the medal is usually before the second optical path is blocked, the signal output from the output terminal of the second photosensor 67 is at the Lo level (c in FIG. 9). Further, a state in which a Hi level signal continues to be output from the output terminal of the first photosensor 66 and a Lo level signal continues to be output from the output terminal of the second photosensor 67 flows down the medal path 61. The medal continues until just before the second optical path is blocked (between cd in FIG. 9).

When the medal flowing down the medal passage 61 finishes blocking the second optical path, the signal output from the output terminal of the second photosensor 67 changes from the Lo level to the Hi level. At this time, since the medal is usually after blocking the first optical path, the signal output from the output terminal of the first photosensor 66 is at the Hi level (d in FIG. 9).
The medal detection signal in the state where the light emission of the first photosensor 66 is stopped and the light emission of the second photosensor 67 is emitted is the same as the pattern shown in FIG.
Further, in this embodiment, when a medal detection signal having a pattern other than that shown in FIGS. 6 and 9 is output, it is abnormal, and the abnormality determining means 160 determines that it is abnormal.

(Medal detection process)
The medal detection process in the present embodiment will be described based on the flowcharts shown in FIGS.
As described above, in the present embodiment, the medal is inserted from the medal insertion slot 41 in a state where the light emission of the first photosensor 66 is stopped and the light emission of the second photosensor 67 is emitted. The light emission control means 150 performs either waiting control or control waiting for insertion of a medal from the medal insertion slot 41 in a state where both the light emitting portions of the first photo sensor 66 and the second photo sensor 67 are caused to emit light. Each time a game is played, it is selected and executed based on a random value.

Further, when the control for waiting for the insertion of a medal from the medal insertion slot 41 in the state where the light emission unit of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is turned on is selected. As in the embodiment, in the state of waiting for the medal insertion, the light receiving unit of the second photosensor 67 detects light by stopping the light emission of the light emitting unit of the first photosensor 66 and inserting the medal. If it stops, the light emission control means 150 makes the light emission part of the 1st photosensor 66 light-emit.
In step 200, the lower 1 bit of the light emission pattern selection counter N is stored in S. Here, the light emission pattern selection counter N is for generating a random number used for the selection / switching between the two states described above, and is incremented by 1 at a predetermined time. It is provided on the microcomputer which comprises. Further, S is for storing the lower 1 bit of the light emission pattern selection counter N, and is provided in a predetermined area on the RAM of the microcomputer constituting the control device 100. When the lower 1 bit of the light emission pattern selection counter N is stored in S, the process proceeds to step 201.

  In step 201, the medal can be inserted. In addition, when the medal can be inserted, energization to the cancel coil 63f is started. Then, the iron core of the cancel coil 63f pulls the upper piece of the swing arm 63d against the urging force of the spring 63e. As a result, the state shown in FIG. That is, the path of medals inserted from the medal insertion slot 41 is in the downstream direction with respect to the branch portion of the medal path 61. Then, the medal inserted from the medal insertion slot 41 passes through the medal selector 63 and the medal sensor 65 and reaches the medal tank of the hopper unit 70. When the medal insertion is set to be possible, the medal sensor 65 can detect the medal. In addition, from the time when the medal insertion is permitted until the medal is inserted, there is a waiting state for medal insertion. If the medal can be inserted, the process proceeds to step 202.

In step 202, 0 is set in the medal passage limit time detection timer TM. When 0 is set in the medal passage limit time detection timer TM, the process proceeds to step 203.
In step 203, it is determined whether S = 0. In the present embodiment, S is either 0 or 1, and when S = 0, the light emission part of the first photosensor 66 is stopped and the light emission part of the second photosensor 67 is caused to emit light. Control for waiting for the insertion of a medal from the medal insertion slot 41 is selected. On the other hand, when S = 1, the medal is emitted with the light emitting portions of both the first photosensor 66 and the second photosensor 67 being lit. A control for waiting for the insertion of a medal from the insertion slot 41 is selected. If it is determined that S = 0, the process proceeds to step 204. On the other hand, if it is determined that S = 0, that is, if it is determined that S = 1, the process proceeds to step 213.

In step 204, the light emission of the light emitting unit of the first photosensor 66 is stopped. Then, the process proceeds to Step 205.
In step 205, after waiting for a certain time, it is confirmed whether the signals output from the output terminals of the first photosensor 66 and the second photosensor 67 are Hi level or Lo level. To be compared. The confirmation and comparison operations are the same as in step 103. In step 204, the light emission of the light emitting unit of the first photosensor 66 is stopped. However, it takes a certain time to shift the light emitting unit of the first photosensor 66 from the light emitting state to the light-off state. In determining whether the signal output from the output terminal of one photosensor 66 is at the Lo level, in order to prevent malfunction, a waiting period is set here. Then, the process proceeds to Step 206.

In step 206, 1 is added to the value of the light emission pattern selection counter N. Then, the process proceeds to Step 207.
In step 207, it is determined whether or not the signal output from the output terminal of the first photosensor 66 is a Lo level signal. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, if it is determined that the signal output from the output terminal of the first photosensor 66 is not a Lo level signal, that is, the signal output from the output terminal of the first photosensor 66 is Hi level. If it is determined that the signal is a signal, the process proceeds to step 208. That is, when the light receiving unit of the first photosensor 66 detects light, the process proceeds to step 208. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 is a Lo level signal, the process proceeds to step 209. That is, if the light receiving unit of the first photosensor 66 does not detect light, the process proceeds to step 209.

  In step 208, abnormality determination processing is performed. Specifically, when the light emission of the light emitting unit of the first photosensor 66 is stopped, a Lo level signal should continue to be output from the output terminal, and when a Hi level signal is output, It is abnormal. That is, it is abnormal if the light receiving unit detects light when the light emission of the light emitting unit of the first photosensor 66 is stopped. Then, when the Hi-level signal is output from the output terminal when the light emission unit of the first photosensor 66 is stopped, the abnormality determination unit 160 performs an unauthorized act using an unauthorized instrument. It is determined as abnormal. That is, when light emission from the light emitting unit of the first photo sensor 66 is stopped, if the light receiving unit detects light, it is abnormal, and the abnormality determining unit 160 performs an illegal act using an unauthorized instrument. It is determined as abnormal. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 209, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level before and after waiting for a predetermined time in Step 205. Further, the determination as to whether or not the change has occurred is made based on the result of the confirmation and comparison in step 205. Here, if it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level, the routine proceeds to step 210. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Hi level to the Lo level, the process returns to step 204.

In step 210, the light emitting unit of the first photosensor 66 is caused to emit light and a predetermined time is waited. It takes a certain time to shift the light emitting unit of the first photosensor 66 from the extinguished state to the light emitting state. In order to prevent malfunctions when making a determination, the system waits for a certain period of time. Then, the process proceeds to Step 211.
In step 211, it is determined whether or not the signal output from the output terminal of the first photosensor 66 is a Lo level signal. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, if it is determined that the signal output from the output terminal of the first photosensor 66 is not a Lo level signal, that is, the signal output from the output terminal of the first photosensor 66 is Hi level. If it is determined that the signal is a signal, the process proceeds to step 212. That is, if it is determined that the light receiving unit of the first photosensor 66 is detecting light, the process proceeds to step 212. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 is a Lo level signal, the process proceeds to step 218. That is, if it is determined that the light receiving unit of the first photosensor 66 is not detecting light, the process proceeds to step 218.

  In step 212, abnormality determination processing is performed. Specifically, when the medal guided downward in the medal path 61 blocks the second optical path, and the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level, the light emission control means 150 causes the light emitting portion of the first photosensor 66 to emit light. At this time, since the medal should be before the first optical path has been blocked, the Lo level signal should continue to be output from the output terminal of the first photosensor 66, and when the Hi level signal is output, It is abnormal. That is, at this time, since the medal should be before the first optical path has been blocked, the light receiving portion of the first photosensor 66 should not detect light, and it is abnormal when the light receiving portion detects light. When the Hi-level signal is output from the output terminal of the first photosensor 66 when the light emitting unit of the first photosensor 66 emits light, the abnormality determination unit 160 indicates that the medal with the thread tied is a medal. It is determined that there is an abnormality because the passage 61 is guided upward. In other words, when the light receiving unit detects light when the light emitting unit of the first photosensor 66 emits light, the abnormality determination unit 160 causes the medal with the thread tied to the medal path 61 to be guided upward. It is determined as abnormal. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

In step 213, the light emitting portion of the first photosensor 66 is caused to emit light. Then, the process proceeds to step 214.
In step 214, after waiting for a certain period of time, it is confirmed whether the signals output from the output terminals of the first photosensor 66 and the second photosensor 67 are at the Hi level or the Lo level. To be compared. The confirmation and comparison operations are the same as in step 103. In step 213, the light emitting portion of the first photosensor 66 is caused to emit light, but it takes a certain time to shift the light emitting portion of the first photosensor 66 from the light-off state to the light emitting state. When determining whether or not the signal output from the output terminal of the photo sensor 66 is at the Lo level, a certain period of time is waited to prevent malfunction. Further, the fixed time waiting in step 214 is approximately one unit time in the medal passage limit time detection timer TM. Then, the process proceeds to Step 215.

In step 215, 1 is added to the value of the light emission pattern selection counter N. Then, the process proceeds to Step 216.
In step 216, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Hi level to the Lo level. Specifically, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Hi level to the Lo level before and after waiting for a certain time in step 214. Further, the determination as to whether or not the change has occurred is made based on the result of the confirmation and comparison in step 214. If it is determined that the signal output from the output terminal of the first photosensor 66 has changed from the Hi level to the Lo level, the process proceeds to step 217. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 has not changed from the Hi level to the Lo level, the routine proceeds to step 220.

  In step 217, it is determined whether or not the signal output from the output terminal of the second photosensor 67 is at the Hi level. That is, it is determined whether the light receiving unit of the second photosensor 67 is detecting light. Here, when it is determined that the signal output from the output terminal of the second photosensor 67 is at the Hi level, that is, when it is determined that the light receiving unit of the second photosensor 67 is detecting light. Go to step 218. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 is not Hi level (Lo level), that is, the light receiving unit of the second photosensor 67 has not detected light. If it is determined, step 219 follows.

In step 218, a predetermined value is set in the medal passage limit time detection timer TM. Then, the process returns to step 214.
In step 219, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the first photosensor 66 changing from the Hi level to the Lo level means that the medal flowing down the medal path 61 is in a position where it begins to block the first optical path. In this case, the signal output from the output terminal of the second photosensor 67 is not at the Hi level (when it is at the Lo level). If the light receiving unit of the photosensor 67 does not detect light, it is abnormal. When the signal output from the output terminal of the first photosensor 66 changes from the Hi level to the Lo level, the signal output from the output terminal of the second photosensor 67 is not the Hi level (Lo level). In other words, if the light receiving part of the second photosensor 67 does not detect light, the abnormality determination means 160 determines that the medal with the thread tied is guided upward in the medal path 61, etc. It is determined. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 220, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level before and after waiting for a certain time in Step 214. Further, the determination as to whether or not the change has occurred is made based on the result of the confirmation and comparison in step 214. If it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level, the process proceeds to step 221. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Hi level to the Lo level, the process proceeds to step 223.

  In step 221, it is determined whether or not the signal output from the output terminal of the first photosensor 66 is at the Lo level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Lo level, that is, when the light receiving unit of the first photosensor 66 is determined not to detect light. Return to step 214. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 is not at the Lo level (Hi level), that is, the light receiving unit of the first photosensor 66 is detecting light. If it is determined, the routine proceeds to step 222.

  In step 222, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the second photosensor 67 changing from the Hi level to the Lo level means that the medal flowing down the medal path 61 is in a position where it begins to block the second optical path. In this case, the signal output from the output terminal of the first photosensor 66 is not at the Lo level (when it is at the Hi level), that is, the first photo is taken. If the light receiving part of the sensor 66 detects light, it is abnormal. When the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level, the signal output from the output terminal of the first photosensor 66 is not at the Lo level (Hi level). In other words, when the light receiving unit of the first photosensor 66 detects light, the abnormality determination unit 160 determines that the medal with the thread tied is guided upward in the medal path 61 and the like. judge. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 223, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level. Specifically, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level before and after waiting for a certain time in step 214. Further, the determination as to whether or not the change has occurred is made based on the result of the confirmation and comparison in step 214. If it is determined that the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level, the process proceeds to step 224. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 has not changed from the Lo level to the Hi level, the process proceeds to step 226.

  In step 224, it is determined whether or not the signal output from the output terminal of the second photosensor 67 is at the Lo level. That is, it is determined whether or not the light receiving unit of the second photosensor 67 has detected light. Here, when it is determined that the signal output from the output terminal of the second photosensor 67 is at the Lo level, that is, when it is determined that the light receiving unit of the second photosensor 67 is not detecting light. Return to step 214. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 is not at the Lo level (Hi level), that is, the light receiving unit of the second photosensor 67 detects light. If it is determined, step 225 follows.

  In step 225, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the first photosensor 66 changing from the Lo level to the Hi level means that the medal flowing down the medal path 61 is at a position where it has blocked the first optical path. And the second optical path should still be in a position where it is still blocked. At this time, if the signal output from the output terminal of the second photosensor 67 is not at the Lo level (Hi level), that is, If the light receiving part of the second photosensor 67 detects light, it is abnormal. When the signal output from the output terminal of the first photosensor 66 changes from the Lo level to the Hi level, the signal output from the output terminal of the second photosensor 67 is not at the Lo level (Hi level). In other words, when the light receiving unit of the second photosensor 67 detects light, the abnormality determination unit 160 determines that the medal with the thread tied is guided upward in the medal path 61 and determines that there is an abnormality. To do. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 226, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level before and after waiting for a fixed time in step 214. Further, the determination as to whether or not the change has occurred is made based on the result of the confirmation and comparison in step 214. If it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level, the process proceeds to step 227. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Lo level to the Hi level, the process proceeds to step 230.

  In step 227, it is determined whether or not the signal output from the output terminal of the first photosensor 66 is at the Hi level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 is detecting light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Hi level, that is, when it is determined that the light receiving unit of the first photosensor 66 is detecting light. The process proceeds to step 228. On the other hand, when it is determined that the signal output from the output terminal of the first photosensor 66 is not Hi level (Lo level), that is, the light receiving unit of the first photosensor 66 has not detected light. If it is determined, step 235 follows.

In step 228, a medal one count process is performed. Specifically, when proceeding to step 228, a medal detection signal having a pattern as shown in FIG. 6 or FIG. 9 is output. Then, the medal counting means 170 adds one count value. When the count value of the medal count means 170 reaches the upper limit “3”, the credit medal count means 180 adds one count value. Then, the medal one-count process ends. Then, the process proceeds to Step 229.
In step 229, 0 is set in the medal passage limit time detection timer TM. As described above, the fact that 0 is set in the medal passage limit time detection timer TM means that the medal is not passing through the medal passage 61. Then, the process proceeds to Step 233.

In step 230, it is determined whether or not the value of the medal passage limit time detection timer TM is greater than zero. In step 230, it is determined whether or not the value of the medal passage limit time detection timer TM is greater than 0 in order to determine whether or not the medal is passing through the first photosensor 66 and the second photosensor 67. It is. If it is determined that the value of the medal passage limit time detection timer TM is greater than 0, the process proceeds to step 231. On the other hand, if it is determined that the value of the medal passage limit time detection timer TM has become 0, the process proceeds to step 233.
In step 231, 1 is subtracted from the value of the medal passage limit time detection timer TM. Then, the process proceeds to Step 232.

  In step 232, it is determined whether or not the value of the medal passage limit time detection timer TM after the subtraction in step 231 is greater than zero. The reason why the value of the medal passage limit time detection timer TM is determined to be greater than 0 in step 232 is to determine whether or not the time is over. Here, even if the value of the medal passage limit time detection timer TM is decremented by 1 in step 231, if it is determined that the value of the medal passage limit time detection timer TM is greater than 0, the process returns to step 214. On the other hand, if it is determined that the value of the medal passage limit time detection timer TM has become 0 as a result of subtracting 1 from the value of the medal passage limit time detection timer TM in step 231, the process proceeds to step 235.

In step 233, it is determined whether a start signal has been output. If it is determined that the start signal has been output, the process proceeds to step 234. On the other hand, if it is determined that the start signal is not output, the process returns to step 203.
In step 234, the medal cannot be inserted. Further, when the medal insertion is disabled, the energization to the cancel coil 63f is stopped, and the swing arm 63d is in the state shown in FIG. 4B. That is, the path of medals inserted from the medal insertion slot 41 is in the direction of the medal return path 62. Then, the medals inserted from the medal insertion slot 41 are guided to the medal return passage 62 and discharged from the medal return slot 33. If the medal insertion is disabled, the medal sensor 65 cannot detect the medal. Then, the medal detection process ends.

  In step 235, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the second photosensor 67 changing from the Lo level to the Hi level means that the medal flowing down the medal path 61 is at a position where the second optical path is completely blocked. , And the first optical path should already be in the position where the light has already been interrupted. At this time, if the signal output from the output terminal of the first photosensor 66 is not Hi level (Lo level), that is, If the light receiving unit of one photosensor 66 does not detect light, it is abnormal. When the signal output from the output terminal of the second photosensor 67 changes from the Lo level to the Hi level, the signal output from the output terminal of the first photosensor 66 is not the Hi level (Lo level). That is, if the light receiving portion of the first photosensor 66 does not detect light, the abnormality determination means 160 determines that the medal with the thread tied is guided upward in the medal path 61 and the like. Is determined. In step 232, when the value of the medal passage limit time detection timer TM becomes 0, the time is over. Then, when the value of the medal passage limit time detection timer TM becomes 0 in step 232, the abnormality determination unit 160 determines that the term is over and determines that there is an abnormality. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

As described above, in the present embodiment, the light emitting unit of the first photosensor 66 is stopped and the light emitting unit of the second photosensor 67 is turned on to wait for the medal insertion from the medal insertion slot 41. Either the control or the control for waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 are lit, the light emission control means 150 Is performed once based on a random number value.
In the present embodiment, in the control of waiting for the insertion of a medal from the medal insertion slot 41 with the light emitting portions of both the first photosensor 66 and the second photosensor 67 emitting light, Since a medal detection signal having a similar pattern is output, a medal detection process is performed as in the conventional gaming machine 10.

Further, in this embodiment, when the light receiving unit detects light when the light emitting unit of the first photosensor 66 is stopped, it is determined that there is an abnormality. Thereby, the fraud using a fraudulent instrument can be prevented.
In the present embodiment, when the light receiving unit of the second photosensor 67 stops detecting light when the light emitting unit of the first photosensor 66 is stopped, the first photosensor is detected within a predetermined time. If the light emitting unit 66 emits light and the light receiving unit of the first photosensor 66 detects light at this time, it is determined that there is an abnormality. As a result, it is possible to simultaneously prevent an illegal act using an illegal instrument and an illegal act that illegally increases the number of credits with a medal tied with a thread.

(Third embodiment)
(Explanation of drawings)
13 to 15 are flowcharts of the medal detection process in the third embodiment.
(Game machine 10)
The gaming machine 10 according to the third embodiment has the same hardware configuration as the gaming machine 10 according to the first embodiment.
In addition, the gaming machine 10 according to the third embodiment stops the light emission of the light emitting part of the first photosensor 66 and the light emitting part of the second photosensor 67 emits light from the medal slot 41. The control of waiting for the insertion of a medal and the control of waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 are made to emit 1 medal. Each time a sheet is detected, it is alternately switched and executed.

(Medal detection process)
The medal detection process in the present embodiment will be described based on the flowcharts shown in FIGS.
In step 300, it is determined whether the lower 1 bit of the light emission pattern selection counter N is 0 or not. In this embodiment, every time the medal detection process is performed once, 1 is added to the value of the light emission pattern selection counter N. If it is determined that the lower 1 bit of the light emission pattern selection counter N is 0, the process proceeds to step 301. On the other hand, if it is determined that the lower 1 bit of the light emission pattern selection counter N is not 0 (is 1), the routine proceeds to step 302.

In step 301, the light emitting unit of the first photosensor 66 is caused to emit light. Then, the process proceeds to step 303.
In step 302, the light emission of the light emitting unit of the first photosensor 66 is stopped. Then, the process proceeds to step 303.
In step 303, the medal can be inserted. In addition, when the medal can be inserted, energization to the cancel coil 63f is started. Then, the iron core of the cancel coil 63f pulls the upper piece of the swing arm 63d against the urging force of the spring 63e. As a result, the state shown in FIG. That is, the path of medals inserted from the medal insertion slot 41 is in the downstream direction with respect to the branch portion of the medal path 61. Then, the medal inserted from the medal insertion slot 41 passes through the medal selector 63 and the medal sensor 65 and reaches the medal tank of the hopper unit 70. When the medal insertion is set to be possible, the medal sensor 65 can detect the medal. In addition, from the time when the medal insertion is permitted until the medal is inserted, there is a waiting state for medal insertion. Then, when the medal insertion is permitted, the process proceeds to step 304.

In step 304, 0 is set in the medal passage limit time detection timer TM. Then, the process proceeds to Step 305.
In step 305, it is determined whether or not the light emitting unit of the first photosensor 66 is emitting light. Here, if it is determined that the light emitting unit of the first photosensor 66 is emitting light, the process proceeds to step 306. On the other hand, if it is determined that the light emitting unit of the first photosensor 66 is not emitting light, the process proceeds to step 315.
In step 306, after waiting for a certain period of time, it is confirmed whether the signals output from the output terminals of the first photo sensor 66 and the second photo sensor 67 are at the Hi level or the Lo level. To be compared. The confirmation and comparison operations are the same as in step 103. In step 301, the light emitting portion of the first photosensor 66 is caused to emit light. In step 302, the light emitting portion of the first photosensor 66 is stopped, but the light emitting portion of the first photosensor 66 is turned off. Whether a signal output from the output terminal of the first photosensor 66 in step 308 is at a Lo level or not is determined when it takes a certain time to shift to the light emitting state or conversely to shift from the light emitting state to the off state. In order to prevent malfunctions when making a determination, the system waits for a certain period of time. Then, the process proceeds to Step 307.

In step 307, 1 is added to the value of the light emission pattern selection counter N. Then, the process proceeds to Step 308.
In step 308, it is determined whether the signal output from the output terminal of the first photosensor 66 is at the Lo level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is not at the Lo level (ie, at the Hi level), that is, the light receiving unit of the first photosensor 66 detects the light. If it is determined, the process proceeds to step 309. On the other hand, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Lo level, that is, when it is determined that the light receiving unit of the first photosensor 66 is not detecting light, Proceed to step 310.

  In step 309, abnormality determination processing is performed. Specifically, when the light emission of the light emitting unit of the first photosensor 66 is stopped, a Lo level signal should continue to be output from the output terminal, and when a Hi level signal is output, It is abnormal. That is, it is abnormal if the light receiving unit detects light when the light emission of the light emitting unit of the first photosensor 66 is stopped. Then, when the Hi-level signal is output from the output terminal when the light emission unit of the first photosensor 66 is stopped, the abnormality determination unit 160 performs an unauthorized act using an unauthorized instrument. It is determined as abnormal. That is, when light emission from the light emitting unit of the first photo sensor 66 is stopped, if the light receiving unit detects light, it is abnormal, and the abnormality determining unit 160 performs an illegal act using an unauthorized instrument. It is determined as abnormal. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 310, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level before and after waiting for a certain time in Step 306. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 306. If it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level, the process proceeds to step 311. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Hi level to the Lo level, the process proceeds to step 314.

In step 311, the light emitting unit of the first photosensor 66 is caused to emit light and wait for a predetermined time. In step 312, when determining whether or not the signal output from the output terminal of the first photosensor 66 is at the Lo level, a predetermined time is waited here in order to prevent malfunction. Then, the process proceeds to step 312.
In step 312, it is determined whether the signal output from the output terminal of the first photosensor 66 is at the Lo level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is not at the Lo level (ie, at the Hi level), that is, the light receiving unit of the first photosensor 66 detects the light. If it is determined, the process proceeds to step 313. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 is a Lo level signal, that is, it is determined that the light receiving unit of the first photosensor 66 is not detecting light. Then, the process proceeds to step 319.

  In step 313, abnormality determination processing is performed. Specifically, when the medal guided downward in the medal path 61 blocks the second optical path, and the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level, the light emission control means 150 causes the light emitting portion of the first photosensor 66 to emit light. At this time, since the medal should be before the first optical path has been blocked, the Lo level signal should continue to be output from the output terminal of the first photosensor 66, and when the Hi level signal is output, It is abnormal. That is, at this time, since the medal should be before the first optical path has been blocked, the light receiving portion of the first photosensor 66 should not detect light, and it is abnormal when the light receiving portion detects light. Then, when a Hi level signal is output from the output terminal when the light emitting unit of the first photosensor 66 emits light, that is, when the light receiving unit detects light, the abnormality determination unit 160 binds the yarn. It is determined that the attached medal is abnormal, for example, by guiding the medal passage 61 upward. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

In step 314, a determination is made whether a start signal has been output. Here, if it is determined that the start signal has been output, the process proceeds to step 334. On the other hand, if it is determined that the start signal is not output, the process returns to step 306.
In step 315, after waiting for a certain period of time, it is confirmed whether the signals output from the output terminals of the first photosensor 66 and the second photosensor 67 are at the Hi level or the Lo level. To be compared. The confirmation and comparison operations are the same as in step 103. In step 301, the light emitting portion of the first photosensor 66 is caused to emit light. In step 302, the light emitting portion of the first photosensor 66 is stopped, but the light emitting portion of the first photosensor 66 is turned off. Since it takes a certain time to shift to the light emitting state or to shift from the light emitting state to the off state, it is determined in step 322 whether or not the signal output from the output terminal of the first photosensor 66 is at the Lo level. In order to prevent malfunctions when making a determination, the system waits for a certain period of time. Further, the fixed time waiting in this step 315 is approximately one unit time in the medal passage limit time detection timer TM. Then, the process proceeds to Step 316.

In step 316, 1 is added to the value of the light emission pattern selection counter N. Then, the process proceeds to Step 317.
In step 317, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Hi level to the Lo level. Specifically, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Hi level to the Lo level before and after waiting for a fixed time in Step 315. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 315. If it is determined that the signal output from the output terminal of the first photosensor 66 has changed from the Hi level to the Lo level, the process proceeds to step 318. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 has not changed from the Hi level to the Lo level, the process proceeds to step 321.

  In step 318, it is determined whether or not the signal output from the output terminal of the second photosensor 67 is at the Hi level. That is, it is determined whether the light receiving unit of the second photosensor 67 is detecting light. Here, when it is determined that the signal output from the output terminal of the second photosensor 67 is at the Hi level, that is, when it is determined that the light receiving unit of the second photosensor 67 is detecting light. Go to step 319. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 is not Hi level (Lo level), that is, the light receiving unit of the second photosensor 67 has not detected light. If it is determined, step 320 is proceeded to.

In step 319, a predetermined value is set in the medal passage limit time detection timer TM. Then, the process returns to step 315.
In step 320, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the first photosensor 66 changing from the Hi level to the Lo level means that the medal flowing down the medal path 61 is in a position where it begins to block the first optical path. In this case, the signal output from the output terminal of the second photosensor 67 is not at the Hi level (when it is at the Lo level). If the light receiving unit of the photosensor 67 does not detect light, it is abnormal. When the signal output from the output terminal of the first photosensor 66 changes from the Hi level to the Lo level, the signal output from the output terminal of the second photosensor 67 is not the Hi level (Lo level). In other words, if the light receiving part of the second photosensor 67 does not detect light, the abnormality determination means 160 determines that the medal with the thread tied is guided upward in the medal path 61, etc. It is determined. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 321, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level before and after waiting for a predetermined time in Step 315. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 315. If it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level, the process proceeds to step 322. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Hi level to the Lo level, the process proceeds to step 324.

  In step 322, it is determined whether or not the signal output from the output terminal of the first photosensor 66 is at the Lo level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Lo level, that is, when the light receiving unit of the first photosensor 66 is determined not to detect light. Return to step 315. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 is not at the Lo level (Hi level), that is, the light receiving unit of the first photosensor 66 is detecting light. If it is determined, the process proceeds to step 323.

  In step 323, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the second photosensor 67 changing from the Hi level to the Lo level means that the medal flowing down the medal path 61 is in a position where it begins to block the second optical path. In this case, the signal output from the output terminal of the first photosensor 66 is not at the Lo level (when it is at the Hi level), that is, the first photo is taken. If the light receiving part of the sensor 66 detects light, it is abnormal. When the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level, the signal output from the output terminal of the first photosensor 66 is not at the Lo level (Hi level). In other words, when the light receiving unit of the first photosensor 66 detects light, the abnormality determination unit 160 determines that the medal with the thread tied is guided upward in the medal path 61 and determines that there is an abnormality. To do. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 324, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level. Specifically, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level before and after waiting for a certain time in step 315. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 315. If it is determined that the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level, the process proceeds to step 325. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 has not changed from the Lo level to the Hi level, the process proceeds to step 327.

  In step 325, it is determined whether the signal output from the output terminal of the second photosensor 67 is at the Lo level. That is, it is determined whether or not the light receiving unit of the second photosensor 67 has detected light. Here, when it is determined that the signal output from the output terminal of the second photosensor 67 is at the Lo level, that is, when it is determined that the light receiving unit of the second photosensor 67 is not detecting light. Return to step 315. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 is not at the Lo level (Hi level), that is, the light receiving unit of the second photosensor 67 detects light. If it is determined, step 326 follows.

  In step 326, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the first photosensor 66 changing from the Lo level to the Hi level means that the medal flowing down the medal path 61 is at a position where it has blocked the first optical path. And the second optical path should still be in a position where it is still blocked. At this time, if the signal output from the output terminal of the second photosensor 67 is not at the Lo level (Hi level), that is, If the light receiving part of the second photosensor 67 detects light, it is abnormal. When the signal output from the output terminal of the first photosensor 66 changes from the Lo level to the Hi level, the signal output from the output terminal of the second photosensor 67 is not at the Lo level (Hi level). In other words, when the light receiving unit of the second photosensor 67 detects light, the abnormality determination means 160 determines that the medal with the thread tied is guided toward the medal path 61 upward, judge. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 327, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level before and after waiting for a predetermined time in Step 315. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 315. If it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level, the process proceeds to step 328. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Lo level to the Hi level, the process proceeds to step 330.

  In step 328, it is determined whether the signal output from the output terminal of the first photosensor 66 is at the Hi level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 is detecting light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Hi level, that is, when it is determined that the light receiving unit of the first photosensor 66 is detecting light. Go to step 329. On the other hand, when it is determined that the signal output from the output terminal of the first photosensor 66 is not Hi level (Lo level), that is, the light receiving unit of the first photosensor 66 has not detected light. If it is determined, step 335 follows.

In step 329, a medal one count process is performed. Specifically, when proceeding to step 329, a medal detection signal having a pattern as shown in FIG. 6 or FIG. 9 is output. Then, the medal counting means 170 adds one count value. When the count value of the medal count means 170 reaches the upper limit “3”, the credit medal count means 180 adds one count value. Then, the medal one-count process ends. Then, the process returns to step 300.
In step 330, it is determined whether or not the value of the medal passage limit time detection timer TM is greater than zero. In step 330, it is determined whether or not the value of the medal passage limit time detection timer TM is greater than 0 in order to determine whether or not the medal is passing through the first photosensor 66 and the second photosensor 67. It is. If it is determined that the value of the medal passage limit time detection timer TM is greater than 0, the process proceeds to step 331. On the other hand, if it is determined that the value of the medal passage limit time detection timer TM is 0, the process proceeds to step 333.

In step 331, 1 is subtracted from the value of the medal passage limit time detection timer TM. Then, the process proceeds to Step 332.
In step 332, it is determined whether or not the value of the medal passage limit time detection timer TM after the subtraction in step 331 is greater than zero. The reason for determining whether or not the value of the medal passage limit time detection timer TM is greater than 0 in step 332 is to determine whether or not the time is over. Here, even if the value of the medal passage limit time detection timer TM is decremented by 1 in step 331, if it is determined that the value of the medal passage limit time detection timer TM is greater than 0, the process returns to step 315. On the other hand, if it is determined that the value of the medal passage limit time detection timer TM has become 0 as a result of subtracting 1 from the value of the medal passage limit time detection timer TM in step 331, the process proceeds to step 335.

In step 333, it is determined whether a start signal has been output. Here, if it is determined that the start signal has been output, the process proceeds to step 334. On the other hand, if it is determined that the start signal is not output, the process returns to step 315.
In step 334, the medal cannot be inserted. Further, when the medal insertion is disabled, the energization to the cancel coil 63f is stopped, and the swing arm 63d is in the state shown in FIG. 4B. That is, the path of medals inserted from the medal insertion slot 41 is in the direction of the medal return path 62. Then, the medals inserted from the medal insertion slot 41 are guided to the medal return passage 62 and discharged from the medal return slot 33. If the medal insertion is disabled, the medal sensor 65 cannot detect the medal. Then, the medal detection process ends.

  In step 335, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the second photosensor 67 changing from the Lo level to the Hi level means that the medal flowing down the medal path 61 is at a position where the second optical path is completely blocked. , And the first optical path should already be in the position where the light has already been interrupted. At this time, if the signal output from the output terminal of the first photosensor 66 is not Hi level (Lo level), that is, If the light receiving unit of one photosensor 66 does not detect light, it is abnormal. When the signal output from the output terminal of the second photosensor 67 changes from the Lo level to the Hi level, the signal output from the output terminal of the first photosensor 66 is not the Hi level (Lo level). That is, if the light receiving portion of the first photosensor 66 does not detect light, the abnormality determination means 160 determines that the medal with the thread tied is guided upward in the medal path 61 and the like. Is determined. In step 332, when the value of the medal passage limit time detection timer TM becomes 0, the time is over. Then, when the value of the medal passage limit time detection timer TM becomes 0 in step 332, the abnormality determination unit 160 determines that the term is over and determines that there is an abnormality. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

Thus, in the present embodiment, the medal is inserted from the medal insertion slot 41 in the state where the light emission of the first photosensor 66 is stopped and the light emission of the second photosensor 67 is emitted. The light emission control means 150 performs the control for waiting and the control for waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 are caused to emit light. Every time one sheet is detected, it is alternately switched and executed.
In the present embodiment, in the control of waiting for the insertion of a medal from the medal insertion slot 41 with the light emitting portions of both the first photosensor 66 and the second photosensor 67 emitting light, Since a medal detection signal having a similar pattern is output, a medal detection process is performed as in the conventional gaming machine 10.

Further, in this embodiment, when the light receiving unit detects light when the light emitting unit of the first photosensor 66 is stopped, it is determined that there is an abnormality. Thereby, the fraud using a fraudulent instrument can be prevented.
In the present embodiment, when the light receiving unit of the second photosensor 67 stops detecting light when the light emitting unit of the first photosensor 66 is stopped, the first photosensor is detected within a predetermined time. If the light emitting unit 66 emits light and the light receiving unit of the first photosensor 66 detects light at this time, it is determined that there is an abnormality. As a result, it is possible to simultaneously prevent an illegal act using an illegal instrument and an illegal act that illegally increases the number of credits with a medal tied with a thread.

(Fourth embodiment)
(Explanation of drawings)
16 to 18 are flowcharts of the medal detection process in the fourth embodiment.
(Game machine 10)
The gaming machine 10 according to the fourth embodiment has the same hardware configuration as the gaming machine 10 according to the first embodiment.
In addition, the gaming machine 10 according to the fourth embodiment stops the light emission of the light emitting unit of the first photosensor 66 and the light emitting unit of the second photosensor 67 emits light from the medal insertion slot 41. Control for waiting for the insertion of a medal and control for waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 emit light. It is characterized in that it is executed by alternately switching at intervals shorter than the time required for detection of.

(Medal detection process)
The medal detection process in the present embodiment will be described based on the flowcharts shown in FIGS.
In step 400, the medal can be inserted. In addition, when the medal can be inserted, energization to the cancel coil 63f is started. Then, the iron core of the cancel coil 63f pulls the upper piece of the swing arm 63d against the urging force of the spring 63e. As a result, the state shown in FIG. That is, the path of medals inserted from the medal insertion slot 41 is in the downstream direction with respect to the branch portion of the medal path 61. Then, the medal inserted from the medal insertion slot 41 passes through the medal selector 63 and the medal sensor 65 and reaches the medal tank of the hopper unit 70. When the medal insertion is set to be possible, the medal sensor 65 can detect the medal. In addition, from the time when the medal insertion is permitted until the medal is inserted, there is a waiting state for medal insertion. If the medal can be inserted, the process proceeds to step 401.

In step 401, 0 is set in the medal passage limit time detection timer TM. As described above, the fact that 0 is set in the medal passage limit time detection timer TM means that the medal is not passing through the medal passage 61. Then, the process proceeds to Step 402.
In step 402, the light emitting unit of the first photosensor 66 is caused to emit light. Then, the process proceeds to Step 403.
In step 403, after waiting for a certain time, it is confirmed whether the signals output from the output terminals of the first photosensor 66 and the second photosensor 67 are Hi level or Lo level. To be compared. The confirmation and comparison operations are the same as in step 103. In step 402 and step 429, the light emitting part of the first photosensor 66 is caused to emit light. In step 428, the light emitting part of the first photosensor 66 is stopped. Since it takes a certain time to shift from the light-off state to the light-emitting state, or vice versa, the signal output from the output terminal of the first photosensor 66 at step 408 and step 412. In order to prevent malfunctions when determining whether or not the signal is at the Lo level or when determining whether or not the signal output from the output terminal of the first photosensor 66 is at the Hi level in step 418, Here, it is supposed to wait for a certain time. Further, the fixed time waiting in step 403 is approximately one unit time in the medal passage limit time detection timer TM. Then, the process proceeds to step 404.

In step 404, it is determined whether or not the light emitting unit of the first photosensor 66 is emitting light. Here, if it is determined that the light emitting unit of the first photosensor 66 is emitting light, the process proceeds to step 405. On the other hand, if it is determined that the light emitting portion of the first photosensor 66 is not emitting light, the process proceeds to step 408.
In step 405, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Hi level to the Lo level. Specifically, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Hi level to the Lo level before and after waiting for a certain time in Step 403. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 403. If it is determined that the signal output from the output terminal of the first photosensor 66 has changed from the Hi level to the Lo level, the process proceeds to step 406. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 has not changed from the Hi level to the Lo level, the process proceeds to step 411.

  In step 406, it is determined whether the signal output from the output terminal of the second photosensor 67 is at the Hi level. That is, it is determined whether the light receiving unit of the second photosensor 67 is detecting light. Here, when it is determined that the signal output from the output terminal of the second photosensor 67 is at the Hi level, that is, when it is determined that the light receiving unit of the second photosensor 67 is detecting light. The process proceeds to step 407. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 is not Hi level (Lo level), that is, the light receiving unit of the second photosensor 67 has not detected light. If it is determined, the process proceeds to step 410.

In step 407, a predetermined value is set in the medal passage limit time detection timer TM. Then, the process proceeds to step 427.
In step 408, it is determined whether the signal output from the output terminal of the first photosensor 66 is at the Lo level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is not at the Lo level (ie, at the Hi level), that is, the light receiving unit of the first photosensor 66 detects the light. If it is determined, the process proceeds to step 409. On the other hand, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Lo level, that is, when it is determined that the light receiving unit of the first photosensor 66 is not detecting light, Proceed to step 421.

  In step 409, abnormality determination processing is performed. Specifically, when the light emission of the light emitting unit of the first photosensor 66 is stopped, a Lo level signal should continue to be output from the output terminal, and when a Hi level signal is output, It is abnormal. That is, it is abnormal if the light receiving unit detects light when the light emission of the light emitting unit of the first photosensor 66 is stopped. Then, when the Hi-level signal is output from the output terminal when the light emitting unit of the first photosensor 66 is stopped, the abnormality determining unit 160 detects that the light receiving unit detects light. It is determined that there is an abnormality because an illegal act using an illegal instrument is being performed. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 410, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the first photosensor 66 changing from the Hi level to the Lo level means that the medal flowing down the medal path 61 is in a position where it begins to block the first optical path. In this case, the signal output from the output terminal of the second photosensor 67 is not at the Hi level (Lo level), that is, the second optical sensor 67 is not in a position that blocks the second optical path. It is abnormal if the light receiving part of the photo sensor 67 does not detect light. When the signal output from the output terminal of the first photosensor 66 changes from the Hi level to the Lo level, the signal output from the output terminal of the second photosensor 67 is not the Hi level (Lo level). In other words, if the light receiving part of the second photosensor 67 does not detect light, the abnormality determination means 160 determines that the medal with the thread tied is guided upward in the medal path 61, etc. Is determined. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 411, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level before and after waiting for a certain time in Step 403. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 403. If it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Hi level to the Lo level, the process proceeds to step 412. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Hi level to the Lo level, the process proceeds to step 414.

  In step 412, it is determined whether the signal output from the output terminal of the first photosensor 66 is at the Lo level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 has detected light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is not at the Lo level (ie, at the Hi level), that is, the light receiving unit of the first photosensor 66 detects the light. If it is determined, the process proceeds to step 413. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 is a Lo level signal, that is, it is determined that the light receiving unit of the first photosensor 66 is not detecting light. Then, the process proceeds to step 427.

  In step 413, abnormality determination processing is performed. Specifically, when the medal guided downward in the medal path 61 blocks the second optical path, and the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level, the light emission control means 150 causes the light emitting portion of the first photosensor 66 to emit light. At this time, since the medal should be before the first optical path has been blocked, the Lo level signal should continue to be output from the output terminal of the first photosensor 66, and when the Hi level signal is output, It is abnormal. That is, the light receiving unit of the first photosensor 66 should not detect light, and it is abnormal when the light receiving unit detects light. Then, when a Hi level signal is output from the output terminal when the light emitting unit of the first photosensor 66 emits light, that is, when the light receiving unit detects light, the abnormality determination unit 160 binds the yarn. It is determined that the attached medal is abnormal, for example, by guiding the medal passage 61 upward. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 414, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level. Specifically, it is determined whether or not the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level before and after waiting for a certain time in Step 403. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 403. If it is determined that the signal output from the output terminal of the first photosensor 66 has changed from the Lo level to the Hi level, the process proceeds to step 415. On the other hand, if it is determined that the signal output from the output terminal of the first photosensor 66 has not changed from the Lo level to the Hi level, the process proceeds to step 417.

  In step 415, it is determined whether the signal output from the output terminal of the second photosensor 67 is at the Lo level. That is, it is determined whether or not the light receiving unit of the second photosensor 67 has detected light. Here, when it is determined that the signal output from the output terminal of the second photosensor 67 is at the Lo level, that is, when it is determined that the light receiving unit of the second photosensor 67 is not detecting light. Go to step 427. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 is not at the Lo level (Hi level), that is, the light receiving unit of the second photosensor 67 detects light. If it is determined, step 416 follows.

  In step 416, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the first photosensor 66 changing from the Lo level to the Hi level means that the medal flowing down the medal path 61 is at a position where it has blocked the first optical path. And the second optical path should still be in a position where it is still blocked. At this time, if the signal output from the output terminal of the second photosensor 67 is not at the Lo level (Hi level), that is, If the light receiving part of the second photosensor 67 detects light, it is abnormal. When the signal output from the output terminal of the first photosensor 66 changes from the Lo level to the Hi level, the signal output from the output terminal of the second photosensor 67 is not at the Lo level (Hi level). In other words, when the light receiving unit of the second photosensor 67 detects light, the abnormality determination means 160 determines that the medal with the thread tied is guided toward the medal path 61 upward, judge. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

  In step 417, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level. Specifically, it is determined whether or not the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level before and after waiting for a certain time in Step 403. Further, whether or not the change has occurred is determined based on the result of the confirmation and comparison in step 403. If it is determined that the signal output from the output terminal of the second photosensor 67 has changed from the Lo level to the Hi level, the process proceeds to step 418. On the other hand, if it is determined that the signal output from the output terminal of the second photosensor 67 has not changed from the Lo level to the Hi level, the process proceeds to step 421.

  In step 418, it is determined whether the signal output from the output terminal of the first photosensor 66 is at the Hi level. That is, it is determined whether or not the light receiving unit of the first photosensor 66 is detecting light. Here, when it is determined that the signal output from the output terminal of the first photosensor 66 is at the Hi level, that is, when it is determined that the light receiving unit of the first photosensor 66 is detecting light. Go to step 419. On the other hand, when it is determined that the signal output from the output terminal of the first photosensor 66 is not Hi level (Lo level), that is, the light receiving unit of the first photosensor 66 has not detected light. If it is determined, the process proceeds to step 420.

In step 419, a medal one count process is performed. Specifically, when proceeding to step 419, a medal detection signal having a pattern as shown in FIG. 6 or FIG. 9 is output. Then, the medal counting means 170 adds one count value. When the count value of the medal count means 170 reaches the upper limit “3”, the credit medal count means 180 adds one count value. Then, the medal one-count process ends. Then, the process proceeds to step 427.
In step 420, abnormality determination processing is performed. Specifically, the signal output from the output terminal of the second photosensor 67 changing from the Lo level to the Hi level means that the medal flowing down the medal path 61 is at a position where the second optical path is completely blocked. , And the first optical path should already be in the position where the light has already been interrupted. At this time, if the signal output from the output terminal of the first photosensor 66 is not Hi level (Lo level), that is, If the light receiving unit of one photosensor 66 does not detect light, it is abnormal. When the signal output from the output terminal of the second photosensor 67 changes from the Lo level to the Hi level, the signal output from the output terminal of the first photosensor 66 is not the Hi level (Lo level). That is, if the light receiving portion of the first photosensor 66 does not detect light, the abnormality determination means 160 determines that the medal with the thread tied is guided upward in the medal path 61 and the like. Is determined. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.

In step 421, it is determined whether or not the value of the medal passage limit time detection timer TM is greater than zero. In step 421, whether or not the value of the medal passage limit time detection timer TM is greater than 0 is determined by judging whether or not the medal is passing through the first photosensor 66 and the second photosensor 67. To do. If it is determined that the value of the medal passage limit time detection timer TM is greater than 0, the process proceeds to step 422. On the other hand, if it is determined that the value of the medal passage limit time detection timer TM is 0, the routine proceeds to step 424.
In step 422, 1 is subtracted from the value of the medal passage limit time detection timer TM. Then, the process proceeds to Step 423.

  In step 423, it is determined whether or not the value of the medal passage limit time detection timer TM after the subtraction in step 422 is greater than zero. The reason why the value of the medal passage limit time detection timer TM is determined to be greater than 0 in step 423 is to determine whether or not the time is over. Here, even if the value of the medal passage limit time detection timer TM is decremented by 1 in step 422, if it is determined that the value of the medal passage limit time detection timer TM is greater than 0, the process proceeds to step 427. On the other hand, when it is determined that the value of the medal passage limit time detection timer TM has become 0 as a result of subtracting 1 from the value of the medal passage limit time detection timer TM in step 422, the process proceeds to step 426.

In step 424, a determination is made whether a start signal has been output. Here, if it is determined that the start signal has been output, the routine proceeds to step 425. On the other hand, if it is determined that the start signal is not output, the process proceeds to step 427.
In step 425, the medal cannot be inserted. Further, when the medal insertion is disabled, the energization to the cancel coil 63f is stopped, and the swing arm 63d is in the state shown in FIG. 4B. That is, the path of medals inserted from the medal insertion slot 41 is in the direction of the medal return path 62. Then, the medals inserted from the medal insertion slot 41 are guided to the medal return passage 62 and discharged from the medal return slot 33. If the medal insertion is disabled, the medal sensor 65 cannot detect the medal. Then, the medal detection process ends.

In step 426, abnormality determination processing is performed. Specifically, in step 423, when the value of the medal passage limit time detection timer TM becomes 0, the time is over. Then, when the value of the medal passage limit time detection timer TM becomes 0 in step 423, the abnormality determination unit 160 determines that the term is over and that it is abnormal. The operation after the abnormality determination is the same as that in the first embodiment. Then, the abnormality determination process ends.
In step 427, it is determined whether or not the light emitting unit of the first photosensor 66 is emitting light. Here, if it is determined that the light emitting unit of the first photosensor 66 is emitting light, the process proceeds to step 428. On the other hand, if it is determined that the light emitting unit of the first photosensor 66 is not emitting light, the process proceeds to step 429.

In step 428, the light emission of the first photosensor 66 is stopped. Then, the process returns to step 403.
In step 429, the light emitting unit of the first photosensor 66 is caused to emit light. Then, the process returns to step 403.
Thus, in the present embodiment, the medal is inserted from the medal insertion slot 41 in the state where the light emission of the first photosensor 66 is stopped and the light emission of the second photosensor 67 is emitted. The light emission control means 150 performs the control for waiting and the control for waiting for the insertion of a medal from the medal insertion slot 41 in a state in which the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 emit light. It is executed by alternately switching at intervals shorter than the time required for detecting the sheets.

In the present embodiment, in the control of waiting for the insertion of a medal from the medal insertion slot 41 with the light emitting portions of both the first photosensor 66 and the second photosensor 67 emitting light, Since a medal detection signal having a similar pattern is output, a medal detection process is performed as in the conventional gaming machine 10.
Further, in this embodiment, when the light receiving unit detects light when the light emitting unit of the first photosensor 66 is stopped, it is determined that there is an abnormality. Thereby, the fraud using a fraudulent instrument can be prevented.
(Fifth embodiment)
(Explanation of drawings)
FIG. 19 is a time chart of the medal detection signal in the fifth embodiment.

(Game machine 10)
The gaming machine 10 according to the first to fourth embodiments allows only the first photo sensor 66 to stop the light emission of the light emitting unit while allowing the light receiving unit to detect the light. As for the photo sensor 67, it is made impossible to stop the light emission of the light emitting unit while enabling the light detection by the light receiving unit, but the gaming machine 10 according to the fifth embodiment has the first to fourth types. Contrary to the gaming machine 10 according to the embodiment, only the second photo sensor 67 can stop the light emission of the light emitting unit while allowing the light receiving unit to detect the light, and the first photo sensor For 66, light emission from the light emitting unit cannot be stopped while light detection by the light receiving unit is possible.

In addition, the gaming machine 10 according to the fifth embodiment has the same hardware configuration as the first photo sensor 66 and the second photo sensor 67 other than the light emitting units, according to the first to fourth embodiments. Same as 10.
(Medal sensor 65)
As described above, in the present embodiment, the second photosensor 67 can stop the light emission of the light emitting unit while allowing the light receiving unit to detect the light. The light emitting unit cannot stop the light emission while the light receiving unit can detect the light.

(Light emission control means 150)
In the present embodiment, the light emission control means 150 controls the light emission of the light emitting unit of the second photosensor 67. That is, the light emission control unit 150 causes the light emitting unit of the second photosensor 67 to emit light or stops light emission.
In the present embodiment, the light emission control means 150 stops the light emission of the light emitting portion of the second photosensor 67 in the medal insertion waiting state.
Further, in the present embodiment, the light emission control unit 150 stops the light emission of the light emitting unit of the second photosensor 67 within a predetermined time if the light receiving unit of the first photosensor 66 stops detecting light. Then, the light emitting portion of the second photosensor 67 that has stopped emitting light is caused to emit light.

In the present embodiment, the “predetermined time” is the time from when the medal guided downward in the medal path 61 starts to block the first optical path to just before starting to block the second optical path.
That is, in the present embodiment, the predetermined time is from the start of blocking the first optical path to immediately before the start of blocking the second optical path.
In other words, in the present embodiment, the continuation time of the state where the medal flowing down the medal passage 61 blocks the first optical path but does not block the second optical path is a predetermined time.
Further, the predetermined time varies depending on various conditions such as the inclination angle of the medal passage 61, the size of the medal, and the mounting positions of the first photosensor 66 and the second photosensor 67.

In the present embodiment, once the light emission control unit 150 causes the light emission unit of the second photosensor 67 to emit light, the light emission unit of the second photosensor 67 continues to emit light until the medal one count process is completed. In addition, when the medal one count process is finished, a medal insertion waiting state is entered. Then, the light emission control unit 150 stops the light emission of the light emitting unit of the second photosensor 67.
(Medal detection signal)
In the medal insertion waiting state, the light emitting portion of the first photosensor 66 is allowed to emit light, the light emitting portion of the second photosensor 67 is stopped, and the light receiving portion of the first photosensor 66 detects light. When it disappears, the medal detection signal when the light emitting unit of the second photosensor 67 is controlled to emit light will be described based on the time chart shown in FIG.

In the medal insertion waiting state, a Hi level signal continues to be output from the output terminal of the first photosensor 66, but a Lo level signal continues to be output from the output terminal of the second photosensor 67 (in FIG. 19). Before a).
When a medal flowing down the medal passage 61 begins to block the first optical path, the signal output from the output terminal of the first photosensor 66 changes from the Hi level to the Lo level. At this time, the light emitting unit of the second photosensor 67 emits light, but since the medal is usually before the second optical path starts to be blocked, the signal output from the output terminal of the second photosensor 67 is at the Lo level. To Hi level (a in FIG. 19). In addition, a state in which a Lo level signal continues to be output from the output terminal of the first photosensor 66 and a Hi level signal continues to be output from the output terminal of the second photosensor 67 is normally in the medal path 61. The medal that flows down continues until just before blocking the second optical path (between a and b in FIG. 19).

When a medal flowing down the medal passage 61 begins to block the second optical path, the signal output from the output terminal of the second photosensor 67 changes from the Hi level to the Lo level. At this time, since the medal is usually before the first optical path is blocked, the signal output from the output terminal of the first photosensor 66 is at the Lo level (b in FIG. 19). In addition, when the Lo level signal continues to be output from the output terminal of the first photosensor 66 and the Lo level signal continues to be output from the output terminal of the second photosensor 67, the medal path 61 flows down. The medal to continue continues until just before the first optical path is blocked (between bc in FIG. 19).
When the medal flowing down the medal passage 61 finishes blocking the first optical path, the signal output from the output terminal of the first photosensor 66 normally changes from Lo level to Hi level. At this time, since the medal is usually before the second optical path is blocked, the signal output from the output terminal of the second photosensor 67 is at the Lo level (c in FIG. 19). Further, a state in which a Hi level signal continues to be output from the output terminal of the first photosensor 66 and a Lo level signal continues to be output from the output terminal of the second photosensor 67 flows down the medal path 61. The medal continues until just before the second optical path is blocked (between cd in FIG. 19).

When a medal flowing down the medal passage 61 finishes blocking the second optical path, the signal output from the output terminal of the second photosensor 67 normally changes from Lo level to Hi level. At this time, since the medal is usually after blocking the first optical path, the signal output from the output terminal of the first photosensor 66 is at the Hi level (d in FIG. 19). In addition, a state in which a Hi level signal continues to be output from the output terminal of the first photosensor 66 and a Hi level signal continues to be output from the output terminal of the second photosensor 67 is a process of counting one medal. Is continued (after d in FIG. 19).
(Medal counting means 170)
In the present embodiment, when a medal inserted into the medal insertion slot 41 flows down the medal passage 61, passes through the medal selector 63, and passes through the medal sensor 65, a medal detection signal is output. At this time, a medal detection signal having a pattern as shown in FIG. 19 is output. Then, the medal counting means 170 performs a counting operation. Specifically, the medal counting means 170 adds one count value each time a medal detection signal having a pattern as shown in FIG. 19 is output once. In this way, the number of medals inserted into the medal insertion slot 41 is counted.

Further, in the present embodiment, the upper limit value of the count value of the medal counting means 170 is set to “3”.
(Credit medal counting means 180)
The credit medal counting means 180 is for counting the number of medals that are credited.
In the present embodiment, the maximum number of medals inserted is 3 per game. Therefore, when four or more medals are inserted into the medal insertion slot 41, the fourth and subsequent medals are counted as credits by the credit medal counting means 180.

The medal count is the same as that of the medal counting means 170. That is, in this embodiment, when a medal inserted into the medal insertion slot 41 passes the medal sensor 65, a medal detection signal having a pattern as shown in FIG. 19 is output. Each time a medal detection signal having a pattern as shown in FIG. 19 is output once, the credit medal counting means 180 adds one count value.
In the present embodiment, the maximum number of medal credits is 50. For this reason, when the count value of the medal count means 170 reaches “3” and the count value of the credit medal count means 180 reaches “50”, medals inserted into the medal insertion slot 41 thereafter are medal It is guided to the medal return passage 62 by the canceller 64 and discharged from the medal return port 33.

(Abnormality determination means 160)
The abnormality determining means 160 is for determining that an abnormality is detected when the light receiving section corresponding to the light emitting section detects light when the light emission control section 150 stops light emission.
In the present embodiment, the abnormality determination unit 160 detects an abnormality when the light receiving unit of the second photosensor 67 detects light while the light emission control unit 150 stops light emission of the second photosensor 67. judge.
That is, when the light emission of the light emitting part of the second photosensor 67 is stopped, the light receiving part of the second photosensor 67 should normally not detect light, and the light receiving part of the second photosensor 67 is light. Is detected, it is abnormal. Then, when the light receiving unit of the second photosensor 67 detects light when the light emitting unit of the second photosensor 67 is stopped from emitting light, the abnormality determining unit 160 performs an illegal act using an unauthorized instrument. It is determined as abnormal.

More specifically, in the present embodiment, when the light emission of the light emitting portion of the second photosensor 67 is stopped, a Lo level signal should continue to be output from the output terminal of the second photosensor 67. If a Hi level signal is output, it is abnormal. Then, the abnormality determining means 160, when a Hi level signal is output from the output terminal of the second photosensor 67 when the light emitting portion of the second photosensor 67 is stopped, the second photosensor 67. It is determined that the light receiving unit has detected an abnormality, and it is determined that an illegal act using an unauthorized device is being performed.
In the present embodiment, the abnormality determination unit 160 causes the light receiving unit of the second photosensor 67 to emit light when the light emission control unit 150 emits the light emitting unit of the second photosensor 67 that has stopped emitting light. If not detected, it is determined as abnormal.

  In other words, in the present embodiment, when the medal guided downward through the medal path 61 starts to block the first optical path, the second optical path should not be blocked. Further, when the medal guided downward through the medal passage 61 blocks the first optical path, the light emission control means 150 detects that the light receiving control unit 150 does not detect the light. The light emitting unit emits light. At this time, the medal should be before starting to block the second optical path, so the light receiving unit of the second photosensor 67 should detect light. At this time, the second photosensor It is abnormal if 67 light-receiving parts do not detect light. Then, when the light emitting unit of the second photosensor 67 emits light and the light receiving unit of the second photosensor 67 does not detect light, the abnormality determination unit 160 moves the medal with the string up the medal path 61. It is determined that there is an abnormality as being directed toward

  More specifically, in the present embodiment, when a medal guided downward in the medal path 61 blocks the first optical path, the signal output from the output terminal of the first photosensor 66 changes from the Hi level to Lo. When the level is reached, the light emission control means 150 causes the light emitting portion of the second photosensor 67 to emit light. At this time, the medal should be before the second optical path begins to be blocked, so the output terminal of the second photosensor 67 The Hi level signal should continue to be output from the output, and when the Lo level signal is output, it is abnormal. Then, when the Lo level signal is output from the output terminal of the second photosensor 67 when the light emitting unit of the second photosensor 67 emits light, the abnormality determination unit 160 causes the light receiving unit of the second photosensor 67 to It is determined that there is no abnormality, assuming that no light is detected, and that the medal with the thread tied is guided upward in the medal path 61.

The operation after the abnormality determination is the same as in the first to fourth embodiments.
As described above, in the present embodiment, the second photosensor 67 is stopped when light emission from the light emitting unit is stopped and light emission from the light emitting unit is stopped while enabling detection of light by the light receiving unit. When the light receiving unit detects light, it is determined as abnormal. Thereby, the fraud using a fraudulent instrument can be prevented.
In the present embodiment, when the light receiving unit of the first photosensor 66 stops detecting light when the light emitting unit of the second photosensor 67 is stopped, the second photosensor is detected within a predetermined time. If the light emitting unit 67 emits light, and the light receiving unit of the second photosensor 67 does not detect light at this time, it is determined as abnormal. As a result, it is possible to simultaneously prevent an illegal act using an illegal instrument and an illegal act that illegally increases the number of credits with a medal tied with a thread.

  In the fifth embodiment, as in the first embodiment, the light emitting unit of the first photosensor 66 emits light and the light emitting unit of the second photosensor 67 stops emitting light. Switching between the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 may not be performed, and the first photo sensor 66 may be switched as in the second embodiment. The medal detection process includes a state in which the light emitting unit emits light and the light emitting unit of the second photosensor 67 stops emitting light and a state in which the light emitting units of both the first photosensor 66 and the second photosensor 67 emit light. Alternatively, it may be selected and switched based on the random number acquired at the start, and the light emitting unit of the first photosensor 66 is caused to emit light as in the third embodiment, and the second Light emission of photosensor 67 The stop state and the state in which the light emitting portions of both the first photo sensor 66 and the second photo sensor 67 emit light may be alternately switched every time the medal detection process is performed once. As in the fourth embodiment, the light emitting portion of the first photosensor 66 is caused to emit light and the light emitting portion of the second photosensor 67 is stopped, and the first photosensor 66 and the second photosensor 67 You may make it switch alternately the state which made both the light emission parts light-emit many times at high speed during one medal detection process.

(Sixth embodiment)
In the gaming machine 10 according to the sixth embodiment, both the first photo sensor 66 and the second photo sensor 67 can stop the light emission of the light emitting unit while allowing the light detection unit to detect the light. It is a thing.
In addition, the gaming machine 10 according to the sixth embodiment has the same hardware configuration as the first photosensor 66 and the second photosensor 67 other than the light emitting units, according to the first to fifth embodiments. Same as 10.
(Medal sensor 65)
As described above, in the present embodiment, both the first photosensor 66 and the second photosensor 67 are configured so that the light emission from the light emitting unit can be stopped while the light can be detected by the light receiving unit. Yes.

(Light emission control means 150)
In the present embodiment, the light emission control means 150 controls the light emission of the light emitting sections of both the first photosensor 66 and the second photosensor 67. That is, the light emission control unit 150 causes the light emitting units of both the first photosensor 66 and the second photosensor 67 to emit light or stops light emission.
Further, in the present embodiment, when the light emission control means 150 stops the light emission of the light emitting part of the first photosensor 66, the light emission part of the second photosensor 67 emits light and the light emission part of the second photosensor 67 emits light. When the stop is stopped, the light emitting unit of the first photosensor 66 emits light. That is, when the light emission control unit 150 stops light emission of one light emitting unit, the other light emitting unit emits light. Therefore, the light emission control unit 150 does not stop the light emission of the light emitting unit of the first photosensor 66 and the light emission of the light emitting unit of the second photosensor 67 at the same time. That is, the light emission control means 150 does not turn off the lights of both light emitting units simultaneously.

In the present embodiment, the light emission control means 150 detects the light from the light receiving portion of the second photosensor 67 when the light emission portion of the first photosensor 66 is stopped in the medal insertion waiting state. When there is no light, the light emitting portion of the second photosensor 67 that has stopped emitting light is caused to emit light within a predetermined time. In addition, the predetermined time in this case is the predetermined time shown in the first embodiment.
In the present embodiment, the light emission control unit 150 detects light when the light receiving unit of the first photosensor 66 stops light emission when the light emitting unit of the second photosensor 67 is stopped in the medal insertion waiting state. When there is no light, the light emitting portion of the second photosensor 67 that has stopped emitting light is caused to emit light within a predetermined time. Also, the predetermined time in this case is the predetermined time shown in the fifth embodiment.

In the present embodiment, the light emission control means 150 may cause the light emitting units of both the first photosensor 66 and the second photosensor 67 to emit light in the medal insertion waiting state.
Further, in the waiting state for medal insertion, the light emission of the first photosensor 66 is stopped, the light emission of the second photosensor 67 is turned on, and the light reception of the second photosensor 67 detects the light. If it stops, the light emission part of the 1st photosensor 66 is made to emit light, and the light emission part of the 1st photosensor 66 is made to emit light in the waiting state for medal insertion, and the light emission part of the second photosensor 67 is made to emit light. When the light receiving unit of the first photosensor 66 stops detecting light, the first photosensor 66 and the second photosensor are controlled in the control for causing the light emitting unit of the second photosensor 67 to emit light and in the state of waiting for medal insertion. The control for causing both of the light emitting units 67 to emit light is, for example, switching randomly or in a predetermined pattern every time medal detection processing is performed. It can be.

(Medal detection signal)
In the present embodiment, in the medal insertion waiting state, the light emission part of the first photosensor 66 is stopped, the light emission part of the second photosensor 67 is turned on, and the light reception part of the second photosensor 67 is received. If no light is detected, the light emitting unit of the first photosensor 66 may be controlled to emit light. At this time, a medal detection signal as shown in the time chart of FIG. 6 is output.
In the present embodiment, in the medal insertion waiting state, the light emitting portion of the first photosensor 66 is caused to emit light, and the light emission portion of the second photosensor 67 is stopped, so that the first photosensor 66 When the light receiving unit stops detecting light, the light emitting unit of the second photosensor 67 may be controlled to emit light. At this time, a medal detection signal as shown in the time chart of FIG. 19 is output.

Further, in the present embodiment, in the state of waiting for the insertion of medals, there is a case where control is performed to cause both the first photosensor 66 and the second photosensor 67 to emit light. In this case, in FIG. A medal detection signal as shown in the time chart is output.
(Medal counting means 170, credit medal counting means 180)
In the present embodiment, in the medal insertion waiting state, the light emission part of the first photosensor 66 is stopped, the light emission part of the second photosensor 67 is turned on, and the light reception part of the second photosensor 67 is received. If no light is detected, when the medal detection signal as shown in the time chart of FIG. 6 is output when the light emitting unit of the first photosensor 66 is controlled to emit light, the medal counting means 170 On the condition that the count value is less than the upper limit “3”, one count value is added, and when the count value of the medal count means 170 reaches “3”, the credit medal count means 180 counts. One count value is added on condition that the value is less than the upper limit “50”.

  In the present embodiment, in the medal insertion waiting state, the light emitting portion of the first photosensor 66 is caused to emit light, and the light emission portion of the second photosensor 67 is stopped, so that the first photosensor 66 When the light receiving unit stops detecting light, when the medal detection signal as shown in the time chart of FIG. 19 is output when the light emitting unit of the second photosensor 67 is controlled to emit light, the medal counting means 170 However, on the condition that the count value is less than the upper limit value “3”, one count value is added, and when the count value of the medal count means 170 reaches “3”, the credit medal count means 180 Then, one count value is added on condition that the count value is less than the upper limit value “50”.

Further, in the present embodiment, when control for making the light emitting parts of both the first photosensor 66 and the second photosensor 67 emit light in the medal insertion waiting state, as shown in the time chart of FIG. When the medal detection signal is output, the medal count unit 170 adds one count value on condition that the count value is less than the upper limit “3”, and the count value of the medal count unit 170 becomes “ When the value reaches “3”, the credit medal counting means 180 adds one count value on condition that the count value is less than the upper limit “50”.
(Abnormality determination means 160)
In the present embodiment, the abnormality determination unit 160 detects an abnormality when the light receiving unit of the first photosensor 66 detects light while the light emission control unit 150 stops light emission of the first photosensor 66. judge.

In the present embodiment, the abnormality determination unit 160 detects that the light receiving unit of the second photosensor 67 detects light when the light emission control unit 150 stops the light emission of the light emitting unit of the second photosensor 67. Judge as abnormal.
In the present embodiment, the abnormality determination unit 160 causes the light receiving unit of the first photosensor 66 to emit light when the light emission control unit 150 causes the light emitting unit of the first photosensor 66 that has stopped emitting light to emit light. If detected, it is determined as abnormal.
In the present embodiment, the abnormality determination unit 160 causes the light receiving unit of the second photosensor 67 to emit light when the light emission control unit 150 emits the light emitting unit of the second photosensor 67 that has stopped emitting light. If not detected, it is determined as abnormal.

As described above, in the present embodiment, the first photosensor 66 is stopped when light emission from the light emitting unit is stopped and light emission from the light emitting unit is stopped while light detection by the light receiving unit is enabled. When the light receiving unit detects light, it is determined to be abnormal, and the second photosensor 67 stops light emission of the light emitting unit while stopping detection of light by the light receiving unit, and stops light emission of the light emitting unit. When the light receiving unit detects light when the light is on, it is determined as abnormal. Thereby, the fraud using a fraudulent instrument can be prevented.
In the present embodiment, when the light receiving unit of the second photosensor 67 stops detecting light when the light emitting unit of the first photosensor 66 is stopped, the first photosensor is detected within a predetermined time. When the light receiving unit of the first photosensor 66 detects light at this time, it is determined that there is an abnormality, and when the light emission of the second photosensor 67 is stopped, When the light receiving portion of one photosensor 66 stops detecting light, the light emitting portion of the second photosensor 67 is caused to emit light within a predetermined time. At this time, if the light receiving portion of the second photosensor 67 does not detect light, Judge as abnormal. As a result, it is possible to simultaneously prevent an illegal act using an illegal instrument and an illegal act that illegally increases the number of credits with a medal tied with a thread.

(Other embodiments)
In the second embodiment, the control of waiting for the insertion of a medal from the medal insertion slot 41 with the light emission of the first photosensor 66 stopped and the light emission of the second photosensor 67 emitted. Alternatively, either one of the controls for waiting for the insertion of a medal from the medal insertion slot 41 in a state where both the light emitting portions of the first photo sensor 66 and the second photo sensor 67 are made to emit light, the light emission control means 150 is used for 1 Each time it is performed, it is selected and executed based on a random number value. In the third embodiment, the light emission of the light emitting portion of the first photosensor 66 is stopped and the second photosensor 67 is used. Control for waiting for the insertion of a medal from the medal insertion slot 41 while the light emitting section of the first photosensor is turned on, and the medal insertion slot with the light emitting sections of both the first photosensor 66 and the second photosensor 67 being turned on. Waiting for the medal from 41 The door, each time a medal is detected one were to run by switching alternately.

  Here, by appropriately combining or rearranging the second embodiment and the third embodiment, for example, the light emission unit of the first photosensor 66 is stopped and the light emission unit of the second photosensor 67 is used. Control for waiting for the insertion of a medal from the medal insertion slot 41 with the light emitted, or the medal of the medal from the medal insertion slot 41 with the light emitting portions of both the first photosensor 66 and the second photosensor 67 illuminated. Either one of the controls for waiting for insertion can be selected and executed based on a random value every time one medal is detected, and the light emitting unit of the first photosensor 66 can be selected. Control that waits for the insertion of a medal from the medal insertion slot 41 in a state where the light emission is stopped and the light emitting portion of the second photosensor 67 is emitted, and the light emission of both the first photosensor 66 and the second photosensor 67 Part The control of waiting for the insertion of a medal from the medal insertion slot 41 in a state where the light is emitted can be alternately performed every time the game is performed.

  Even in this case, it is possible to simultaneously prevent an illegal act using an illegal instrument and an illegal act that illegally increases the number of credits with a medal tied with a thread.

1 is a block diagram of a gaming machine according to a first embodiment of the present invention. 1 is a front view of a gaming machine according to a first embodiment of the present invention. The front view of the medal processing unit of the gaming machine according to the first embodiment of the present invention. Sectional drawing of the medal selector of the gaming machine according to the first embodiment of the present invention. The conceptual diagram which shows a mode that a medal passes a medal sensor in the gaming machine which concerns on the 1st Embodiment of this invention. The time chart which shows the medal | token detection signal of the gaming machine which concerns on the 1st Embodiment of this invention. The flowchart which shows the outline of operation | movement of the gaming machine which concerns on the 1st Embodiment of this invention. The flowchart which shows the outline of operation | movement of the gaming machine which concerns on the 1st Embodiment of this invention. The time chart which shows the medal | token detection signal of the gaming machine which concerns on the 2nd Embodiment of this invention. The flowchart which shows the outline of operation | movement of the gaming machine which concerns on the 2nd Embodiment of this invention. The flowchart which shows the outline of operation | movement of the gaming machine which concerns on the 2nd Embodiment of this invention. The flowchart which shows the outline of operation | movement of the gaming machine which concerns on the 2nd Embodiment of this invention. The flowchart which shows the outline of operation | movement of the game machine which concerns on the 3rd Embodiment of this invention. The flowchart which shows the outline of operation | movement of the game machine which concerns on the 3rd Embodiment of this invention. The flowchart which shows the outline of operation | movement of the game machine which concerns on the 3rd Embodiment of this invention. The flowchart which shows the outline of operation | movement of the game machine which concerns on the 4th Embodiment of this invention. The flowchart which shows the outline of operation | movement of the game machine which concerns on the 4th Embodiment of this invention. The flowchart which shows the outline of operation | movement of the game machine which concerns on the 4th Embodiment of this invention. The time chart which shows the medal | token detection signal of the game machine which concerns on the 5th Embodiment of this invention.

Explanation of symbols

10 gaming machine 20 chassis
30 Front door 31 Pattern see-through window
32 Medals outlet 33 Medals return port
34 Medal tray 35 Lamp
36 Speaker 40 Operation unit
41 Medal slot 42 Bet switch
42a Single bed switch 42b Max bed switch
43 Start switch 44 Stop switch
45 Checkout switch 50 reel unit
51 rotating reel 60 medal processing unit
61 Medal passage 61a Vertical section
61b Slightly inclined part 61c Bent part
62 Medal return passage
63 Medal selector 63a Upper engagement collar
63b Lower engaging flange 63c Dropout opening
63d swing arm 63e spring
63f Cancel coil 65 Medal sensor
66 1st photo sensor 67 2nd photo sensor
68 Optical center 70 Hopper unit
100 Controller 110 Game control means
120 Role lottery means 130 Stop control means
140 Winning determination means 150 Light emission control means
160 Abnormality determination means 165 Abnormality notification means
170 Medal counting means 180 Credit medal counting means

Claims (7)

A medal passage for guiding a medal inserted into the medal slot in a certain direction;
A first photo sensor provided at a predetermined position in the medal passage;
A gaming machine comprising a second photosensor provided at a predetermined position downstream of the first photosensor in the middle of the medal passage,
Each of the first photosensor and the second photosensor includes a light emitting unit that emits light and a light receiving unit that receives light emitted from the light emitting unit, and the medal passing through the medal path causes the light emitting unit to receive the light. Formed to block the light path,
At least one of the first photosensor and the second photosensor is formed to be capable of stopping the light emission of the light emitting unit while allowing the light detection by the light receiving unit to be detected,
Pachislot machines
Light emission control means for controlling light emission of the light emitting unit;
A gaming machine comprising: an abnormality determining unit that determines that an abnormality is detected when a light receiving unit corresponding to the light emitting unit detects light when light emission of the light emitting unit is stopped by the light emission control unit. The optical path from the light emitting unit to the light receiving unit of the first photosensor and the optical path from the light emitting unit to the light receiving unit of the second photosensor are formed so as to be simultaneously blocked by one medal passing through the medal path,
The light emission control means immediately stops when the light receiving unit corresponding to the light emitting unit emitting light stops detecting light when the light emitting unit of either the first photo sensor or the second photo sensor is stopped. Or, within a predetermined time, let the light emitting part that has stopped emitting light to emit light,
The abnormality determining means determines whether or not there is an abnormality based on whether or not the light receiving unit corresponding to the light emitting unit detects light when the light emitting control unit stops emitting light. The gaming machine according to claim 1, wherein: The light emission control means stops the light emission immediately or within a predetermined time when the light receiving part of the second photosensor stops detecting light when the light emission part of the first photosensor is stopped. Make the light emitting part of the photo sensor emit light,
The abnormality determination unit is characterized in that when the light emitting unit of the first photosensor that has stopped emitting light emits light when the light receiving unit of the first photosensor detects light, the abnormality determination unit determines that there is an abnormality. The gaming machine according to claim 2.   The light emission control means always executes control for waiting for the insertion of a medal from the medal insertion slot in a state where the light emission of the first photosensor is stopped and the light emission unit of the second photosensor is turned on. The gaming machine according to claim 3.   The light emission control means waits for the insertion of a medal from the medal insertion slot in a state where the light emission unit of the first photosensor is stopped and the light emission unit of the second photosensor is turned on, or the first photosensor and the second photosensor Either one of the controls for waiting for the insertion of medals from the medal insertion slot with both the light emitting units of the photosensors illuminated is selected and executed based on the random number every time the game is played. The gaming machine according to claim 3.   The light emission control means waits for the insertion of a medal from the medal insertion slot while stopping the light emission of the light emitting unit of the first photosensor and causing the light emitting unit of the second photosensor to emit light, and the first photosensor and the second photosensor The control of waiting for the insertion of a medal from the medal insertion slot in a state where both light emitting portions of the photosensor are lit is alternately performed every time one medal is detected. 3. The gaming machine according to 3. The light emission control means waits for the insertion of a medal from the medal insertion slot while stopping the light emission of the light emitting unit of the first photosensor and causing the light emitting unit of the second photosensor to emit light, and the first photosensor and the second photosensor Control that waits for the insertion of a medal from the medal insertion slot while both light emitting portions of the photosensor are lit is alternately performed at an interval shorter than the time required for detecting one medal. The gaming machine according to claim 3.

Images