JP2016077731A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To surely detect a dishonest act performed to a token selector.SOLUTION: A token selector 10 comprises: a guide member 13 capable of moving to a support position for supporting tokens M passing through a token channel 11 and a discharge position for discharging the tokens M from the token channel 11; and a first sensor 16 disposed on a position capable of detecting the tokens M supported by the guide member 13. The first sensor 16 has a step-plate state movable member 161 disposed on a wall face part 11a of the token channel 11, and when length of a direction orthogonal to a token M passage direction on the wall face part 11a is wall face part length HN, the movable member 161 has length XN in the direction along the direction orthogonal to the token M passage direction, which is almost equal to the wall face part length HN.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a gaming machine.

A slot machine is known as a gaming machine that uses a gaming medal to play a game.
In this type of slot machine, a medal selector that detects a medal inserted into a predetermined medal slot is provided (see, for example, Patent Document 1).
The medal selector is formed with a flow path for guiding at least a medal inserted from the medal insertion slot into the slot machine, and a detecting means such as a photosensor for detecting the inserted medal is provided in this flow path. It has been.
The slot machine is also provided with a main control unit that controls the progress of the game. When a detection signal output from the detection means indicating that a medal has been detected is input, the number of detected medals is calculated. It counts and this count value is memorized as credit.

JP-A-2005-342397

  However, the conventional gaming machine has room for improvement.

  The gaming machine of the present invention is a gaming machine provided with a medal selector that detects inserted medals, and the medal selector has a medal flow path through which the inserted medals pass and a medal passes through the medal flow path. A medal supported by the guide member, a guide member movable to a support position for supporting the medal and a discharge position for discharging the medal from the medal flow path. A medal flow path having a wall portion facing a circular surface of a medal that passes in a standing state, and the first sensor The movable member has a tread plate-like movable member provided on the wall surface, and when the length of the wall surface in the direction orthogonal to the medal passage direction is the wall surface length, the movable member is orthogonal to the medal passage direction. It is constituted that the length of the direction along the direction is formed in approximately the same length as the wall portion length.

It is a front view which shows the structure of the slot machine in embodiment of this invention. It is a perspective view which shows the internal structure of a slot machine. It is a figure which shows the structure of a medal selector, Comprising: (i) is a front view, (ii) is a rear view. It is a figure which shows the structure of a monitoring sensor, Comprising: (i) is a front view, (ii) is DD sectional drawing of (i). It is sectional drawing (AA sectional drawing of FIG.3 (i)) of a medal selector, Comprising: It is a figure which shows the state in which the blocker is supporting the medal. It is sectional drawing (BB sectional drawing of FIG.3 (i)) of a medal selector, Comprising: It is a figure which shows the state without a medal in a medal flow path. It is sectional drawing (BB sectional drawing of FIG.3 (i)) of a medal selector, Comprising: It is a figure which shows the state which the medal contacted the tread part of the monitoring sensor. It is sectional drawing (BB sectional drawing of FIG.3 (i)) of a medal selector, Comprising: It is a figure which shows the state in which the tread part of the monitoring sensor was accommodated in the recessed part for monitoring sensors by the press from a medal. It is a front view of a medal selector and is a diagram showing the position of a medal when a monitoring sensor, an insertion detection sensor, and an exit sensor are in an ON or OFF state. It is an external appearance perspective view when a medal selector is seen from diagonally downward. It is a wave form chart showing the waveform of detection signal P1 outputted from a surveillance sensor, (i) is a wave form figure of a detection signal when a surveillance sensor detects a regular medal, and (ii) is ON time from a threshold. It is a waveform diagram of a long detection signal. It is sectional drawing (CC sectional drawing of FIG.3 (i)) of a medal selector, Comprising: It is a figure which shows the state without a medal in a medal flow path. It is sectional drawing (CC sectional drawing of FIG.3 (i)) of a medal selector, Comprising: It is a figure which shows the state in which the tread part of the monitoring sensor was accommodated in the recessed part for monitoring sensors by the press from a medal. It is sectional drawing (CC sectional drawing of FIG.3 (i)) of a medal selector, Comprising: It is a figure which shows the state by which the to-be-contacted part of the exit sensor was accommodated in the recessed part for exit sensors by the press from a medal. It is sectional drawing (CC sectional drawing of FIG.3 (i)) of a medal selector, Comprising: It is a figure which shows the state which the medal which flowed back is contact | abutting to the exit sensor. It is a front view of a medal selector, and is a figure showing the state where a disk-like member provided in a fraudulent instrument is located in the vicinity of an insertion detection sensor. It is a figure which shows the waveform diagram and medal | token detection pattern which show the waveform of the detection signals P1-P3 each output from the monitoring sensor, the insertion detection sensor, and the exit sensor. It is sectional drawing (AA sectional drawing of FIG.3 (i)) of a medal selector, Comprising: It is a figure which shows the state by which a blocker does not support a medal and a medal is discharged | emitted. It is a front view of a medal selector, and is a diagram showing the positions of medals detected by an insertion detection sensor and the positions of medals that have been inserted consecutively.

  Hereinafter, preferred embodiments of a gaming machine according to the present invention will be described with reference to the drawings.

[Game machine]
There are various machines such as a slot machine, a sparrow ball, and an arrange ball as a gaming machine equipped with a sensor for detecting an inserted gaming medal. In the present embodiment, the present invention is applied to a slot machine. The case will be described.

  The slot machine of the present embodiment is configured as a revolving type gaming machine that can acquire medals as game media by rotating a plurality of reels, and a medal slot provided in front of the slot machine, A medal selector that detects a medal inserted in the medal slot, and this medal selector is a medal channel through which the inserted medal passes and a photo sensor that detects a medal passing through the medal channel The configuration includes a detection sensor and a monitoring sensor that detects the medal before and after a period in which the insertion detection sensor detects the medal.

  In addition, as shown in FIGS. 1 and 2, the slot machine of the present embodiment is based on the number of medals actually inserted from the medal slot 2 (for example, three) or the credit medal stored internally. When the bet button 2a is operated, the game can be started according to the number of medals (for example, 3) inserted in a signal format. When the start lever 3 is operated (starting operation) in this state, a plurality of reels When the stop button 5 (5a to 5c) corresponding to each of the reels 41a to 41c is pressed, the lottery of the lottery process performed at the operation timing of the start lever 3 is started. Each reel 41a to 41c is controlled to stop with a combination of symbols according to the result, and the presence or absence of a prize is determined based on the stopped combination of symbols. That the medals from the medal payout device 6 in accordance with the result being paid out, and a feasible structure of ordinary slot machine game.

In the slot machine 1 that can realize such a slot machine game, the medal selector 10 that detects a medal inserted into the medal slot 2 and the medal detected based on the detection signal output from the medal selector 10 are detected. A main control unit 7 is provided.
Hereinafter, the configurations of the medal selector 10 and the main control unit 7 of the present embodiment will be described with reference to FIGS.

[Overall configuration of medal selector and main control unit]
As shown in FIGS. 1 to 3, the medal selector 10 includes a medal flow path 11 formed as a path through which the medal M inserted into the medal insertion slot 2 passes while rolling in a standing state, and the start lever 3. A blocker that removes the medal M from the medal flow path 11 and guides the medal M to the medal payout opening 6a by turning off the solenoid 12 provided on the back side of the medal selector 10 based on the start signal output by the operation. 13, an insertion port side detection sensor 14 that is provided upstream of the blocker 13 in the medal flow path 11 and detects the medal M inserted into the medal insertion slot 2, and downstream of the blocker 13 in the medal flow path 11. And a blocker 13 provided with an insertion detection sensor 15 that is a photo sensor for detecting the medal M passing through the medal flow path 11. The monitoring sensor 16 that is provided at a position where the held medal M can be detected and detects the medal M, and the medal exit through which the medal M that has passed through the medal flow path 11 goes out of the medal selector 10. 18 (see FIG. 3, FIG. 10, etc.) and an exit sensor 17 that detects the medal M.

  In this configuration, when the insertion port side detection sensor 14, the insertion detection sensor 15, the monitoring sensor 16, and the outlet sensor 17 detect the medal M passing through the medal flow path 11, the detection port 14 outputs a detection signal indicating that it has been detected. Send to the main control unit 7.

The main control unit 7 includes a main board on which a control chip in which a main CPU, a main ROM, a main RAM, and the like are integrated, a board case that houses the main board, and the like, and each sensor provided in the medal selector 10. Drum units provided in the housing 1b based on the detection signals output from 14 to 17 and the signals output from the operation means such as the start lever 3 and the stop button 5 are received. The slot machine game can be advanced by controlling each device such as 4 and the medal payout device 6.
The main control unit 7 receives detection signals output from the sensors 14 to 17 and detects that the medal M has passed through the medal flow path 11 based on the detection signals. The occurrence of abnormality can also be detected.

  Next, detailed configurations of the medal selector 10 and the main control unit 7 will be described.

[Detailed configuration of medal selector and main control unit]
Here, the following items will be described.
(A) Monitoring sensor (b) Outlet sensor (c) Detection of medals in the main control unit (d) Blocker (e) Medal flow path (f) Input port side detection sensor

(A) Structure and operation of monitoring sensor (a-1) The monitoring sensor 16 functions as the first sensor of the present invention, and detects the medal M passing through the medal flow path 11.
As shown in FIGS. 3 (i) and 3 (ii), the monitoring sensor 16 detects a displacement of the movable member 161 that is displaced by the contact of the medal M passing through the medal flow path 11 and the displacement of the movable member 161. Displacement detection sensor 162.
As shown in FIGS. 4 (i) and 4 (ii), the movable member 161 has a tread plate-like shape (flap shape) that is displaced when the medal M passing through the medal flow path 11 comes into contact and receives a pressure from the medal M. It has a tread plate portion 161a, a shaft support portion 161b that is pivotally supported by a base portion 19 that is a base member of the medal selector 10, and a detected portion 161c that is displaced in accordance with the displacement of the tread plate portion 161a.
When the displacement detection sensor 162 detects the displacement of the detected portion 161 c of the movable member 161, the displacement detection sensor 162 outputs a detection signal indicating that the medal M has been detected and sends it to the main control portion 7.

Here, the movable member 161 is provided at the next location in the medal flow path 11.
The medal flow path 11 has a wall surface portion 11a that faces the circular surface of the medal M that passes in a standing state. Moreover, the wall surface part 11a has the wall surface part surface 11b which is a surface facing the circular surface of the medal M which passes in a standing state (refer FIG. 3 (i) and FIG. 5).

Of the movable member 161, the shaft support portion 161b and the detected portion 161c are located behind the wall surface portion 11b in the wall surface portion 11a of the medal flow path 11 (see FIG. 6).
On the other hand, the tread plate 161a is generally provided in a state along the wall surface 11b of the wall 11a of the medal channel 11, but a part protrudes obliquely forward from the wall 11b. It is provided in the state.

The configuration of the tread plate portion 161a will be further described.
The tread plate portion 161a is a thin plate-like member, and when one surface of the thin plate (one surface of the surfaces orthogonal to the thickness direction) is a flow channel side surface 161d, the flow channel side surface 161d is It is provided in the wall surface part 11a in the state which follows the surface direction of the wall surface part surface 11b.
However, the flow path side surface 161d of the tread plate portion 161a is not a flat surface with no undulations, but is formed as a surface that gradually protrudes diagonally forward from the wall surface 11b.

Here, in the case where the tread plate portion 161a is provided on the wall surface portion 11a, among the four sides of the rectangular channel-side surface 161d, the side facing the upstream side of the medal channel 11 is defined as the upstream side 161e, and this upstream side A side facing 161e, that is, a side facing the downstream side of the medal flow path 11 is defined as a downstream side 161f (see FIGS. 4 and 6). When the flow path side surface 161d is traced from the upstream side 161e toward the downstream side 161f, the flow path side surface 161d can be divided into four surfaces according to the inclination angle.
The first surface 161g is a surface having the upstream side 161e as one side, and a virtual plane including the upstream side 161e and the downstream side 161f is a tread board virtual surface FK (FIG. 4 (ii)). Reference), which is a surface inclined in a direction protruding from the tread plate virtual surface FK.
The second surface 161h is a surface that is adjacent to the first surface 161g, and is a surface that is inclined in a direction recessed from the tread plate virtual surface FK.
The third surface 161i is a surface that is adjacent to the second surface 161h, and is a surface that is inclined in a direction protruding from the tread plate virtual surface FK.
The fourth surface 161j is a surface that is adjacent to the third surface 161i and has the downstream side 161f as one side, and is inclined in a direction recessed from the tread plate virtual surface FK.

When the tread plate portion 161a is provided on the wall surface portion 11a, it is provided in the following state.
Here, as shown in FIG. 6, a surface including the wall surface 11 b of the wall surface 11 and the surface when the wall surface 11 b is virtually extended in the surface direction is defined as a wall surface virtual surface HK. . In addition, a recess formed in the wall surface portion 11a where the tread plate portion 161a is provided is referred to as a monitoring sensor recess portion 11c. In this case, the first surface 161g of the tread plate 161a is provided inside the monitoring sensor recess 11c and inside the wall surface imaginary surface HK. The second surface 161h is provided at a position along the wall surface virtual surface HK inside the monitoring sensor recess 11c. The third surface 161i is provided at a position that intersects the wall surface virtual surface HK. That is, a part of the third surface 161i (the side in contact with the second surface 161h) is provided inside the monitoring sensor recess 11c, and the other part (the side in contact with the fourth surface 161j) is monitored. Provided outside the sensor recess 11c. The fourth surface 161j is provided outside the monitoring sensor recess 11c.

By providing the tread plate portion 161a at such a position, the medal M passing through the medal flow path 11 contacts the third surface 161i of the tread plate portion 161a, and the medal M presses the third surface 161i while flowing down. By doing so, the said footboard part 161a displaces (refer FIGS. 6-8).
That is, the tread plate portion 161a has the first surface 161g, the second surface 161h, and a part of the third surface 161i located inside the monitoring sensor recess 11c, and the other of the third surface 161i. And the fourth surface 161j are positioned so as to protrude obliquely outside the monitoring sensor recess 11c, while the medal M passes through the medal flow path 11 and the wall surface imaginary surface HK. Pass along. For this reason, the medal M comes into contact with the third surface 161i of the tread plate 161a when the tip of the medal M in the flow-down direction approaches the monitoring sensor recess 11c (see FIG. 7).

The third surface 161i of the tread plate portion 161a is an inclined surface, and the shaft support portion 161b is formed at a position along the upstream side 161e on the back surface of the tread plate portion 161a. When the medal M abutting against the surface 161i presses the third surface 161i to further flow down, the tread plate portion 161a rotates about the central axis of the shaft support portion 161b, and the third surface 161i and the fourth surface The entire tread plate 161a including the surface 161j is housed in the monitoring sensor recess 11c (see FIG. 8).
Note that the shaft support 161b is formed at a position along the upstream side 161e on the back surface of the tread plate 161a. Further, the axial direction of the central axis passing through the shaft supporting portion 161b is a direction along the upstream side 161e. As a result, the tread plate 161a is rotatable about the central axis of the shaft support 161b.

When the tread plate 161a is rotated and displaced about the central axis of the shaft support 161b, the detected part 161c is also displaced. The displacement detection sensor 162 that has detected the displacement of the detected portion 161c outputs a detection signal indicating that the medal M has been detected.
On the other hand, after the entire tread plate portion 161a is accommodated in the monitoring sensor recess 11c, the tread plate portion 161a does not exist in the forward direction of the medal M, so that the medal M continues to flow down the medal flow path 11, It passes through the medal outlet 18 and enters the medal guiding passage 20 connected to the outside.
Further, the movable member 161 rotates around the central axis of the shaft support portion 161b by the urging force of the urging member 163 when the medal M does not come into contact with the tread plate portion 161a and is no longer pressed from the medal M. A part of the tread plate 161a (a part of the third surface 161i and a fourth surface 161j) moves from the inside of the monitoring sensor recess 11c to the outside and returns to a state of protruding obliquely forward from the wall surface virtual surface HK. (See FIG. 6).

As described above, the monitoring sensor 16 can detect the medal M passing through the medal flow path 11, but the tread board 161 a further detects the medal M supported by the blocker 13 in the medal flow path 11. It is provided at a position where it can be performed.
As shown in FIG. 9, when the medal M passes through the medal channel 11, the medal M is supported by the blocker 13 in a part of the medal channel 11 (medal “M11” shown in FIG. 9). Then, the medal M is supported by the blocker 13, and the tip in the flow direction comes into contact with the third surface 161 i of the tread plate portion 161 a of the movable member 161 of the monitoring sensor 16. Thereafter, as the medal M further flows down, the tread plate portion 161a is displaced, and the displacement of the detected portion 161c due to this displacement is detected by the displacement detection sensor 162.

For the displacement detection sensor 162, for example, a sensor or a switch that can detect the displacement of the detected portion 161c of the movable member 161, such as a photo sensor, can be used.
Further, in a state where the medal M is not in contact, the shaft support portion 161b is maintained so that a part of the tread plate portion 161a protrudes obliquely forward from the wall surface 11b of the wall surface portion 11a of the medal flow passage 11. Is provided with an urging member 163 (see FIG. 4 (ii)). For the urging member 163, for example, a torsion spring or the like can be used.

(A-2) Features of the monitoring sensor The monitoring sensor 16 has the structure described in (a-1) and operates as described in (a-1). I have.
Here, the following items will be described.
(A-21) Length in a direction along the direction orthogonal to the passing direction of the medal M in the tread board 161a (a-22) Positional relationship between the tread board 161a and the insertion detection sensor 15 (a-23) Monitoring sensor Time when 16 detects medal M and fraud detection

(A-21) Length in a direction along the direction orthogonal to the passing direction of the medal M in the tread board portion 161a As one of the features of the monitoring sensor 16, the passing direction of the medal M in the tread plate portion 161a of the movable member 161 The length XN in the direction along the direction RT orthogonal to the MR is the wall surface length HN of the wall surface portion 11a of the medal channel 11 (the length in the direction along the direction RT of the wall surface portion 11a orthogonal to the passing direction MR of the medal M). 3) (see FIG. 3 (i)).
In other words, the length XN of the tread plate 161a is as follows.
Of the directions orthogonal to the direction MR in which the medal M passes through the medal flow channel 11, the direction along the wall surface 11b of the wall surface portion 11a is defined as a flow channel orthogonal direction RT. And the length of the wall surface part 11a in the direction along the channel orthogonal direction RT is defined as the wall surface part length HN. At this time, the tread plate 161a of the movable member 161 is formed such that the length XN in the direction along the flow path orthogonal direction RT is substantially the same as the wall surface length HN.
In addition, “the length XN of the tread plate 161a is substantially the same length as the wall surface length HN” means that the length XN is the same length as the wall surface length HN and the length XN. Includes a length slightly shorter than the wall surface length HN and a length XN slightly longer than the wall surface length HN. The length XN of the tread plate 161a shown in FIG. 3 (i) is slightly shorter than the wall surface length HN.

Thus, by setting the length XN of the tread plate portion 161a to substantially the same length as the wall surface portion length HN, it is possible to reliably detect the medal M passing through the place where the tread plate portion 161a is installed.
That is, when the medal M reaches the recess 11c for the monitoring sensor in the middle of flowing down the medal flow path 11, and when the tip in the flow direction of the medal M contacts the third surface 161i of the tread plate portion 161a, The tread plate portion 161a is present facing the circular surface of the medal M (the circular surface on the left side in the flow direction), but the tread plate portion 161a is present at a position facing the top of the circular surface of the medal M, Further, the tread plate portion 161a is also present at a position facing the lower portion of the circular surface of the medal M, and the tread plate portion 161a is present at a position facing any position on the circular surface of the medal M in this way. Therefore, the monitoring sensor 16 having the tread plate portion 161a can reliably detect the medal M.

In addition, by making the length XN of the tread plate portion 161a substantially the same length as the wall surface portion length HN in this way, it is possible to reliably detect an unauthorized instrument inserted at a location where the tread plate portion 161a is installed.
There are various types of fraudulent instruments, for example, there are those in which the shape of the fraudulent instrument is formed in a shape that approximates a regular medal M. Such an improper instrument has an LED attached at a predetermined location. The improper instrument is inserted from the medal slot 2 and the LED is inserted into the light emitting part 15a and the light receiving part 15b (photo sensor) 15 ( And the LED is blinked, so that the insertion detection sensor 15 outputs a detection signal corresponding to the blinking of the LED, and the main control unit 7 determines the medal based on the detection signal. It is erroneously determined that M has been detected. Then, the fraudulent instrument performs a fraudulent act of fraudulently increasing the number of credits by repeatedly turning on and off the LED.
Since such an improper instrument is formed in a shape that approximates the shape of the medal M, when it is inserted into the medal insertion slot 2 and tries to reach the vicinity of the insertion detection sensor 15, the tread plate portion 161a of the monitoring sensor 16 is used. Be sure to touch. Thereby, the monitoring sensor 16 can detect the unauthorized instrument reliably.
As will be described later in (a-23), such an unauthorized device stays in the vicinity of the insertion detection sensor 15 for a predetermined time in order to raise the credit illegally. Therefore, when the ON time of the detection signal output from the monitoring sensor 16 continues for a predetermined time or more, the main control unit 7 can determine that an abnormality has occurred in the medal selector 10.

Furthermore, by making the length XN of the tread plate portion 161a substantially the same as the wall surface length HN in this way, the monitoring sensor 16 can also detect the illegal device formed in a shape other than the shape of the medal M. Can be detected when it passes through the installation position of the tread plate portion 161a.
For example, it is assumed that the illegal device or a part thereof is formed in a rod shape or a tube shape. When such an improper instrument is inserted into the medal insertion slot 2 and attempts to reach the input detection sensor 15 through the medal flow path 11, the rod-like portion of the illegal instrument is in the vicinity of the input detection sensor 15. It is located only at the upper part of the medal flow path 11 and not at the lower part.
On the other hand, the tread plate portion 161a of the monitoring sensor 16 has the length XN of the tread plate portion 161a substantially the same as the wall surface length HN. For this reason, even if the illegal instrument is located only in the upper part of the medal flow path 11, since the tread plate part 161a is located in this upper part, the illegal instrument always comes into contact with the tread plate part 161a, The monitoring sensor 16 can reliably detect the unauthorized device.
Further, even when the rod-shaped portion or the like of the unauthorized device is located only at the lower part of the medal flow path 11, the unauthorized device is placed on the foot plate 161a because the foot plate portion 161a is positioned at the lower portion. The monitoring sensor 16 can surely detect the unauthorized device.
In this way, the monitoring sensor 16 has the length XN of the tread plate portion 161a substantially the same as the wall surface length HN. Therefore, regardless of the shape of the improper instrument, It is possible to reliably detect illegal devices located in the vicinity.

(A-22) Positional relationship between the footboard 161a and the making detection sensor 15 As another feature of the monitoring sensor 16, there is a positional relationship with the making detection sensor 15.
The insertion detection sensor 15 functions as the second sensor of the present invention and detects the medal M passing through the medal flow path 11.
The monitoring sensor 16 is arranged at a position where the medal M is detected while the insertion detection sensor 15 is detecting the medal M. In other words, the positional relationship is such that the insertion detection sensor 15 detects the medal M in at least a part of the period in which the monitoring sensor 16 detects the medal M.

In order to realize such a positional relationship, the tread plate 161a has a boundary 161k, which is a boundary between the second surface 161h and the third surface 161i, located on the upstream side of the making detection sensor 15, and is downstream. The side edge 161f is located downstream of the making detection sensor 15 (see FIG. 9).
By arranging in such a positional relationship, the monitoring sensor 16 and the insertion detection sensor 15 detect the medal M in the following order.
When the medal M flowing down the medal flow path 11 reaches the concave portion 11c for the monitoring sensor, and the tip of the medal M in the flowing direction comes into contact with and presses the third surface 161i of the tread plate portion 161a, the monitoring sensor 16 is The medal M is detected (medal “M11” shown in FIG. 9). Next, when the medal M enters between the light emitting unit 15a and the light receiving unit 15b in the insertion detection sensor 15, the insertion detection sensor 15 detects the medal M (medal “M12” shown in FIG. 9). Further, when the medal M flows down and passes between the light emitting unit 15a and the light receiving unit 15b, the insertion detection sensor 15 ends the detection of the medal M (medal “M14” illustrated in FIG. 9). Then, when the rear end in the flow direction of the medal M passes the downstream side 161f of the flow path side surface 161d of the tread plate portion 161a, the monitoring sensor 16 ends the detection of the medal M (medal “M16” shown in FIG. 9). .

By making the positional relationship between the footboard 161a and the making detection sensor 15 such a relationship, the following effects can be obtained.
The fraudulent instrument described in (a-21) positions the LED of the fraudulent instrument between the light emitting unit 15a and the light receiving unit 15b of the insertion detection sensor 15. Then, the unauthorized device stays in the vicinity of the insertion detection sensor 15 for a predetermined time and causes the insertion detection sensor 15 to malfunction.
In this case, since the unauthorized device only needs to have its own LED positioned between the light emitting unit 15a and the light receiving unit 15b of the insertion detection sensor 15, the position indicated by M12 in the medal M illustrated in FIG. Or it may be in the position shown in M14.
Thus, it is conceivable that the unauthorized device stays in the vicinity of either the upstream side or the downstream side with respect to the installation position of the insertion detection sensor 15.

On the other hand, the tread plate portion 161a of the monitoring sensor 16 is provided at the locations where the boundary 161k and the downstream side 161f are respectively described.
For example, the boundary 161k is provided on the upstream side with respect to the installation position of the insertion detection sensor 15. For this reason, the monitoring sensor 16 can detect an improper instrument located upstream from the installation position of the insertion detection sensor 15.
The downstream side 161 f is provided on the downstream side with respect to the installation position of the making detection sensor 15. For this reason, the monitoring sensor 16 can detect an improper instrument located downstream from the installation position of the insertion detection sensor 15.
In this way, the monitoring sensor 16 can detect both an unauthorized instrument located upstream from the installation position of the insertion detection sensor 15 and an unauthorized instrument located downstream. For this reason, the monitoring sensor 16 can detect the said unauthorized device reliably.

(A-23) Time during which the monitoring sensor 16 detects the medal M and fraud detection When the monitoring sensor 16 detects the medal M or the fraudulent instrument, the detection signal P1 is shifted from OFF to ON, and detection indicating this ON. The signal P1 is sent to the main control unit 7.
When the detection signal P1 is input, the main control unit 7 measures the time during which the detection signal P1 is ON as the ON time.
The main control unit 7 compares the ON time of the detection signal P1 with a threshold value, and determines that the monitoring sensor 16 has detected a regular medal M when the ON time is shorter than the threshold value. On the other hand, when the ON time of the detection signal P1 exceeds the threshold value, the main control unit 7 determines that an abnormality has occurred in the medal selector 10 (see FIG. 11).

The reason for making such a determination is as follows.
As described above, the monitoring sensor 16 can detect the medal M detected by the insertion detection sensor 15. In addition, the monitoring sensor 16 can also detect an unauthorized device that the insertion detection sensor 15 misrecognizes as a medal M.
Here, the time for the monitoring sensor 16 to detect the regular medal M is a short time. This is because the medal M inserted into the medal insertion slot 2 passes through the medal flow path 11 of the medal selector 10 while rolling in the standing state.
On the other hand, since the unauthorized device needs to increase the number of credits, it stays in the vicinity of the insertion detection sensor 15 for a predetermined time.
Therefore, a time slightly longer than the time for which the monitoring sensor 16 detects the regular medal M is set as a threshold, and the ON time of the detection signal P1 sent from the monitoring sensor 16 is compared with the threshold. And when ON time is shorter than a threshold value, the main-control part 7 can determine with what the monitoring sensor 16 detected is the regular medal M (refer FIG.11 (i)). On the other hand, when the ON time is longer than the threshold value, the main control unit 7 can determine that what is detected by the monitoring sensor 16 is something other than the regular medal M, and an abnormality has occurred in the medal selector 10 (FIG. 11). (See (ii)).

When the main control unit 7 determines that an abnormality has occurred in the medal selector 10, the main control unit 7 executes a predetermined process.
For example, the main control unit 7 outputs a signal indicating that an abnormality has occurred to the outside of the slot machine 1. A device that receives this signal (for example, a game hall management device that aggregates and manages information related to games) executes a predetermined notification indicating that an abnormality has occurred based on the signal. The store clerk who has recognized this notification can take appropriate measures against the abnormality.
Further, the main control unit 7 sends a signal indicating that an abnormality has occurred to the sub-control unit 8. Accordingly, the sub-control unit 8 notifies the occurrence of an abnormality by outputting an alarm sound in the slot machine 1 or causing the liquid crystal surface unit to have an error surface. The store clerk who has recognized this notification can take appropriate measures against the abnormality.
Furthermore, when the main control unit 7 determines that an abnormality has occurred, the main control unit 7 can stop the progress of the game. As a result, it is possible to prevent an unauthorized credit from being raised later by an unauthorized device, and it is possible to suppress damage to the game hall.

(B) Structure and operation of outlet sensor (b-1) The outlet sensor 17 functions as the third sensor of the present invention, and detects the medal M passing through the medal flow path 11.
The outlet sensor 17 is provided downstream of the blocker 13 in the medal flow path 11, and the medal M flowing down the medal selector 10 is connected to the medal guide path 20 connected to the outside of the medal selector 10. It is provided in the vicinity of the medal outlet 18 (see FIG. 3, FIG. 10, etc.) formed as an opening through which the user wants to advance.

The outlet sensor 17 includes a movable member 171 that is displaced by contact of the medal M passing through the medal flow path 11, and a displacement detection sensor 172 that detects the displacement of the movable member 171 (FIG. 3 (i)). ) And (ii)).
The movable member 171 includes a contacted portion 171a that is displaced when the medal M passing through the medal channel 11 comes into contact with the medal M and receives a pressure from the medal M, and a shaft support portion 171b that is pivotally supported by the base portion 19 of the medal selector 10. , And a detected portion 171c that is displaced in accordance with the displacement of the contacted portion 171a.
The contacted portion 171a is a rod-shaped portion protruding from the shaft support portion 171b, and is formed in a shape in which a middle portion of the rod is bent at a predetermined angle.
When the displacement detection sensor 172 detects the displacement of the detected portion 171 c of the movable member 171, the displacement detection sensor 172 sends a detection signal indicating that the medal M has been detected to the main control portion 7.

Here, the movable member 171 is provided at the next location in the medal flow path 11.
Of the movable member 171, the shaft support 171b and the detected portion 171c are located on the back side of the wall surface portion 11a of the medal flow path 11 (see FIG. 12).
In contrast, the contacted portion 171a is provided at the following location.
A surface including the wall surface 11b of the wall surface 11a and the surface when the wall surface 11b is virtually extended in the plane direction is defined as a wall surface virtual surface HK, and the contacted portion 171a is provided on the wall surface 11a. If the recess formed in the portion to be provided is the exit sensor recess 11d, the portion close to the shaft support portion 171b (the end portion of the contacted portion 171a) of the rod-like contacted portion 171a is the outlet sensor recess 11d. The inner portion is provided on the inner side of the wall surface imaginary surface HK, and the portion of the contacted portion 171a beyond the bent portion (the tip portion of the contacted portion 171a) is provided outside the outlet sensor recess 11d.
Further, when the wall surface 11b of the wall surface portion 11a is viewed from the front, the end portion and the tip portion of the contacted portion 171a are oriented so that the end portion faces the upstream side of the medal flow path 11 and the tip portion is a medal. The direction is such that it faces the downstream side of the flow path 11.

By providing the contacted part 171a in such a position and orientation, the medal M passing through the medal flow path 11 contacts the contacted part 171a, and the medal M presses the contacted part 171a while flowing down. Thus, the contacted portion 171a is displaced.
That is, the contacted portion 171a has a terminal portion located inside the outlet sensor recess 11d and a tip portion positioned in a state of protruding obliquely outside the outlet sensor recess 11d. The medal M passes along the virtual wall surface HK when passing through the medal flow path 11. Therefore, the medal M comes into contact with the contacted portion 171a when the lower end of the medal M in the flow-down direction reaches the outlet sensor recess 11d (see FIG. 13).

  The contacted portion 171a is inclined in the direction toward the downstream side of the medal flow path 11, and the shaft support portion 171b is formed continuously with the end portion of the contacted portion 171a. Therefore, when the medal M that is in contact with the contacted portion 171a presses the contacted portion 171a to further flow down, the contacted portion 171a rotates about the central axis of the shaft support portion 171b, and the contacted portion 171a. Is housed in the outlet sensor recess 11d (see FIG. 14).

When the contacted portion 171a is rotated and displaced about the central axis of the shaft support portion 171b, the detected portion 171c is also displaced. The displacement detection sensor 172 that has detected the displacement of the detected portion 171c outputs a detection signal indicating that the medal M has been detected.
On the other hand, after the entire contacted portion 171a is accommodated in the outlet sensor recess 11d, the contacted portion 171a does not exist in the forward direction of the medal M, so that the medal M further flows down the medal channel 11. Then, it passes through the medal outlet 18 and enters the medal guiding passage 20 connected to the outside.
Further, when the medal M does not contact the contacted portion 171a and is no longer pressed by the medal M, the movable member 171 rotates about the central axis of the shaft support portion 171b by the biasing member 173. Then, the tip portion of the contacted portion 171a returns to a state of protruding outward from the outlet sensor recess 11d (see FIG. 12).

The displacement detection sensor 172 can be, for example, a sensor or a switch that can detect the displacement of the detected portion 171c of the movable member 171 such as a photo sensor.
Further, in a state where the medal M is not in contact, the shaft support portion is maintained so that a part of the contacted portion 171a protrudes obliquely forward from the wall surface 11b of the wall surface portion 11a of the medal flow channel 11. A biasing member 173 is provided at 171b (see FIG. 12). For the urging member 173, for example, a torsion spring or the like can be used.

(B-2) Function of outlet sensor The outlet sensor 17 has the structure described in (b-1) and operates as described in (b-1). Have.
(B-21) Function to prevent reverse flow of medal M (b-22) Function to prevent unauthorized use

(B-21) Function to prevent backflow of medal M This function is detected by the insertion detection sensor 15 and then the medal M that has gone out from the medal exit 18 (or has come out from the medal exit 18) This is a function for preventing the medal M) from going back into the medal outlet 18 for some reason and being detected again by the insertion detection sensor 15 and being counted.

As described above, the contacted portion 171a of the movable member 171 of the outlet sensor 17 has a rod-shaped tip portion protruding from the inside of the outlet sensor recess 11d toward the outside and protruding in the direction toward the medal outlet 18. It is provided in such a state.
For this reason, when the medal M that has gone out from the medal outlet 18 flows backward and enters the medal outlet 18, the lower side surface of the medal M contacts the tip of the contacted portion 171a as shown in FIG. And further entry is blocked.
Thereby, the backflow beyond the medal M is prevented. And the double count of the medal M accompanying the reverse flow of the medal M is prevented.

(B-22) Function to prevent the use of unauthorized equipment In order to explain this function, the configuration of the unauthorized equipment will be described first. The unauthorized appliance described here is an unauthorized appliance called a so-called windmill.
As shown in FIG. 16, the dishonest instrument has a disk-shaped member.
The disc-shaped member has a notch formed at a part of the periphery.
The cutout is a portion cut out in the direction from the peripheral edge toward the center of the disk.
This disk-shaped member is housed in a case (not shown) formed in a size capable of flowing down the medal flow path 11, and when inserted into the medal insertion slot 2, it passes through the medal flow path 11. , And stops at the position where the insertion detection sensor 15 is provided.
After the case stops, when a regular medal M is inserted into the medal slot 2, the leading end of the regular medal M collides with the rear end surface of the case. Along with this collision, the disk-shaped member starts to rotate inside the case.

The disk-shaped member is located between the light emitting unit 15a and the light receiving unit 15b of the insertion detection sensor 15. For this reason, normally, the light emitted from the light emitting portion 15a is blocked, and the light receiving portion 15b is prevented from receiving light.
However, when the disk-shaped member rotates and the notch reaches between the light emitting unit 15a and the light receiving unit 15b, the light emitted from the light emitting unit 15a reaches the light receiving unit 15b without being blocked, and the light receiving unit 15b receives the light. When the disk-shaped member further rotates, the disk-shaped member blocks the light emitted from the light emitting unit 15a and blocks the light reception by the light receiving unit 15b.
By rotating the disk-like member in this manner, the light emitted from the light emitting portion 15a is repeatedly blocked and passed, and the light receiving portion 15b is repeatedly received and not received light. Is a signal that repeats ON and OFF. The main control unit 7 that has received this detection signal erroneously determines that a plurality of medals M have been detected by the insertion detection sensor 15 based on the detection signal being repeatedly turned ON and OFF.
As a result, the credit is illegally raised, and the game is illegally performed.

For such unauthorized devices, the outlet sensor 17 effectively prevents its use.
In order to cause the insertion detection sensor 15 to malfunction, the unauthorized device always stops in a state where it enters between the light emitting portion 15a and the light receiving portion 15b of the insertion detection sensor 15. And when a disk-shaped member rotates, the notch formed in this will also rotate along the periphery of a disk-shaped member.
On the other hand, the contacted portion 171 a of the movable member 171 of the outlet sensor 17 is provided in the vicinity of the medal outlet 18 on the downstream side of the medal flow path 11, similarly to the insertion detection sensor 15. Further, the contacted portion 171 a of the outlet sensor 17 is provided in the vicinity of a position facing the insertion detection sensor 15 via the medal flow path 11. For this reason, when the unauthorized device stops at the position where the input detection sensor 15 can detect, the unauthorized device contacts the contacted portion 171a, and the outlet sensor 17 detects the unauthorized device.
Further, the contacted portion 171 a is provided in such a direction that the rod-shaped end portion faces the upstream side of the medal flow path 11 and the tip portion faces the downstream side of the medal flow path 11. For this reason, when the disc-shaped member of the unauthorized device rotates, the notch also rotates along the peripheral edge, and when the notch reaches the position where the contacted portion 171a is disposed, the circular shape of the disc-shaped member until then is reached. The contacted portion 171a that has been in contact with the surface (the back surface of the disk-shaped member shown in FIG. 16) is lifted by releasing the contact at the notch, and comes into contact with the edge of the notch (FIG. 16). reference).
This contact restricts the rotation of the disk-shaped member and prevents further rotation. As a result, since the light receiving unit 15b of the input detection sensor 15 thereafter does not receive light, the detection signal that has been repeatedly turned ON and OFF continues to indicate only ON, and the main control Part 7 no longer counts credits. Accordingly, it is possible to effectively prevent an unauthorized increase in credit.

(C) Detection of Medals in the Main Control Unit The main control unit 7 detects the detection signal P1 output from the monitoring sensor 16, the detection signal P2 output from the insertion detection sensor 15, and the detection signal output from the exit sensor 17. P3 is received, and based on these detection signals P1 to P3, it is detected that the medal M has passed through the medal flow path 11 of the medal selector 10.

The following items will be described as items related to the detection of the medal M in the main control unit 7.
(C-1) Detection of medal M based on detection signals output from insertion detection sensor 15, monitoring sensor 16, and exit sensor 17 (c-2) Based on detection signals output from insertion detection sensor 15 and exit sensor 17 Detection of medal M

(C-1) Detection of the medal M based on detection signals output from the insertion detection sensor 15, the monitoring sensor 16, and the exit sensor 17.

The main control unit 7 executes the following process to detect the medal M.
(C-11) Reception of detection signal and identification of ON state or OFF state of each sensor 15-17 (c-12) Identification of time series order for transition between ON state and OFF state in each sensor (c- 13) Determination of detection of medal M

(C-11) Reception of detection signal and identification of ON state or OFF state of each sensor 15-17 The main control unit 7 outputs the detection signal P1 output from the monitoring sensor 16 and the input detection sensor 15. The detection signal P2 and the detection signal P3 output from the outlet sensor 17 are received (see FIG. 17).

  Next, the main control unit 7 specifies whether the monitoring sensor 16 is in an ON state or an OFF state based on the detection signal P1. Further, the main control unit 7 specifies whether the making detection sensor 15 is in an ON state or an OFF state based on the detection signal P2. Further, the main control unit 7 specifies whether the exit sensor 17 is in an ON state or an OFF state based on the detection signal P3.

Identification of the ON or OFF state of each of the sensors 15 to 17 will be described here by taking the monitoring sensor 16 as an example.
In a state where the medal M is not present in the medal flow path 11 of the medal selector 10, the medal M is not in contact with the tread plate portion 161a of the movable member 161 of the monitoring sensor 16, and the movable member 161 is displaced. No state (state shown in FIG. 6). In this case, since the displacement detection sensor 162 of the monitoring sensor 16 does not detect the detected part 161c of the movable member 161, the detection signal P1 indicating OFF is output.
On the other hand, when the medal M is inserted into the medal insertion slot 2 and this medal M passes through the medal flow path 11 of the medal selector 10 and this medal M comes into contact with the tread plate portion 161a of the movable member 161 of the monitoring sensor 16, it is movable. The member 161 rotates around the central axis of the shaft support 161b (see FIG. 8). Along with this, the tread plate portion 161a of the movable member 161 is displaced and the detected portion 161c is displaced. In this case, the displacement detection sensor 162 detects the displaced detected portion 161c and outputs a detection signal P1 indicating ON.
The displacement detection sensor 162 continues to output a detection signal P1 indicating ON while detecting the displaced detected portion 161c.

  After that, when the medal M passes through the installation position of the tread plate portion 161a of the monitoring sensor 16 in the medal flow path 11 and the medal M is not in contact with the tread plate portion 161a, the movable member is moved by the urging force of the urging member 163. 161 rotates about the central axis of the shaft support 161b, and returns to the state before the movable member 161 is displaced (see FIG. 6). As a result, the displacement detection sensor 162 does not detect the detected portion 161c of the movable member 161 that has been detected so far, and outputs a detection signal P1 indicating OFF in accordance with this non-detection.

  When the detection signal P1 is input and the detection signal P1 indicates ON, the main control unit 7 specifies that the monitoring sensor 16 is detecting the medal M, that is, the ON state. On the other hand, when the detection signal P1 indicates OFF, it is specified that the monitoring sensor 16 is not detecting the medal M, that is, the OFF state.

  Although the identification of the ON or OFF state in the monitoring sensor 16 has been described here, the same processing is performed for the identification of the ON or OFF state in the input detection sensor 15 and the identification of the ON or OFF state in the outlet sensor 17. Can be performed on content.

(C-12) Identification of time-series order for transition between ON state and OFF state in each sensor The main control unit 7 performs the input detection sensor 15, the monitoring sensor 16, the exit sensor based on the detection signals P1 to P3. While specifying the ON or OFF state for each of 17, the time series order of the transition from ON to OFF or OFF to ON is specified.
For example, it is assumed that the detection signals P1 to P3 input by the main control unit 7 have waveforms as shown in FIGS. 17 (i) to (iii). In this case, the time series order of the transition between the ON state and the OFF state in each of the sensors 15 to 17 is as follows.
Monitoring sensor 16 transitions from OFF to ON → Input detection sensor 15 changes from OFF to ON → Exit sensor 17 changes from OFF to ON → Input detection sensor 15 changes from ON to OFF → Exit sensor 17 changes from ON to OFF Transition → Monitoring sensor 16 transitions from ON to OFF

(C-13) Determination of detection of medal M When the main control unit 7 specifies the time series order of the transition between the ON state and the OFF state of each sensor 15 to 17, this time series order is stored in advance. And medal detection pattern A (which indicates the time-series order of transition between the ON state and the OFF state of each sensor 15 to 17 and is stored in advance in a predetermined storage unit).
When the identified time-series order matches the medal detection pattern A, it is determined that the medal M has been detected.
On the other hand, when the specified time series order is different from the medal detection pattern A, the main control unit 7 does not determine that the medal M has been detected.

For example, the detection signals P1 to P3 input by the main control unit 7 have waveforms as shown in FIGS. 17 (i) to (iii), and at the time of transition between the ON state and the OFF state in the sensors 15 to 17. Assume that the sequence order is the order described above.
On the other hand, as shown in FIG. 17 (iv), the medal detection pattern A indicates that the monitoring sensor 16 is ON → the insertion detection sensor 15 is ON → the exit sensor 17 is ON → the insertion detection sensor 15 is OFF → the exit sensor 17 is Assume that the order of OFF → monitoring sensor 16 is OFF.
In this case, since the specified time series order matches the medal detection pattern A, the main control unit 7 determines that the medal M has been detected.

The following points can be cited as characteristics of such determination.
(Ci)
The insertion detection sensor 15 detects the medal M in at least a part of the period in which the monitoring sensor 16 detects the medal M.
While the insertion detection sensor 15 detects the medal M, the monitoring sensor 16 detects the medal M.
That is, there is a period in which the monitoring sensor 16 and the insertion detection sensor 15 detect the same medal M at the same time.

(C-ii)
The monitoring sensor 16 starts detecting the medal M before the insertion detection sensor 15 detects the medal M, and continues the predetermined medal M after the insertion detection sensor 15 finishes detecting the medal M. Detect period.

(C-iii)
The exit sensor 17 detects the medal M during at least a part of the period during which the monitoring sensor 16 detects the medal M.
While the exit sensor 17 detects the medal M, the monitoring sensor 16 detects the medal M.
That is, there is a period in which the monitoring sensor 16 and the exit sensor 17 are detecting the same medal M at the same time.

(C-iv)
The monitoring sensor 16 starts detecting the medal M before the exit sensor 17 detects the medal M, and continues detection of the medal M after the outlet sensor 17 finishes detecting the medal M for a predetermined period of time. To do.

(Cv)
As a summary of (ci) to (c-iv), the monitoring sensor 16 has a period before and after the period when the insertion detection sensor 15 detects the medal M and the period when the outlet sensor 17 detects the medal M. The medal M is detected.
In addition, the medal detection pattern A is not a simple pattern in which the three sensors 15 to 17 are sequentially turned off in the order in which the three sensors 15 to 17 are turned on. It is in order.
For this reason, it is difficult for a fraudster to intervene, and fraud can be prevented in advance.

Further, the main control unit 7 determines that the medal M has been detected based on at least the detection signals received from both the monitoring sensor 16 and the insertion detection sensor 15.
Also in this respect, the monitoring sensor 16 and the input detection sensor 15 are not simply turned off sequentially in the order in which they are turned on, but the complicated that the monitoring sensor 16 that has been turned on first is turned off last. Order.
For this reason, it is difficult for a fraudster to intervene, and fraud can be prevented in advance.

When the regular medal M is inserted, the monitoring sensor 16, the insertion detection sensor 15 and the outlet sensor 17 are turned on in time-series order, the insertion detection sensor 15 is turned ON, and the outlet sensor 17 is The medal selector 10 is arranged so that the insertion detection sensor 15 is turned off, the exit sensor 17 is turned off, and the monitoring sensor 16 is turned off.
Specifically, as shown in FIG. 9, the medal M inserted into the medal slot 2 flows down the medal flow path 11 and reaches the position of the medal “M11” shown in FIG. Touches the tread plate portion 161a of the monitoring sensor 16 and presses the tread plate portion 161a, the monitoring sensor 16 is turned on. Next, when the medal M flows down and reaches the position of the medal “M12” shown in FIG. 9, the insertion detection sensor 15 detects the medal M and is turned on. Subsequently, when the medal M flows down and reaches the position of the medal “M13” shown in FIG. 9, the tip of the medal M comes into contact with the contacted portion 171a of the outlet sensor 17 and presses the contacted portion 171a. The outlet sensor 17 detects the medal M and is turned on. Then, when the medal M flows down and reaches the position of the medal “M14” shown in FIG. 9, the insertion detection sensor 15 does not detect the medal M, so the state is turned OFF. Further, when the medal M flows down and reaches the position of the medal “M15” shown in FIG. 9, the medal M does not press the contacted portion 171a of the exit sensor 17, and the exit sensor 17 does not detect the medal M. Therefore, it will be in an OFF state. Thereafter, when the medal M flows down and reaches the position of the medal “M16” shown in FIG. 9, the medal M does not press the tread plate portion 161a of the monitoring sensor 16, and the monitoring sensor 16 does not detect the medal M. , OFF state.
When the regular medal M is inserted, the monitoring sensor 16, the insertion detection sensor 15, and the exit sensor 17 are arranged in the medal selector 10 so as to transit between the ON state and the OFF state in such a time series order. ing.
And the tread board part 161a of the monitoring sensor 16 is formed in such a shape that the sensors 15 to 17 transition between the ON state and the OFF state in the above-mentioned time series order, and such transition is possible. It is arranged in the position.

  (C-2) Detection of the medal M based on the detection signals output from the insertion detection sensor 15 and the exit sensor 17

In (c-1), the method for determining the detection of the medal M based on the transition between the ON state and the OFF state of the three sensors 15 to 17 has been described.
Here, a method for determining the detection of the medal M based on the transition between the ON state and the OFF state of the two sensors of the insertion detection sensor 15 and the exit sensor 17 will be described.

In order to detect the medal M, the main control unit 7 executes the processes (c-11) to (c-14) described in (c-1).
Here, the contents of the processes (c-11) to (c-14) executed in (c-2) are basically executed in (c-1) (c-11). The contents of each process in (c-14) are the same, but there are also differences.
Here, of the contents of the processes (c-11) to (c-14), the difference from the contents executed in (c-1) will be described.

(C-11) The main control unit 7 receives at least the detection signal P2 output from the closing detection sensor 15 and the detection signal P3 output from the exit sensor 17.
The main control unit 7 specifies whether the making detection sensor 15 is in an ON state or an OFF state based on the detection signal P2. Further, the main control unit 7 specifies whether the exit sensor 17 is in an ON state or an OFF state based on the detection signal P3.

(C-12) The main control unit 7 specifies the ON or OFF state for each of the input detection sensor 15 and the outlet sensor 17 based on the detection signals P2 and P3. Specify the chronological order of transition to.
For example, assume that the detection signals P2 and P3 input by the main control unit 7 have waveforms as shown in FIGS. 17 (ii) and (iii). In this case, the time series order of the transition between the ON state and the OFF state in each of the sensors 15 and 17 is as follows.
Input detection sensor 15 changes from OFF to ON → Exit sensor 17 changes from OFF to ON → Input detection sensor 15 changes from ON to OFF → Exit sensor 17 changes from ON to OFF

(C-13) When the main control unit 7 specifies the time series order of the transition between the ON state and the OFF state of the sensors 15 and 17, this time series order is stored in the medal detection pattern B ( It shows the time series order of ON / OFF transition of each sensor 15 and 17 and is stored in advance in a predetermined storage unit).
When the identified time-series order matches the medal detection pattern B, it is determined that the medal M has been detected.
On the other hand, when the identified time series order is different from the medal detection pattern B, the main control unit 7 does not determine that the medal M has been detected.

For example, the detection signals P2 and P3 input by the main controller 7 have waveforms as shown in FIGS. 17 (ii) and (iii), and when the sensors 15 and 17 transition between the ON state and the OFF state. Assume that the sequence order is the order described above.
On the other hand, in the medal detection pattern B, as shown in FIG. 17 (v), the insertion detection sensor 15 is ON → the exit sensor 17 is ON → the insertion detection sensor 15 is OFF → the exit sensor 17 is OFF. To do.
In this case, since the specified time-series order matches the medal detection pattern B, the main control unit 7 determines that the medal M has been detected.
On the other hand, when the identified time series order is different from the medal detection pattern B, the main control unit 7 does not determine that the medal M has been detected.

  Even when the determination is made with such contents, the main control unit 7 can detect the medal M that has passed through the medal flow path 11 of the medal selector 10.

(D) Blocker (d-1) Structure and Operation The blocker 13 supports the medal M so that the medal M can pass through the medal flow path 11, and for the medal M exceeding the maximum number of credits. A guide member for releasing the support of the medal M so as to be discharged from the medal flow path 11, a support position for supporting the medal M and a discharge position for discharging the medal M from the medal flow path 11. It is movable.
The blocker 13 has a medal support part 131 arranged on a side of the medal flow path 11 along a direction from the upstream side to the downstream side of the medal flow path 11 over a predetermined length. Yes.

The blocker 13 operates in accordance with the operation of the solenoid 12.
The solenoid 12 is a guide member control unit that moves and holds the blocker 13 from the discharge position to the support position by excitation, and moves the blocker 13 from the support position to the discharge position by releasing the excitation.
For example, when the solenoid 12 is excited, the blocker 13 is attracted to the solenoid 12 as shown in FIG. Thereby, the medal support part 131 of the blocker 13 protrudes from the side part of the medal flow path 11 to the front of the wall surface part 11a.
Thus, the state in which the medal support part 131 protrudes from the side of the medal flow path 11 is a state in which the medal M is supported so that the medal M can pass through the medal flow path 11. The state becomes the support position of the blocker 13.

On the other hand, when the solenoid 12 is not excited, the blocker 13 that has been attracted is separated from the solenoid 12 as shown in FIG. In this case, the blocker 13 is biased by a biasing member (not shown), and the medal support portion 131 of the blocker 13 is pulled down from the side of the medal flow path 11 to the back side of the wall surface portion 11a.
Thus, the state where the medal support part 131 is pulled down from the side of the medal flow path 11 is a state where the medal M that is about to pass through the medal flow path 11 cannot be supported. It is discharged downward from. That is, the state in which the medal support part 131 is pulled down from the side part of the medal flow path 11 to the back side of the wall surface part 11a is the discharge position of the blocker 13.

The solenoid 12 operates under the control of the main control unit 7.
For example, when the number of medals M exceeding the maximum number of credits (for example, 50) is inserted into the medal insertion slot 2, the main control unit 7 discharges the excess medals M from the medal selector 10. Therefore, the solenoid 12 is shifted from the excited state to the non-excited state.

The control of the solenoid 12 by the main control unit 7 and the operation of the main control unit 7 will be further described.
In a state where the maximum number of credits has not been reached and the medal M can be inserted into the medal insertion slot 2, the main control unit 7 brings the solenoid 12 into an excited state, and the medal support unit 131 of the blocker 13 is moved. Move to support position.
The main control unit 7 operates as a counting unit of the present invention, and counts the number of credits based on at least the detection signal P2 from the insertion detection sensor 15. When the counted number of credits reaches the maximum number, the main control unit 7 puts the solenoid 12 in a non-excited state and moves the medal support unit 131 of the blocker 13 from the support position to the discharge position.
Thereby, even if the medal M is inserted into the medal insertion slot 2 thereafter, the medal M is discharged from the medal flow path 11 of the medal selector 10 and sent to the medal payout opening 6a.

Thus, the medal M inserted after the maximum number of credits is discharged from the medal flow path 11 of the medal selector 10, but in order to be able to execute such an operation, the medal support part 131 of the blocker 13. Has the following shape.
When the maximum number of credits has not been reached, the blocker 13 is in the support position when the medal M can be inserted into the medal slot 2. In this case, when the medal M is inserted into the medal insertion slot 2, the medal M is detected by the insertion detection sensor 15. The position of the medal M when detected by the insertion detection sensor 15 in this way is shown as “M21” in FIG.
When detecting the medal M, the insertion detection sensor 15 sends a detection signal P2 indicating ON to the main control unit 7. When this detection signal is input, the main control unit 7 increases the count by “1”.

If the medal M indicated as “M21” in FIG. 19 is the medal M that is counted by the main control unit 7 and becomes the maximum number of credits, the main control unit 7 removes the solenoid 12 from the excited state. Switch to the excited state.
Thereby, the medal support part 131 of the blocker 13 moves from the support position to the discharge position. For this reason, medals M that are subsequently inserted into the medal slot 2 are discharged from the medal channel 11.

However, when a plurality of medals M are continuously inserted into the medal insertion slot 2, and the next medal M ("M22" shown in FIG. 19) is present immediately behind the medal M indicated as "M21". Since this “next medal M” is the medal M exceeding the maximum number of credits, it is not sent out from the medal outlet 18 but is discharged downward from the medal flow path 11 and paid out from the medal payout outlet 6a. Must be.
For this reason, the main control unit 7 moves the medal support part 131 of the blocker 13 from the support position to the discharge position. However, since this movement is a mechanical movement, a predetermined time is required to move from the support position to the discharge position.

On the other hand, the “next medal M” is inserted from the medal insertion slot 2 and passes through the medal channel 11 at a predetermined speed.
Here, after the insertion detection sensor 15 detects the medal M indicated as “M21”, the “medal support portion 131 of the blocker 13 so that“ M22 ”as the“ next medal ”is discharged from the medal flow path 11. Assuming that the time until the guide member moves to the discharge position is the guide member movement time, the “next medal” “M22” is the medal flow path 11 between the start and end of the guide member movement time. Will move.
Thus, even when “M22” which is the “next medal” moves, the downstream side end portion of the medal support portion 131 of the blocker 13 so that the “next medal” is discharged from the medal flow path 11. 132 is located in the vicinity of the position facing the insertion detection sensor 15 across the medal flow path 11.
That is, the position where the end 132 on the downstream side of the medal support part 131 of the blocker 13 is arranged is that the “next medal” moves in the medal flow path 11 from the start to the end of the guide member moving time. At this time, it is located at a position where it can support the “next medal” after the movement, or on the downstream side of the medal flow path 11 from this position.
By providing the blocker 13 so as to be in such a position, the medal M inserted after the maximum number of credits is surely discharged from the medal flow path 11 and paid out from the medal payout opening 6a. Can be.

(E) Medal Channel The medal channel 11 is a passage through which the medal M inserted into the medal slot 2 passes through the medal selector 10.
The medal flow path 11 is formed with a wall surface portion 11a facing the circular surface of the medal M passing through the medal flow path 11 (see FIGS. 3 and 5). Moreover, this wall surface part 11a has the wall surface part surface 11b which is a surface facing the circular surface of the medal M which passes in a standing state.
The wall surface 11 b is a substantially vertical surface when the medal selector 10 is attached to the back surface of the front door 1 a of the slot machine 1.

Thus, by making the wall surface 11b substantially vertical, clogging of the medal M in the medal channel 11 can be prevented.
For example, it is assumed that the wall surface 11b is not a vertical surface but an inclined surface in which the surface faces obliquely upward or obliquely downward.
In this case, when the medal M is inserted into the medal insertion slot 2, the medal M is inserted in a substantially vertical state. However, when the medal M comes into contact with the inclined wall surface 11b, the medal M also tilts according to the inclination. It becomes like this. That is, when the medal M passes through the medal flow path 11, the posture of the medal M has to be changed from the vertically standing posture to the inclined posture.
Accordingly, the medal M easily collides with the wall surface 11b and the blocker 13 at the circular surface and the peripheral surface, and the flow of the medal M is suppressed due to the collision, and the medal M flows down in the middle of the medal flow path 11. Clogging may occur due to stopping.

On the other hand, when the wall surface 11b is a substantially vertical surface, the medal M inserted into the medal slot 2 in a posture standing in a substantially vertical direction passes through the medal channel 11 while maintaining this posture. Can pass through.
For this reason, since the medal M does not collide with the wall surface 11b or the blocker 13 when passing through the medal flow path 11, a situation in which the medal M stops flowing in the middle of the medal flow path 11 also occurs. Disappear.
From this, the clogging of medals M in the medal flow path 11 can be prevented by making the wall surface 11b substantially vertical.

The reason why the wall surface 11b can be made substantially vertical is that the medal support 131 of the blocker 13 is located below the medal channel 11.
For example, when the medal support part 131 of the blocker 13 is positioned above the medal flow path 11, the wall surface 11 b of the medal flow path 11 is inclined obliquely downward so that the medal support part 131 supports the medal M. The medal M should be inclined according to the inclined surface so that the upper end of the medal M is supported by the medal support portion 131. As a result, when the medal M passes through the medal flow path 11, the posture must be changed from the posture standing in the vertical direction to the tilted posture, which may cause clogging.
On the other hand, when the medal support part 131 of the blocker 13 is positioned below the medal flow path 11, the medal support part 131 is positioned in the direction of the center of gravity of the medal M. It can be maintained in the posture. Thereby, since it is not necessary to make the wall surface part surface 11b of the medal flow path 11 into an inclined surface, this wall surface part surface 11b can be made into a substantially perpendicular surface.

  In this way, the medal selector 10 of the present embodiment is not provided with a return button for returning the jammed M because the medal M is not clogged.

(F) Insertion Port Side Detection Sensor The insertion port side detection sensor 14 is a sensor for detecting the medal M inserted into the medal insertion port 2 and is provided upstream of the blocker 13 in the medal flow path 11. Yes.
The inlet side detection sensor 14 outputs a detection signal when it detects that the stepping plate-shaped movable member 141, the displacement member 142 that is displaced in conjunction with the movement of the movable member 141, and the displacement member 142 are displaced. And a displacement detection sensor 143 sent to the main controller 7 (see FIG. 3).

The movable member 141 is formed in a substantially rectangular plate shape, and one side surface 141a of the four side surfaces of the rectangular plate shape faces the upstream side of the medal flow path 11, and faces the one side surface 141a. The medal channel 11 is provided such that the side surface 141b facing the downstream side of the medal channel 11.
The movable member 141 is located at a position where one side surface 141a is slightly shifted to the back side of the medal selector 10 from the wall surface 11b of the medal channel 11, but the side surface 141b facing the one side surface 141a. Is located in front of the wall surface 11 b of the medal flow path 11.
Furthermore, the movable member 141 is pivotally supported with respect to the base 19 of the medal selector 10 so that the direction along the wall surface length HN of the medal flow path 11 is the axial direction of the rotation shaft.
For this reason, when the medal M inserted into the medal slot 2 contacts the movable member 141, the movable member 141 rotates about the rotation axis. When the displacement member 142 is displaced along with the rotation of the movable member 141, the displacement detection sensor 143 that detects the displacement outputs a detection signal indicating ON and sends the detection signal to the main control unit 7.

Here, the movable member 141 is formed such that the length YN in the direction along the channel orthogonal direction RT is substantially the same as the wall surface length HN or slightly longer than the wall surface length HN (see FIG. 3).
By setting the length YN of the movable member 141 to such a length, the medal M passing through the place where the movable member 141 is installed can be reliably detected.

Further, by setting the length YN of the movable member 141 to such a length, it is possible to reliably detect an unauthorized instrument inserted at a location where the movable member 141 is installed.
There are various types of unauthorized devices, and for example, there are a rod-shaped device and a tube-shaped device as the shape of the unauthorized device or its parts.
Here, when the length YN of the movable member 141 is shorter than the wall surface length HN, a gap is formed between the side portion of the movable member 141 and the side portion of the medal flow path 11. An instrument can be inserted into the gap. Then, since the insertion port side detection sensor 14 including the movable member 141 cannot detect the unauthorized instrument, a situation in which the medal M is paid out illegally occurs.

On the other hand, when the length YN of the movable member 141 is equal to or longer than the wall surface length HN, there is a gap between the side of the movable member 141 and the side of the medal channel 11. Therefore, for example, when a rod-shaped fraudulent instrument is inserted from the medal slot 2, the fraudulent instrument always comes into contact with the movable member 141. Then, the insertion port side detection sensor 14 including the movable member 141 can reliably detect the unauthorized device.
Then, the insertion port side detection sensor 14 sends a detection signal indicating ON to the main control unit 7 based on detection of an unauthorized device. The main control unit 7 generates an abnormality based on the detection signal indicating ON. Can be detected. For example, the time interval between the timing at which the detection signal sent from the insertion port side detection sensor 14 transitions from OFF to ON and the timing at which the detection signal sent from the loading detection sensor 15 subsequently transitions from OFF to ON. Is shorter than the predetermined time, it is determined that both the insertion slot side detection sensor 14 and the insertion detection sensor 15 have detected the regular medal M. On the other hand, when the time interval is longer than the predetermined time, it can be determined that an abnormality such as an illegal act has occurred. In this case, the main control unit 7 can notify the clerk of the game hall of the occurrence of the abnormality by executing a notification indicating that the abnormality has occurred.

As described above, according to the gaming machine of the present embodiment, in the medal flow path of the medal selector, the monitoring that detects the medal before and after the period in which the insertion detection sensor that is a photosensor detects the medal. By providing the sensor, it is possible to reliably detect an illegal instrument inserted for the purpose of erroneous operation of the insertion detection sensor.
Further, in the medal flow path of the medal selector, by providing an exit sensor disposed in the vicinity of the medal outlet in a direction in which the protruding direction is directed toward the medal outlet, it is possible to prevent the medal that has flowed back from the medal outlet from further entering. .
Further, in the main control unit, the ON state of each sensor in the time series order of monitoring sensor ON, closing detection sensor ON, exit sensor ON, closing detection sensor OFF, exit sensor OFF, monitoring sensor OFF. When it is determined that the OFF state has transitioned, it is determined that a medal has been detected. Therefore, it is difficult to intervene in fraud, and the occurrence of this fraud can be prevented.

The preferred embodiment of the gaming machine of the present invention has been described above, but the gaming machine according to the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the present invention. Needless to say.
For example, in the above-described embodiment, the slot machine is exemplified as an example of the gaming machine provided with the medal selector. However, the gaming machine is not limited to the slot machine, and a gaming machine using a medal as a gaming medium, for example, It may be a sparrow ball or an arrangement ball. Further, in the case of a slot machine, it may be a sealed slot machine.

  In the above-described embodiment, the main control unit detects a medal or detects the occurrence of an abnormality based on detection signals output from the monitoring sensor, the input detection sensor, and the exit sensor. However, for example, a medal may be detected or an abnormality may be detected based on a detection signal output from the insertion port side detection sensor. For example, the main control unit measures the elapsed time from the timing of receiving the detection signal indicating ON output from the insertion port side detection sensor to the timing of receiving the detection signal indicating ON output from the insertion detection sensor. If the elapsed time is within a predetermined time, it may be determined that a regular medal has been detected. On the other hand, if the elapsed time is equal to or longer than the predetermined time, it may be determined that an abnormality has occurred.

  Further, it is assumed that the insertion detection sensor, the displacement detection sensor of the monitoring sensor, the displacement detection sensor of the exit sensor, and the displacement detection sensor of the insertion port side detection sensor provided in the medal selector all use photo sensors. However, it is not limited to a photo sensor, and a proximity sensor, a capacitance sensor, or the like may be used.

1 slot machine (game machine)
7 Main control part 10 Medal selector 11 Medal flow path 11a Wall part 12 Solenoid (guide member control part)
13 Blocker (guide member)
132 Blocker downstream end 15 Input detection sensor (second sensor)
16 Monitoring sensor (first sensor)
161 Movable member 161a Tread plate portion 17 Exit sensor (third sensor)
M Medal HN Wall length XN Monitoring sensor tread length P1-P3 Detection signal

Claims (6)

A gaming machine equipped with a medal selector for detecting inserted medals,
The medal selector
A medal flow path through which the inserted medal passes,
The medal is supported so that the medal can pass through the medal flow path, and moved to a support position for supporting the medal and a discharge position for discharging the medal from the medal flow path. Possible guide members;
A first sensor provided at a position capable of detecting a medal supported by the guide member;
The medal flow path has a wall portion facing the circular surface of the medal that passes in a standing state,
The first sensor has a stepping plate-like movable member provided on the wall portion of the medal flow path,
When the length of the wall surface in the direction orthogonal to the medal passage direction is the wall surface length, the movable member has a length in a direction along the direction orthogonal to the medal passage direction substantially equal to the wall surface length. A gaming machine characterized by being formed to the same length. The medal selector
A second sensor for detecting the medal in at least a part of the period in which the first sensor is detecting the medal;
While the second sensor is detecting the medal, the first sensor is detecting the medal,
The control unit of the gaming machine determines that the medal has been detected based on receiving at least a detection signal indicating that the medal has been detected from both the first sensor and the second sensor. The gaming machine according to claim 1. The medal selector includes a third sensor capable of preventing a medal passing through the medal flow path from flowing backward,
The gaming machine according to claim 2, wherein the control unit determines the detection of the medal based on detection signals output from the first sensor, the second sensor, and the third sensor, respectively. The control unit determines whether each of the first sensor, the second sensor, and the third sensor is ON or OFF based on the detection signal,
In chronological order, the first sensor is turned on, the second sensor is turned on, the third sensor is turned on, the second sensor is turned off, the third sensor is turned off, and the first sensor is turned off. The gaming machine according to claim 3, wherein the first sensor, the second sensor, and the third sensor are arranged in the medal selector. A counting unit that counts the number of credits based on a detection signal from the second sensor;
A guide member control unit that moves the guide member from the support position to the discharge position when the number of credits counted by the counting unit reaches a predetermined number;
The guide member is disposed over a predetermined length along a direction from the upstream side to the downstream side of the medal flow path on one side of the medal flow path,
When the time from when the second sensor detects the predetermined number of medals when counted by the counting unit until the guide member moves to the discharge position is defined as a guide member movement time,
In order that the next medal is discharged from the medal flow path even if the next medal moves in the medal flow path between the start and end of the guide member moving time, The gaming machine according to any one of claims 2 to 4, wherein an end on the downstream side is located in the vicinity of a position facing the second sensor across the medal flow path. The control unit of the gaming machine executes a predetermined process based on the ON time of the detection signal output from the first sensor continuing for a predetermined period or longer. The gaming machine described in Crab.

Images