JP2015173775A - Token sorting device and game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a token sorting device allowing tokens to stably flow by fixing an interval between the tokens flowing in a token passage while maintaining an inexpensive configuration with the token passage of an entrance portion as a lateral passage.SOLUTION: A token selector 1 includes a token passage 33 for rolling and lowering a token M by dead weight from a first lateral passage L0 provided immediately below a supply port 18 of the token M to a vertical passage L1, and from the vertical passage L1 to a second lateral passage L2. In a falling position of a token supplied from the supply port 18 in the first lateral passage L0, a rolling auxiliary member 400, which absorbs shock of the token M falling from the supply port 18 and colliding, suppresses a rebound of the token, permits a shift to rolling operation, and which is made of low rebounding robber, is provided.

Description

  The present invention relates to a medal sorting device and a gaming machine provided in a gaming machine such as a slot machine.

  Conventionally, when a medal sorting device (medal selector) receives an inserted medal, it sorts the medal based on its size and the like, while taking down the medal passage, an appropriate medal is taken in, and a small-diameter medal, etc. Inappropriate medals are removed from the medal passage and returned to the return port of the gaming machine. Also, surplus medals inserted exceeding a predetermined number, and medals inserted during reel rotation of the gaming machine, during credit settlement, when the power is turned off, etc. are also returned to the return slot.

  In such a medal selection device, it is important that the inserted medals flow stably from the top to the bottom of the medal passage. In particular, in order to stably flow medals continuously inserted, it is important to secure a distance (medal interval) between medals at the entrance portion of the medal sorting device.

  For example, Patent Documents 1 and 2 describe a configuration in which a cradle is provided at the entrance of a medal sorting device, and an appropriate medal and an improper medal are selected according to the diameter and weight of the medal, and a medal interval is secured. Yes. However, the selection of medals by a cradle requires many parts such as a shaft, a movable piece, a spring, and a retaining ring, which increases the cost.

  As a configuration not using a cradle, for example, Patent Document 3 describes a configuration in which an improper medal is laid down and removed using a small-diameter medal exclusion lever while descending the medal passage. And according to this, the medal passage of the entrance portion of the medal sorting device is once bent in the horizontal direction and then connected to the vertical passage. In this way, the medal passage located just below the insertion slot is used as a horizontal passage, and the inserted medal is temporarily received at the bottom surface of the horizontal passage and then sent to the vertical passage to secure the medal interval. .

JP 2001-155206 A JP 2013-3673 A JP 2012-183131 A

  However, in the configuration in which the medal passage at the entrance portion is received at the bottom as a horizontal passage and then sent to the vertical passage, the medal interval can be secured, but the medal interval is not constant. This will be described.

  The medal received on the bottom surface of the horizontal passage collides with the bottom surface and jumps, moves so as to slide (slip) in the horizontal passage, and reaches the vertical passage. The distance and direction of the sliding movement is not stable compared to the movement by rolling, and even if medals are inserted at equal intervals from the insertion slot, the intervals between the medals descending the vertical passage are not equal. . In particular, when the next medal (following medal) collides with the bounced medal (previous medal), it may happen that the previous medal vigorously falls down the vertical passage and makes contact with the previous medal. . Such a collision between medals may cause clogging of medals in the subsequent stage of selecting inappropriate medals such as small diameter medals.

  The present invention has been made in view of the above problems, and can maintain a low-cost configuration in which the medal passage at the entrance portion is a lateral passage and can stably flow the medals flowing through the medal passage. An object is to provide a medal sorting device and a gaming machine.

  In order to solve the above-described problems, the medal sorting device of the present invention includes a first lateral passage provided immediately below a medal slot, a vertical passage, and the vertical passage to a second lateral passage. A medal sorting device provided with a medal passage that rolls medals down by its own weight and falls into a position where a medal inserted from the insertion port in the first lateral passage falls and collides A rolling assist member made of low-rebound rubber is provided, which absorbs the impact of the medal and suppresses the medal bounce and shifts to a rolling operation.

  According to the above configuration, the rolling assist member made of low-rebound rubber is provided at the drop position of the first lateral passage where the medal inserted from the insertion slot collides. The rolling assist member absorbs the impact of the medals that fall from the insertion slot and collides, and suppresses the jumping of the medals and shifts to a rolling operation.

  Thereby, the medal inserted from the insertion slot collides with the rolling auxiliary member without colliding with the bottom surface of the first lateral passage, rolls without jumping, and flows to the vertical passage, so that it is uniform. The medal interval is secured and the flow of medals can be stabilized. Further, depending on the timing of inserting medals, medals may collide with each other. However, since the rolling assist member absorbs the impact caused by the collision between medals, stable medal flow can be realized.

  In addition, since only a rolling assist member made of low-rebound rubber is disposed, it is easy to assemble and can be configured at a low manufacturing cost.

  In the medal sorting device of the present invention, it is further preferable that the low resilience rubber constituting the rolling auxiliary member has a resilience elastic modulus of less than 7%.

  When the rebound resilience is 7% or more, the impact of the medals falling from the height of the slot and colliding cannot be absorbed (instantaneously), and the medals bounce off and move smoothly to the rolling motion. No longer. On the other hand, by setting the rebound resilience to less than 7%, it is possible to absorb the impact of the medals that fall from the insertion slot and collide, suppress the medal bounce, and smoothly shift to the rolling operation.

  In the medal sorting device of the present invention, the rolling assist member may be made of low-rebound butyl rubber.

  Butyl rubber has characteristics such as being resistant to animal fats and oils, and since there is little change in the resilience elastic modulus that absorbs the impact of medals at the environmental temperature (5 to 50 ° C.) where the medal sorting device is expected to be used. Suitable for the rolling assist member in the invention.

  In addition, the present invention also falls within the scope of the invention for a gaming machine provided with the above-described medal sorting device of the present invention.

  According to the present invention, there is provided a medal sorting device and a gaming machine that can stably flow by keeping the interval of medals flowing through the medal passage constant while maintaining an inexpensive configuration in which the medal passage at the entrance portion is a lateral passage. There is an effect that it can be provided.

It is an external perspective view of a slot machine provided with a medal selector of the present embodiment. It is a perspective view which shows the internal structure of the door which opened the front door of the slot machine in the single swing type. It is an external appearance perspective view which shows the front side (surface side) of the medal selector of the state which removed the front cover. It is an external appearance perspective view which shows the back side (back side) of the medal selector of the state which removed the back cover. It is a perspective view which shows the inner surface of the board | substrate which comprises a medal selector. It is a front view which shows the inner surface of the opening / closing plate which comprises a medal selector. It is explanatory drawing which shows the positional relationship of the rolling auxiliary member and insertion slot which were provided in the 1st horizontal direction channel | path in a medal channel. (A)-(c) is explanatory drawing which shows the flow of the medal inserted from the insertion slot. It is a disassembled perspective view which shows attachment of the rolling auxiliary member arrange | positioned from the outer surface side of a board | substrate. It is a graph which shows the relationship between the loss coefficient of the low-resilience rubber which comprises a rolling auxiliary member, and temperature.

  Hereinafter, embodiments of the present invention will be described in detail. In this embodiment, a slot machine installed in a game hall is shown as an example of a gaming machine.

  FIG. 1 is an external perspective view of a slot machine 11 including a medal selector 1 according to the present embodiment. As shown in FIG. 1, the slot machine 11 has a panel 12 and a reel portion 13 at the upper front part corresponding to customer service, and has three stop buttons 14 arranged in parallel in the width direction at the center of the front face. Further, the left side has a start lever 15, a multiplying number setting button 16a and a settlement button 16b, the right side has a return button 17 and a slot 18 for inserting medals M one by one, and a tray 19 in the lower part of the front. .

  When the player uses the slot machine 11 for games, medals M are inserted into the insertion slot 18 one by one. The inserted medals M are sorted by a medal selector (medal sorting device 1) to be described later, and the appropriate medals M selected as valid are taken in. On the other hand, medals selected as inappropriate, surplus medals M inserted in excess of a predetermined number, medals M inserted during reel rotation or credit settlement, when the power is turned off, and the like will be described later. And it returns to the saucer 19 through the return port 27 (refer FIG. 2). The medal M is also returned to the tray 19 when the player depresses the settlement button 16b to stop the game.

  FIG. 2 is a perspective view showing the internal structure of the door in which the front door 11a of the slot machine 11 is opened in a single opening manner. In the internal space of the slot machine main body 11b, a control unit 11c is installed at the top, and three rows of reel units 13 are installed at the center for rotating and stopping the position of the pattern on the outer peripheral surface to use the game. Further, in the internal space, a medal taking-in and paying-out medal paying device 21 is installed in the center of the lower portion, a power supply device 22 is installed on the left side, and an overflow tank 23 is installed on the right side. The control unit 11c processes the signal of the medal selector 1 and controls each unit of the slot machine 11.

  On the other hand, the front door 11a is provided with a reel cover 24, a medal selector 1 for selecting appropriateness of medals, a medal payout chute 26, and a return port 27 in this order from the upper part to the lower part. The medal inserted into the insertion slot 18 is once guided to the medal selector 1, and after the suitability is selected, the medal permitted to be accepted is passed through the medal transport passage 25a connected to the outlet of the medal selector 1. The hopper tank 21 a provided at the upper part of the medal payout device 21 is received. On the other hand, the medal rejected by the medal selector 1 is returned to the tray 19 through the medal payout chute 26 and the return port 27.

  Next, the configuration of the medal selector 1 will be described. FIG. 3 is an external perspective view showing the front side (front side) of the medal selector 1 with the front cover removed. FIG. 4 is an external perspective view showing the back side (back side) of the medal selector 1 with the rear cover removed.

  The medal selector 1 is configured such that a substrate 28 and an opening / closing plate 29 are arranged so as to be openable and closable. An entrance 34 that opens upward is formed between opposed surfaces of the substrate 28 and the opening / closing plate 29, and a lower portion thereof. A medal passage 33 connecting to the outlet 35 is formed.

  The substrate 28 is U-shaped in plan view, and the standing front surface has a square shape. One side of the medal passage 33 is formed on the inner surface of the square substrate 28 (the surface facing the opening / closing plate 29), and a solenoid (driving means) for selecting the medal on the outer surface of the substrate 28. ) 303, the first sensor case 503, the second sensor case 504, the support mechanism 108 of the small-diameter medal removal lever 100, the movable guide link 305, and the like are attached.

  On the other hand, the opening / closing plate 29 has a slightly smaller plate shape that fits in a U-shaped space in plan view of the substrate 28, and is provided opposite to the substrate 28. In the opening / closing plate 29, a support shaft 31 provided perpendicularly to one side portion of the opening / closing plate 29 is pivotally supported by a bearing portion 30 provided on one side portion of the substrate 28. As a result, the opening / closing plate 29 is opened and closed in a single-opening manner in a direction facing the substrate 28 with the support shaft 31 as a rotation fulcrum. Further, the opening / closing plate 29 has a coil spring 32 for pressing the opening / closing plate wound around a support shaft 31. The biasing force of the coil spring 32 constantly biases the opening / closing plate 29 toward the substrate 28 to keep the closed state. . The other surface of the medal passage 33 is formed on the inner surface (the surface facing the substrate 28) of the opening / closing plate 29, and members such as the movable guide mechanism 300 are disposed on the outer surface of the opening / closing plate 29. In addition, an exclusion port (exclusion opening) 200 for eliminating small diameter medals is formed.

  FIG. 5 is a perspective view showing the inner surface of the substrate 28 constituting the medal selector 1. FIG. 6 is a front view showing the inner surface of the opening / closing plate 29 constituting the medal selector 1. As shown in FIGS. 5 and 6, the medal passage 33 has a first transverse passage L0, a longitudinal passage L1, and a second passage that are arranged in a hook shape (hook shape) connecting the inlet 34 and the outlet 35. It is formed in a shape having a lateral passage L2. The first lateral passage L0 is located immediately below the inlet 18, and is inclined obliquely downward from the inlet 34 and connected to the upstream side of the longitudinal passage L1. The second transverse passage L2 is connected to the downstream side of the longitudinal passage L1, and is inclined obliquely downward to reach the outlet 35. The first transverse passage L0 and the longitudinal passage L1 are connected by a curved portion L3 that draws a smooth curve, and the smooth passage is drawn between the longitudinal passage L1 and the second transverse passage L2. It is connected at the bending portion L4.

  As shown in FIG. 5, on the substrate 28 side, a rolling assist member 400 made of low-rebound rubber is disposed in the first lateral passage L0, and a small diameter medal exclusion lever (delay means, (Biasing lever) 100 is disposed, and the first sensor S1 and the second sensor S2 are disposed in the second lateral passage L2. Further, as shown in FIG. 6, the above-described exclusion port 200 is formed on the opening / closing plate 29 side from the downstream side of the longitudinal passage L1 to the upstream side of the second lateral passage L2 including the curved portion L4. A passage forming plate 308 that forms the passage bottom surface of the medal passage 33 is appropriately disposed at the rear stage of the mouth 200 by a movable guide mechanism 300 described later. As will be described in detail later, the characteristic configuration of the medal selector 1 of the present embodiment is in the rolling assist member 400 made of low-rebound rubber disposed in the first lateral passage L0 of the substrate 28.

  The small-diameter medal exclusion lever 100 is for excluding small-diameter medals descending the medal passage 33 from an exclusion port 200 formed on the opening / closing plate 29 side. The small diameter medal exclusion lever 100 is configured such that, on the back side of the substrate 28, the contact guide surface 103 that comes into contact with the medal rotates in the passage thickness direction and advances and retreats, and the contact guide surface 103 can be protruded and retracted on the side surface. The small-diameter medal exclusion lever 100 is biased from the outer surface side of the substrate 28 by a biasing spring (not shown) so that the contact guide surface 103 faces the longitudinal passage L1. The small-diameter medal exclusion lever 100 protrudes into the passage when not in contact with the medal, immerses when it comes into contact with the descending medal, and protrudes again after passing the medal.

  The exclusion port 200 is formed from the curved portion L4 of the opening / closing plate 29 to the upstream side of the second lateral passage L2. An upper guide plate 106 and a lower guide plate 107 are provided at the upper and lower edge portions of the exclusion opening 200 in the opening / closing plate 29 and upstream of the second lateral passage L2. The upper guide plate 106 and the lower guide plate 107 are used to convey and guide the upper and lower portions of appropriate medals that roll in a standing position.

  A passage forming plate 308 provided on the opening / closing plate 29 side is configured to open the passage bottom surface of the medal passage 33 and is driven by the movable guide mechanism 300. The movable guide mechanism 300 includes a drive mechanism 301 (see FIG. 4) mounted on the substrate 28 and a movable guide plate 302 (see FIG. 3) mounted on the opening / closing plate 29.

  As shown in FIG. 4, the drive mechanism 301 has a solenoid (drive means) 303 attached to the outer surface of the substrate 28 and a movable plate (movable member) 304 that is movable by receiving the drive force. One end of the movable plate 304 is urged by a return spring 311 (see FIG. 9), and the movable guide link 305 is hooked on the tip 304a opposite to the urged side.

  In the movable guide link 305, a link shaft 306 (see FIG. 5) provided on the inner surface side protrudes from the outer surface side of the substrate 28 toward the second lateral passage L2, and the protruding link shaft 306 is an opening / closing plate. The movable guide plate 302 (see FIG. 3) disposed on the outer surface 29 is pressed.

  As shown in FIG. 3, the movable guide plate 302 has a lever shape that is long in the vertical direction, and is attached to the support shaft 307 laid on the outer surface of the opening / closing plate 29 along the passage direction of the second lateral passage L2. The central portion of the movable guide plate 302 is pivotally supported and can be rotated. In addition, the upper inner surface of the movable guide plate 302 is opposed to a link shaft 306 protruding from the outer surface of the substrate 28 toward the inner surface, and the tip thereof is the upper inner surface 315 of the movable guide plate 302 (see FIG. 6). Are opposed to each other so that they can be pressed.

  Further, a coiled movable guide plate biasing spring (not shown) is interposed between the lower inner surface of the movable guide plate 302 and the outer surface of the opening / closing plate 29 in a compressed state. With this movable guide plate urging spring, the movable guide plate 302 is urged to the outer surface side with the support shaft 307 as a rotation fulcrum, the upper portion is urged to the inner surface side, and the upper inner surface 315 is pushed by the link shaft 306. Then, the lower part of the movable guide plate 302 rotates toward the substrate 28 against the urging force of the movable guide plate urging spring with the support shaft 307 as a fulcrum.

  As a result, the movable guide plate 302 is moved to the passage formation position and the passage non-formation position under the pressing force of the link shaft 306 that moves forward and backward based on ON / OFF of the solenoid 303.

  A passage forming plate 308 that forms the passage bottom surface of the second lateral passage L2 in the medal passage 33 is attached to the lower end of the movable guide plate 302. This passage forming plate 308 is projected and lowered freely toward the lower portion of the passage region of the medal passage 33 through a lower opening 309 (see FIG. 6) opened at the lower portion of the opening / closing plate 29.

  When the solenoid 303 is OFF (de-energized), the passage forming plate 308 of the movable guide plate 302 is retracted from the medal passage 33 by receiving a biasing force of a movable guide plate biasing spring (not shown), and the bottom surface of the medal passage 33 is for medal removal. It is in a state opened to. On the other hand, when the solenoid 303 is turned on and the movable guide plate 302 receives the pressing force from the link shaft 306 and rotates, the lower passage forming plate 308 protrudes below the medal passage 33 and the medal passage 33 A bottom surface is formed to allow the medal M to pass through.

  Although explanation is omitted, in addition to the movable guide mechanism 300, when the passage formation plate 308 is projected to form the passage bottom surface, a medal is sandwiched between the passage formation plate 308 and the inner surface of the substrate 28. A countermeasure mechanism is also installed.

  Returning to FIG. 5, the first sensor S1 disposed in the center of the second lateral passage L2 on the substrate 28 side and the second sensor S2 provided immediately before the outlet 35 of the medal passage 33 are both medals. It is used to detect passage and is used for counting the number of medals that have passed. The first sensor S1 and the second sensor S2 are disposed from the back side of the substrate 28 in the first sensor case 503 and the second sensor case 504 (see FIG. 4).

  Next, the rolling assisting member 400 made of low resilience rubber disposed in the first lateral passage L0 of the substrate 28 will be described. FIG. 7 is an explanatory diagram showing the positional relationship between the rolling assisting member 400 provided in the first lateral passage L0 in the medal passage 33 and the insertion port 18. FIGS. 8A to 8C are explanatory views showing the flow of medals M inserted from the insertion slot 18.

  The rolling assisting member 400 is made of a low-rebound rubber that is installed over the length of, for example, 6 mm in the passage length direction at the drop position immediately below the insertion port 18 on the bottom surface of the first lateral passage L0. The rolling assist member 400 instantaneously absorbs the impact of the medal M that falls from the insertion slot 18 and collides, suppresses the medal M from jumping, and smoothly shifts to the operation of rolling the first lateral passage L0. Is.

  As shown in FIGS. 8A and 8B, the medal M inserted from the insertion slot 18 and dropped into the medal selector 1 through the inlet 34 does not collide with the bottom surface of the first lateral passage L0. Colliding with the rolling assisting member 400. The rolling auxiliary member 400 instantaneously absorbs the impact of the collided medal M. The medal M that has come into contact with the rolling assisting member 400 stops for a moment when the impact is absorbed, and immediately thereafter rolls toward the longitudinal passage L1 by its own weight, as shown in FIG. 8C. Since the rolling assist member 400 made of low resilience rubber is rubber, the friction coefficient of the surface is high, and the medal M does not slide on the surface of the rolling assist member 400. Therefore, by rolling the medal M without jumping in the first lateral passage L0, a uniform medal interval can be secured.

  Further, at the entrance 34, medals may collide with each other depending on the timing when the medal M is inserted. In the configuration in which the rolling assist member 400 is not provided, the medal M bounces due to the impact of the collision, which prevents stable medal flow. On the other hand, by providing the rolling assist member 400, the impact of collision between medals can be received by the rolling assist member 400, and a stable medal flow can be realized.

  In addition, since the rolling auxiliary member 400 made of low-rebound rubber is only disposed in the first lateral passage L0, it is easy to assemble and can be configured at a low manufacturing cost.

  FIG. 9 is an exploded perspective view showing attachment of the rolling auxiliary member 400 disposed from the outer surface side of the substrate 28. As shown in FIG. 9, the board 28 is provided with a mounting hole 403 that matches the shape of the rolling assist member 400. The rolling assist member 400 is disposed in the mounting hole 403 from the outer surface (rear surface side) of the substrate 28, and after inserting the rolling assist member 400, the mounting hole 403 is closed by the cover 402. The position where the mounting hole 403 is formed is a position below the solenoid 303 described above.

  Next, the low resilience rubber in the present embodiment will be described in detail focusing on the loss coefficient (tan δ). The loss coefficient (tan δ) is a ratio G ″ / G ′ of the storage shear modulus (G ′) and the loss shear modulus (G ″). The loss factor (tan δ) indicates how much energy the material absorbs (changes to heat) as the material deforms. The larger the value of the loss factor (tan δ), the smaller the rebound resilience in the impact buffer test.

  In the medal selector 1 of the present embodiment, the low resilience rubber constituting the rolling assisting member 400 has a loss coefficient (tan δ) of 0.5 or more at 5 to 50 ° C. where the medal selector 1 is assumed as a use environment. It is desirable to be. This is because when the loss coefficient (tan δ) is less than 0.5, the impact of the medal that falls from the height of the slot cannot be absorbed instantaneously, and the medal jumps and rolls. This is because the transition is not smooth.

  FIG. 10 shows the relationship between the loss coefficient (tan δ) of low-rebound rubber (low-rebound butyl rubber) used as the rolling assist member 400 and the temperature in the medal selector 1 of the present embodiment. It can be seen that the loss factor (tan δ) satisfies 0.5 or more in different frequency bands of 10 Hz, 30 Hz, and 50 Hz at the use temperature of 5 to 50 ° C. in the medal selector 1.

  Further, when the low-rebound rubber constituting the rolling assisting member 400 is defined by the rebound resilience in the shock absorbing test, it is necessary to be a material that achieves less than 7%. This means that when the impact resilience is 7% or more, the impact of the medals falling from the height of the slot cannot be absorbed instantaneously, and the medals bounce off and move smoothly to the rolling action. It is because it stops.

  Further, the rubber hardness of the low-rebound rubber constituting the rolling assisting member 400 (rubber durometer (JIS_K_6253) A type, measured at 23 ° C. ± 2 ° C.) is preferably 50 to 65 °. Thus, for example, according to the durability specification of the medal selector 1 such as 10 million medals, even if medals repeatedly collide between them, the function can be satisfied without being deformed or worn.

  Furthermore, since sebum adheres to the medal M, the low resilience rubber constituting the rolling assisting member 400 is preferably one having high resistance to animal oils.

  A low resilience butyl rubber is used for the rolling assisting member 400 as a rubber material that exhibits stable low resilience at 5 to 50 ° C. in the usage environment, and also secures a necessary rubber height and is resistant to animal fats and oils. It is particularly preferred.

  The present invention can be applied to a medal sorting device that does not use a cradle, in which the medal passage at the entrance portion is bent in the horizontal direction and then reaches the vertical passage.

1 Medal selector (medal sorting device)
11 Slot machines (gaming machines)
33 Medal passage 34 Entrance 35 Exit 400 Rolling auxiliary member 402 Cover 403 Mounting hole L0 First lateral passage L1 Vertical passage L2 Second lateral passage L3 Bending portion L4 Bending portion M Medal

Claims (4)

Medal selection provided with a medal passage provided directly below the medal slot from the first lateral passage to the vertical passage and from the vertical passage to the second lateral passage by rolling the medal by its own weight. A device,
Absorbing the impact of the medals falling from the insertion slot and colliding with the dropping position of the medals inserted from the insertion slot in the first lateral passage, and shifting to the operation of rolling down the medals. A medal sorting device comprising a rolling assist member made of low-rebound rubber.   The medal sorting device according to claim 1, wherein the low resilience rubber constituting the rolling assist member has a resilience modulus of less than 7%.   The medal sorting device according to claim 1 or 2, wherein the rolling auxiliary member is made of low-resilience butyl rubber.   A gaming machine comprising the medal sorting device according to any one of claims 1 to 3.

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