JP5314469B2 - Medal throwing device - Google Patents

Description

  According to the present invention, a medal taken into the disk from a plurality of openings that are opened upward on a medal taking-in rotating disk and into which medals formed in a circumferential direction are inserted is rotated to rotate the disk. The present invention relates to a medal throwing device that throws out a predetermined number in the outward direction, and in particular, even if a medal has been crushed by being used for many years and the outer periphery has been crushed, resulting in an increase in thickness or deformation, The present invention relates to a medal throwing apparatus that can reliably pass a path without delay and can prevent obstacles such as locking of rotation of a medal taking-in rotating disk.

  In the conventional medal throwing device, a plurality of openings large enough to receive medals open upward and communicate to the lower surface, and rotate the medal take-in rotary disk formed in the circumferential direction to rotate the medal take-in rotation. A predetermined number of medals taken into the opening from above are thrown out toward the outer periphery of the disk.

  The medal take-in rotating disk is rotatably mounted on the upper surface of the base member. Further, on the lower surface of the medal take-in rotating disk, there is an extrusion unit that slides on the upper surface of the base member as the disk rotates, and causes the medal taken in from the opening for taking in the medal to follow the rotation of the medal take-in rotating disk. , Formed on the back surface of the medal take-in rotating disk in which the opening is formed.

  The push-out portion protrudes from the back surface of the medal take-in rotating disk and the thickness of the medal + α and slides on the upper surface of the base member along with the rotation of the medal take-in rotating disk. To form a slidable space. In the space, the medal taken in from the opening is driven by the pushing portion while being driven by the rotation of the medal take-in rotating disc, and moves in a direction away from the disc center together with the driven centrifugal force.

  Further, medals are thrown out from the opening of a throw-out portion provided on the outer periphery of the medal taking-in rotating disk 41 and capable of passing in the radial direction. The opening also allows the medal to pass by its thickness + α. This + α is a margin for smooth passage and movement of medals.

  Here, in Patent Document 1, in such a medal throwing apparatus, it is possible to reliably count and throw coins without causing a counting mistake, and to prevent coins from being locked even when a throwing mistake occurs. Techniques for disclosing are disclosed. In Patent Document 1, when the coin is pushed in the non-throwing direction and the detection roller is pushed, the detection roller is swung with the detection base without swinging in the direction of opening the coin throwing gap. , Preventing coin lock and mis-throwing.

JP 2000-339508 A (paragraph [0013])

  Here, in order for the medal to slide in the space on the back side of the medal take-in rotating disk and for the medal to pass through the opening of the throw-out portion, the height of the space and the opening is the thickness of the medal. Need to be greater. However, as the medal is used, the outer peripheral portion is hit and the thick edge of the outer peripheral portion is deformed thickly.

  When the edge of the outer peripheral portion becomes thick when passing through the above-described space or opening, the passage may be delayed or impossible in some cases.

  When the passage is delayed and the medal taken between the disk lower surface and the base continues to be unnecessarily driven by the disk rotation due to being pinched between the disk lower surface and the base or increasing friction. There is. In this case, there is a possibility that the medal moves to an unscheduled part and is inserted.

  For example, in a medal throwing device structured to move while following the disk rotation and then throw out while counting the number of medals, the part that is pushed out and the medals first contact is rotated smoothly when the medals come in contact with the bearings. A possible cylindrical portion (hereinafter simply referred to as a detection bearing) is provided.

  In such a medal throwing device, the medal is originally pushed out of the rotating disk for taking in the medal. Therefore, the medal comes into contact with the detection bearing after the contact with the disk is lost. However, when the medal continues to follow the disk rotation unnecessarily, it comes into contact with the detection bearing while being in contact with the disk part, and when the medal center at this time is located on a straight line between these contact parts, in some cases, When a medal is sandwiched, the movement of the medal and the rotation of the medal take-in rotating disk may be deadlocked.

  When deadlock occurs, it may be possible to eliminate this by applying the above-mentioned Patent Document 1. However, if the thickness of the edge of the medal is increased, it is difficult to eliminate this.

  The present invention is to solve the above-mentioned conventional problems, and even if a medal whose outer periphery is struck and crushed due to use for many years, and the thickness has increased or deformed, the internal path to the throw-out is provided. It is an object of the present invention to provide a medal throwing device that can reliably pass through without delay and can prevent obstacles such as rotation locking of a medal take-in rotating disk.

  According to the present invention, a medal taken into the disk from a plurality of openings that are opened upward on a medal taking-in rotating disk and into which medals formed in a circumferential direction are inserted is rotated to rotate the disk. In a medal throwing device that throws out a predetermined number in the outward direction, the medal take-in rotary disk is taken in from the opening between the upper surface of the base member on which the disk is rotatably mounted and the lower surface member of the disk. The lower surface member of the disk is formed in the vicinity of the opening so that a gap larger than the medal thickness is provided for allowing the medal to pass, and the gap is larger than the thickness of the edge of the medal outer periphery. In addition, at the congested position of medals where the passage of medals is stagnant or easy to stop, only a portion where the edges of the medals pass is formed with a recessed portion extended in the thickness direction. The Rukoto is obtained by solving the above problems.

  Here, the medal traffic jam position protrudes from the lower surface of the medal take-in rotating disk, and comes into contact with the medal taken in from the opening to push the medal in accordance with the disk rotation. It is possible to form the dent portion in accordance with the medal traffic jam position, which is a medal position in contact with the inner circumferential surface guided in the circumferential direction.

  Also, the medal traffic jam position protrudes from the lower surface of the medal take-in rotary disk and comes into contact with the medal taken in from the opening, thereby pushing the medal to follow the disk rotation, and the medal accompanying the follower The dent portion can be formed in accordance with the medal traffic jam position at the position where the medal is first brought into contact with the site where the medal is first pushed out of the take-in rotating disk.

  According to the present invention, the bottom surface of the disk is designed so that the outer peripheral edge of the medal is easily passed and moved even if the outer peripheral edge that is thicker than the center is thickened by being used for many years. A recess is formed in the part. Therefore, even if the thickness of the edge of the outer periphery of the medal increases due to secular change, it is advantageous in that it corresponds to this. For example, even if medals with thick edges due to aging are mixed, the game can be paid out smoothly without stopping. Further, even with such medals, the deadlock of the medals between the detection bearing and the disk pushing portion can be reduced, and the life of the apparatus can be improved.

The perspective view of the whole medal throwing device of the embodiment to which the present invention is applied. Front view of the whole medal throwing device of the above embodiment Right side view of the whole medal throwing device of the embodiment. Top view of the whole medal throwing device of the embodiment. The whole exploded perspective view of the whole medal throwing device of the embodiment Whole exploded front view of the whole medal throwing apparatus of the embodiment Exploded perspective view of the dispensing unit portion of the embodiment Plan view of the periphery of the medal take-in rotating disk of the payout unit The perspective view which shows the lower surface of the medal taking in rotation disk used for the prior art example contrasted with the said embodiment. Enlarged view of part B1 in the above perspective view The perspective view which shows the lower surface of the medal taking in rotation disk used for the said embodiment. Enlarged view of part B1 in the above perspective view Sectional drawing of the periphery of the medal taking-in rotating disk provided in the payout unit portion of the embodiment Plan view of medals used in the embodiment and conventionally used Side view of the medal Enlarged side view of the medal edge of part C in FIG. 15 in a new medal Enlarged side view of the medal edge of part C in FIG. The schematic diagram which shows the clearance gap S through which a medal passes in the payout unit part in a prior art example The schematic diagram which shows the clearance gap S through which a medal passes in the payout unit part in the said embodiment. In the embodiment, the sectional plan view showing the state of the medal taking-in rotating disk and the medal in the first stage until the medal taken into the opening of the medal taking-in rotating disk is thrown out from the payout unit part. Plan sectional drawing which shows the said state of the said 2nd step Plan sectional drawing which shows the said state of the said 3rd step Plan sectional view showing the state of the fourth stage A plan view showing a medal that can be in a deadlock state of a conventional medal take-in rotating disk and a state of the medal take-in rotating disk The top view which shows the state of the medal which can be in the deadlock state of the medal taking rotation disk in the said embodiment, and a medal taking rotation disk

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  1 to 6 are a perspective view, a front view, a right side view, a top view, a whole exploded perspective view, and a whole exploded front view, respectively, of an entire medal throwing apparatus according to an embodiment to which the present invention is applied.

  First, the frame unit 2 arranges the entire medal throwing apparatus 1 inside a pachislot machine, a slot machine, a money changer, a vending machine, or the like. Further, as shown in these drawings, a payout unit portion 4 having a mechanism for throwing out a predetermined number of medals is fixed to an inclined upper opening portion of the frame portion 2, and a throwout unit portion 4 is further disposed thereon. The medal container part 3 for storing the medal for performing is arrange | positioned. The medal container section 3 is provided with a chute 31 for receiving extra medals out of the tray when a large number of medals are inserted into the medal tray 30.

  Next, FIGS. 7 and 8 are an exploded perspective view of the payout unit portion 4 of the present embodiment, and a plan view of the payout unit portion 4 as seen from above the periphery of the medal taking-in rotating disk 41, respectively.

  A medal taking-in rotating disk 41 is rotatably mounted on a disk guide 42 attached to the upper surface of the base member 40 of the payout unit 4. The medal taking-in rotating disk 41 is rotationally driven in a clockwise direction in FIG. 8 by a motor shaft 431 of a driving motor 43 attached to the center of the lower surface of the base member 40. The base member 40 is attached with a counting device 5 for counting the number of medals thrown out.

  The medal take-in rotary disk 41 is formed with a plurality of openings 412 having a size for receiving medals arranged in the circumferential direction for separating the medals one by one. Further, as will be described later with reference to FIGS. 9 to 12, medals taken from the opening 412 and separated one by one are pushed out to the medal payout opening 402 on the lower surface of the medal take-in rotating disk 41 and conveyed. The extrusion part 414 for performing is provided. During the conveyance, the disc guide 42 is pushed by the pushing portion 414 along with the rotation of the medal take-in rotary disc 41, and the medal that slides in contact with one side of the medal sliding surface 401 along its inner peripheral surface 422. Then, the medal take-in rotating disk 41 is guided to slide in the circumferential direction.

  The medal payout port 402 (FIG. 2) forms a continuous surface with the medal sliding surface 401, and the medal throwing device directs the medal from the medal sliding surface 401 in the centrifugal direction as the medal take-in rotating disk 41 rotates. Throw out of 1.

  During this time, the count detection unit 5 counts the number of medals thrown out. In addition, a discharge plate 45 (FIG. 7) is provided opposite to the counting detection unit 5, so that the number of medals passing between the detection bearing 44 attached to the counting detection unit 5 and the discharge plate 45 can be reduced. The counting detection unit 5 can reliably count. The counting detection unit 5 is provided with a mechanism for counting medals by converting the optical axis of the photo interrupter to an electric signal by rotating the lever that operates when the medal passes.

  FIG. 9 is a perspective view showing the lower surface of the medal taking-in rotating disk 41 used in the conventional example compared with this embodiment. FIG. 10 is an enlarged view of a B1 portion of the perspective view.

  Below the opening 412 in the B1 portion enlarged in FIG. 10, a shape that forms a circle larger than the medal diameter so as to surround the medal taken from the opening 412 is formed on the lower surface of the medal taking-in rotating disk 41. A protruding portion 414 and a lower surface member 416 that protrude are formed. However, the push-out portion 414 protrudes below the lower surface member 416 by an amount greater than the medal thickness.

  For this reason, during the rotation of the medal take-in rotary disk 41, the protruding portion 414 that protrudes excessively slides on the upper surface of the base member 40, while the lower surface member 416 with less protrusion does not slide on the upper surface of the base member 40, For this reason, a gap corresponding to the above-described thickness is formed between the upper surface and the lower surface member 416 for allowing the thrown medal to pass. With the rotation of the medal take-in rotary disk 41 by the drive motor 43, the medal moves in the direction of arrow B2 and passes through this gap. This gap corresponds to the reference numeral S in FIGS. 18 and 19 described later.

  FIG. 11 is a perspective view showing the lower surface of the medal taking-in rotating disk 41 used in the present embodiment. FIG. 12 is an enlarged view of the B1 portion of the perspective view.

  11 and 12, the medal taking-in rotating disk 41 of this embodiment also has an opening 412 below the opening 412 in the B1 portion to be enlarged, as in FIGS. 9 and 10 of the conventional example. The pushing portion 414 and the lower surface member 416 are formed in a shape that forms a circle larger than the medal diameter so as to surround the medal taken in. The pushing portion 414 has a thickness larger than the medal thickness and protrudes downward from the lower surface member 416.

  Here, in the case of the medal taking-in rotating disk 41 of the present embodiment, as shown in FIGS. 11 and 12, recess portions 417 to which the present invention is applied are formed at both ends of the lower surface member 416. As a result, the gap is expanded only in the portion where the edge passes when the medal center passes through the gap between the lower surface member 416 and the upper surface of the base member 40. The gap corresponds to that of reference S in FIGS. 18 and 19 described later.

  FIG. 13 is a sectional view of the periphery of the medal taking-in rotating disk 41 provided in the payout unit portion 4 of the present embodiment.

  This figure is a cross section in a plane at a position lower than the lower surface of the recessed portion 417 and higher than the lower surface of the lower surface member 416 at both ends of the lower surface member 416. Therefore, the lower surface member 416 shows the outline of the portion excluding the recessed portion 417.

  14 and 15 are a plan view and a side view of medals used in this embodiment and conventionally used, respectively. FIGS. 16 and 17 are enlarged side views of the edge of the medal of the part C in FIG. 15, respectively, which is new or deformed due to use for many years.

  The edge portion Me of the medal M is an outer peripheral portion of the medal M as shown in FIG. 14, and is thicker than the center portion as shown in FIGS. In use, the medal M is hit from the outer periphery, and is deformed by use for many years, and the thickness of the edge portion Me is increased as shown in FIG. Here, the thickness W2 of the medal M in FIG. 17 is larger than the thickness W1 of the new medal M in FIG.

  FIG. 18 and FIG. 19 are schematic diagrams showing the gap S through which the medal M passes in the payout unit portion 4 in the conventional example or in the present embodiment, respectively.

  The gap S is formed between the lower surface member 416 and the upper surface of the base member 40 described above. As shown in the drawing, the thickness of the edge portion Me of the medal is W2, and the thickness of the gap S is W3. When the medal M passes through the gap S, first, the edge Me on the front end side of the medal M passes through the gap S, and thereafter, the portion including the center of the medal and the edge on the tail end side in the moving direction. The part Me passes through the gap S.

  Here, the edge portion Me on the front end side and the tail end side in the advancing direction passes near the center of the gap S, and when the portion including the center of the medal passes, the edge Me is at both ends of the gap S. Go through the side. Therefore, the width W3 of the gap S needs to be (W3> W2) so that the edge portion Me having the thickness W2 can pass through both ends, the vicinity of the center, and any portion.

  As will be described later, when the medal M passes through the gap S, the medal M passing position (congestion position) where the passing of the medal M or the rotation of the medal take-in rotating disk 41 is likely to stagnate or stop to cause deadlock. There is.

  In the present embodiment, such a deadlock is avoided by expanding the gap S of the portion through which the edge portion Me passes at the medal passage position in such a traffic jam position. For example, in FIG. 19, the recessed part 417 is provided in the part of the both ends side of the clearance gap S, and the clearance gap S is expanded to the width W4. In FIG. 19, the dimension W <b> 5 is the depth of the recessed portion 417.

  Here, FIG. 20 to FIG. 23 show the medal take-in in the first to fourth stages until the medal taken into the opening 412 of the medal take-in rotating disk 41 in the present embodiment is thrown out from the payout unit portion 4. It is a top sectional view showing the state of the rotating disk 41 and medals.

  In these FIGS. 20 to 23, in the first to fourth stages, three types of medal taking-in rotating disks 41 are illustrated in the upper, middle, and lower stages.

  First, in the figure of the upper medal taking-in rotating disk 41, a cross-sectional view is shown so that only the pushing part 414 of the disk can be seen. That is, the push-out portion 414 having a large number of protrusions from the medal taking-in rotating disk 41 is cut across, and the lower surface member 416 is a cross-sectional view in a plane that does not cross. Thereby, the payout operation becomes clear.

  Next, in the figure of the middle-stage medal taking-in rotating disk 41, the medal taking-in hole is shown in cross section so that it can be seen. In other words, the extruded portion 414 and the lower surface member 416 are cross-sectional views across a plane, and the recessed portion 417 is a cross-sectional view that does not cross. Thereby, the payout operation becomes clear. The figure of the medal take-in rotary disk 41 in the middle stage can also be said to show the payout operation in the conventional medal take-in rotary disk 41 of FIGS. 9 and 10.

  Subsequently, in the figure of the lower-stage medal taking-in rotating disk 41, the medal taking-in hole is shown in cross section so that it can be seen. That is, it is a cross-sectional view of a plane crossing the extruded portion 414, the lower surface member 416, and the recessed portion 417. Thereby, the position of the recessed part 417 becomes clear.

  Next, each of the first to fourth stages shown in order in FIGS. 20 to 23 will be described. First, in the first stage of FIG. 20, the coin sliding is performed after the medal MA is captured in the opening 412. This is a stage where the surface 401 is slid and conveyed.

  Further, the medal MC of FIG. 20 is in a state of entering the opening 412 while being parallel to the base member 40. The medal MC is in contact with the inner peripheral surface 422 of the disc guide 42 and the pushing portion 414 as shown by a medal B in FIG. 20 due to its own weight or a centrifugal force caused by a rotational motion driven by the medal take-in rotating disc 41. Then, it slides and moves on the coin sliding surface 401 on the base member 40, moves toward the medal payout slot 402, and then enters the state of the medal MA in FIG.

  Next, the second stage in FIG. 21 is a stage in which the medal taking-in rotating disk 41 rotates until the medal MA contacts the detection bearing 44. When the medal take-in rotary disk 41 rotates from the first stage, the medal MA comes into contact with the discharge plate 45 and the detection bearing 44 as shown in FIG. 21 in the second stage.

  Next, the third stage in FIG. 22 is a stage in which the medal MA moves to the counting detection unit 5 side while being in contact with the detection bearing 44. Further, the fourth stage in FIG. 23 is a stage in which the medals MA leave the detection bearing 44 and are thrown out from the unit unit 4. In an initial state where no medal is present, the distance between the discharge plate 45 and the detection bearing 44 is smaller than the medal diameter. When the medal comes into contact, the distance is expanded. Then, when the diameter of the medal is exceeded, the detection bearing 44 pulled by the spring returns to the initial state, and the medal jumps out of the exit vigorously.

  Note that the medal MB in the fourth stage in FIG. 23 is in the same state as the medal MA in the first stage in FIG. 20 in the next stage. After this, all of the second to fourth stages in FIGS. 21 to 23 follow the same state as the medal MA in this order.

  Here, the medal MC in FIG. 22 passes through the position of the medal MB in FIG. 23, the position of the medal MC in FIG. 23, the position of the medal MB in FIG. 23, and the position of the medal MA in FIG. Along the surface 422, the coin slide surface 401 on the upper surface of the base member 40 is slid and conveyed in the space between the upper surface of the base member 40 and the lower surface of the medal take-in rotating disk 41. The space between the upper surface of the base member 40 and the lower surface of the medal taking-in rotating disk 41 is slightly wider than the thickness of the medal because the protrusion of the pushing portion 414 on the lower surface of the medal taking-in rotating disk 41 slides on the upper surface of the base member 40. Maintained.

  If the space between the upper surface of the base member 40 and the lower surface of the medal take-in rotary disk 41 is too wide, two medals may overlap and be taken in from the opening 412 of the medal take-in rotary disk 41. It is narrower than the thickness of the stack. Moreover, the space is wider than the thickness of a medal whose edge has become thicker after many years of use.

  However, even with such a thickness, in the case of a medal with a thick edge, there is a possibility that the medal cannot enter from the opening 412, the above-mentioned space cannot be smoothly conveyed, or it may be caught. For this reason, the present invention is applied and the lower surface member 416 is provided with a recess 417.

  Next, FIG. 24 and FIG. 25 are plan views showing a medal that can be in a deadlock state of the medal taking-in rotating disk 41 in the related art or the present embodiment, and a state of the medal taking-in rotating disk 41, respectively.

  During the first stage of FIG. 20 described above, the medal MA is being thrown out of the disk guide 42. Here, in this first stage, it is assumed that the medal MA moves in the medal taking-in rotating disk 41 with the rotation of the medal taking-in rotating disk 41 without coming out of the disk guide 42. Then, as shown in FIG. 24 and FIG. 25, the medal is sandwiched between the pushing portion 414 and the detection bearing 44. In particular, if the medal is in contact with the pushing portion 414, the center point of the medal, and the medal is in contact with the detection bearing 44, these three points may be in a deadlock state. .

  Normally, the deadlock state can be released by the swinging of the detection bearing 44 described in Patent Document 1. However, when a deadlock is caused by a medal with a thicker edge, the position of the medal does not change even with such a swing, and the deadlock may not be released.

  On the other hand, by applying the present invention, the lower surface member 416 of the above-described medal taking-in rotating disk 41 is provided with a recessed portion 417 at a portion where the edge of the medal contacts or approaches, so that the edge of the medal becomes the lower surface member. 416 is not touched, and it is easy to avoid deadlock. For example, by applying the above-described Patent Document 1, a medal can be paid out without generating a medal.

  Note that the recess 417 of the lower surface member 416 in the present embodiment is provided at a portion where the edge of the medal contacts or approaches in the lower surface member 416, which may cause deadlock or medal passage.

  For example, in the lower stage of FIG. 20 (the payout operation of the present invention) in the first stage, the outer periphery of the medal MB comes into contact with the inner peripheral surface 422 of the disc guide 42 and the medal take-in rotating disc 41 pushing portion 414. . The lower medals MB in FIGS. 21 to 23 are also in contact with each other.

  In this state, a part of the edge of the medal MB is out of the circular portion of the pushing portion 414 and the lower surface member 416, and is scooped from a gap portion between the lower surface member 416 and the upper surface of the base member 40. The edge of the medal MB is a portion about 1 to 2 mm outside the diameter and about 1 to 2 mm inside the diameter.

  For this reason, a part of the edge of the medal MB is positioned in a gap portion between the lower surface member 416 and the upper surface of the base member 40. In the present embodiment, a recess 417 is provided in this portion. The dent amount (dimension W5 in FIG. 19) of the dent portion 417 is required to be equal to or greater than the step size of the edge with respect to the upper and lower surfaces of the medal, but the effect can be exhibited at about 0.2 mm to 0.5 mm.

  In the present embodiment, one lower surface member 416 is provided for each opening 412 of the medal take-in rotating disk 41, and two concave portions 417 are provided at both ends. The two dent portions 417 are substantially equal in length and dent amount. Here, the present invention does not specifically limit the shape, length, or amount of recess of the recess 417. For example, in the medal taking-in rotating disk 41, the shape, length, and amount of dents of the dent portion 417 closer to the center and the dent portion 417 farther from the center may be different. The shape, length, and dent amount of the dent 417 may be determined according to the behavior of the medal driven by the rotation of the medal taking-in rotating disk 41.

DESCRIPTION OF SYMBOLS 1 ... Medal throwing apparatus 2 ... Frame part 3 ... Medal container part 30 ... Medal receptacle 31 ... Chute 34 ... Outer peripheral side wall 34a ... Perpendicular part of outer peripheral side wall 34b ... Volume expansion part of outer peripheral side wall 34d ... Upper extended part 36 DESCRIPTION OF SYMBOLS ... Vertical wall 4 ... Discharge unit part 40 ... Base member 401 ... Coin sliding surface 402 ... Medal payout port 41 ... Medal taking-in rotation disk 42 ... Disc guide 412 ... Opening part 414 ... Extrusion part 416 ... Lower surface member 417 ... Recessed part 422 ... Inner peripheral surface 43 ... Drive motor 431 ... Motor shaft 44 ... Detection bearing 45 ... Discharge plate 5 ... Counting detection unit M ... Medal Me ... Edge of medal outer periphery S ... Gap

Claims (3)

The medal taken in on the rotating disk is opened upward, and the medal taken into the disk through a plurality of openings of a size to receive the medals arranged in the circumferential direction is rotated in the outer circumferential direction by rotating the disk. In the medal throwing device designed to throw a predetermined number,
A clearance larger than the medal thickness is provided between the upper surface of the base member on which the medal take-in rotating disk is rotatably mounted and the lower surface member of the disk for allowing the medal taken from the opening to pass therethrough. A lower surface member of the disk is formed in the vicinity of the opening,
The gap is larger than the thickness of the peripheral edge of the medal, and at the congested position of the medal where the passage of the medal is likely to stagnate or stop, only the portion where the edge of the medal passes extends in the thickness direction. A medal throwing device characterized in that a portion is formed. The medal traffic jam position protrudes from the lower surface of the medal take-in rotary disk and comes into contact with the medal taken in from the opening to push the medal in accordance with the rotation of the disk. The medal position that comes in contact with the inner circumferential surface leading to
2. The medal throwing apparatus according to claim 1, wherein the dent is formed in accordance with the medal traffic jam position. The medal traffic jam position protrudes from the lower surface of the medal take-in rotating disk and comes into contact with the medal taken in from the opening to push the medal in accordance with the disk rotation. The medal position where the pushed out medal comes into contact with the first part,
The medal throwing device according to claim 1 or 2, wherein the dent is formed in accordance with the medal traffic jam position.

Images