JP2010284321A - Token circulation system of game hall - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a token circulation system of a game hall wherein one apparatus is sufficient to use and an equipment cost can be low when disposing two kinds of game machines using tokens of different diameters in one installation bank of game machines. <P>SOLUTION: Two kinds of game machines S1 and S2 in which small and large diameter tokens M1 and M2 are game media are lined in one installation bank of game machines I respectively, and a token recovering and conveying device 1 for recovering the tokens of different outer diameters discharged from the respective game machines in a coexisting state is disposed at the lower part of the installation bank of game machines I. A token supplying and conveying device 2 which has a pair of conveying lines 3a and 3b for separately conveying the tokens of the different outer diameters respectively and supplies the tokens to the respective game machines is disposed at the upper part of the installation bank of game machines. A replenishing body device 5 for sorting the tokens of the different outer diameters recovered by the token recovering and conveying device 1 into small-diameter tokens and large-diameter tokens and supplying the small and large diameter tokens to the respective conveying lines respectively is provided on the end part of the installation bank of game machines. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention automatically applies medals in a game hall where a large number of gaming machines, such as slot machines, coin game machines, and pachinko machines, in which medals with different outer diameters (same as coins and circular chips) are used as game media, are installed. This is related to a medal circulation system of a game arcade that is periodically circulated.

  In general, there are some islands that are installed in a game arcade, in which gaming machines such as slot machines and coin game machines that use medals are arranged. Since a lot of medals are supplied to and discharged from these gaming machines, facilities for automatically supplying medals to each gaming machine and collecting medals from each gaming machine on the installation island are functional. Associated and embedded. That is, a medal collecting and conveying device that collects medals discharged from each gaming machine along the longitudinal direction is arranged at the lower part of the installed island, and is supplied to each gaming machine along the longitudinal direction at the upper part of the installed island. A medal supply transport device for transporting medals is disposed, and a medal lifting lift for transporting medals recovered by the medal recovery transport device is disposed at the longitudinal end of the installation island. Then, the medals lifted by the medal lifting lift are supplied again to the medal supply / conveyance device and also conveyed by the medal supply / conveyance device to be supplied to each gaming machine (for example, see Patent Document 1). .)

  In each of the installed islands, a single type of medal of the same diameter is used for each gaming machine as a game medium, and the supply transport / recovery transport for supplying medals to each gaming machine or collecting them in reverse. All equipment is also made for medals of the same diameter.

Japanese Patent Laying-Open No. 2005-349209 (page 4-9, FIGS. 1 and 3)

  By the way, in general, there are medals having a diameter of 25 mm and those having a diameter of 30 mm, and the outer diameters of medals that can be used differ depending on the type of gaming machine. However, since all the facilities on the installation island according to Patent Document 1 are manufactured using a single medal of the same diameter as a game medium, for example, a medal having a different outer diameter is used as a game medium on one installation island. If different types of gaming machines are to be arranged, facilities equipped with various devices for medals having different outer diameters must be arranged on one installation island. For this reason, there is a fatal problem that the production and construction of the equipment becomes large and the equipment cost becomes high.

  Therefore, the present invention has been made to solve the above problems, and even when two kinds of gaming machines having medals of different outer diameters as game media are mixed and arranged on the installation island, one facility is used. An object of the present invention is to provide a medal circulation system for a game arcade that does not require a large amount of production and construction of the equipment and can reduce the equipment cost.

  In order to achieve such an object, the medal circulation system of the game hall according to the present invention comprises two kinds of gaming machines each having a small diameter medal and a large diameter medal as a game medium, arranged in one installation island, A medal collecting and transporting device for collecting medals discharged from each gaming machine along the longitudinal direction and collecting medals having different outer diameters along the longitudinal direction is arranged at the lower part of the island, and along the longitudinal direction at the upper part of the installed island. A medal supply and transport device that has a pair of transport lines for transporting medals of different outer diameters separately and supplies medals to each gaming machine is provided, and the medal collection transport is performed at the longitudinal end of the installation island. A replenishment main body device that sorts medals with different outer diameters collected by the apparatus into small diameter medals and large diameter medals and supplies these small and large diameter medals to the respective transport lines of the medal supply transport apparatus. The is characterized in that provided.

  Specifically, the replenishment main body device converts the medal collected by the medal collecting and conveying device into a medal lifting lift, and medals discharged from the medal lifting lift into a small diameter medal and a large diameter medal. A medal sorting machine for sorting, and first and second medal storage tanks for separately storing the small and large diameter medals, respectively, and a path switching means for each of the small and large diameter medals sorted by the medal sorting machine. By switching the route, the first and second medal storage tanks or the respective transport lines are supplied.

  At this time, a medal cleaning device for cleaning small and large diameter medals discharged from the first and second medal storage tanks is arranged in the replenishment main body device, and the cleaned small and large diameter medals are transported to the medal. It is preferable to supply the lift.

  The medal circulation system of the game hall according to the present invention has two kinds of gaming machines each using a small-diameter medal and a large-diameter medal as a game medium, arranged on one installation island, and discharged from each gaming machine at the lower part of the installation island. A medal collecting and transporting device for collecting medals of different outer diameters in a mixed state, and a pair of transport lines for separately transporting medals of different outer diameters are arranged in parallel on the upper part of the installation island. A medal supply and transport device for supplying medals to the gaming machine is arranged, and medals with different outer diameters collected by the medal recovery and transport device at the end in the longitudinal direction of the installation island are sorted into small diameter medals and large diameter medals. A replenishment main body device for supplying these small and large diameter medals to each transport line of the medal supply transport device is provided. In this way, the recovered medals are sorted into ones having the same outer diameter, and the selected medals are transported on the transport lines and supplied to the gaming machines. Even if two types of gaming machines that use medals of different diameters as game media are mixed and arranged, medals of different outer diameters can be automatically circulated with one facility. Production and construction are easy, and the equipment cost can be reduced.

  The replenishment main body device includes a medal lifting lift for lifting the medals collected by the medal collecting and conveying device, and a medal sorting machine for sorting medals discharged from the medal lifting lift into a small diameter medal and a large diameter medal. A first and a second medal storage tank for separately storing small and large diameter medals, respectively, by switching the path between the small diameter medal and the large diameter medal selected by the medal sorter by the path switching means. It is preferable to supply one or two medal storage tanks or each conveyance line. Thus, for example, when a certain gaming machine has a request for replenishment of a small diameter medal or a large diameter medal, the medal is intensively discharged from a medal storage tank corresponding to the medal, and the game is performed via a corresponding transport line. The medal can be supplied to the machine, and there is an effect that it can sufficiently cope even in an emergency where the medal should be replenished.

  In addition, if the medal washing device for washing the small and large diameter medals discharged from the first and second medal storage tanks is arranged in the replenishing main unit, medals with different outer diameters can be washed cleanly. The effect that it is suitable is produced.

The top view of the some installation island in the game arcade to which this invention is applied. Side view of one installed island. The enlarged plan view which shows the relationship between the conveyance line and gaming machine in the installation island. Side surface sectional drawing which shows the supply main body apparatus inside a box frame. FIG. The simplified diagram which shows the flow of the medal in a replenishment main body apparatus. The perspective view of a medal sorter. The front view which makes the same part a cross section and shows. The side view which shows the same part as a cross section. The WW line expanded sectional view of FIG. (A) is a side sectional view of the first and second conveying line discharge rods, and (B) is a plan view of the same. The front view of the 1st and 2nd medal storage tank. (A) is the same plane sectional view, (B) is the same side sectional view. (A) is a front sectional view of the lower part of the box frame with the medal cleaning device removed, and (B) is a sectional side view of the same. The perspective view of the medal cleaning apparatus site | part in a box frame. The front view. The expanded front sectional view of a medal washing device site. The expanded front sectional view of a part of medal washing device. XX sectional drawing of FIG. The expansion perspective view of the conveyance belt of the 1st washing part in a medal washing device. The perspective view of the branch unit site | part in a conveyance line. FIG. (A) is the YY line expanded sectional view of FIG. 21, (b) is the ZZ line expanded sectional view. (A) is a side view which shows operation | movement of a rotation member, (b) is the top view. The top view of the branch unit site | part in a conveyance line. The top view which shows the state which replaced the branch unit. Side surface sectional drawing of a box car.

  Hereinafter, the best mode for carrying out the medal circulation system of the game hall according to the present invention will be described in detail. FIG. 1 is a plan view of a plurality of installed islands in a game hall to which the present invention is applied, FIG. 2 is a side view of one installed island, and FIG. 3 is an enlarged plan view showing the relationship between a transfer line and gaming machines in the installed island. FIG. Since each of the installed islands I (I1 to I3) has the same structure, the installed island I1 will be described for convenience. A large number of gaming machines S such as slot machines are arranged in rows on both side surfaces along the longitudinal direction of the installation island I1. Among them, the gaming machine S1 arranged on one side uses a medal M1 having an outer diameter of 25 mm as a gaming medium, and the gaming machine S2 arranged on the other side has a medal M2 having an outer diameter of 30 mm. It is intended as a game medium. In addition, on one side of each of the two types of gaming machines S1 and S2, medal lending units D1 and D2 that are generally referred to as inter-machines are respectively arranged. Then, when the player inserts cash into the medal rental units D1 and D2 or inserts a prepaid card made of a magnetic card, a predetermined number of medals are lent out.

  A medal collection and transport device 1 that collects medals M1 and M2 having different outer diameters discharged from the gaming machines S1 and S2 along the longitudinal direction thereof is disposed below the installation island I1. In addition, a medal supply and transport device 2 having a pair of transport lines 3a and 3b for transporting medals M1 and M2 having different outer diameters along the longitudinal direction thereof in parallel is provided above the installation island I1. Arranged. A medal counter 4 for returning acquired medals to the store side and counting the medals is provided at one end in the longitudinal direction of the installed island I1. Since medals M1 and M2 having different outer diameters are inserted into the medal counter 4, medals M1 and M2 having different outer diameters are mixed. Further, the medals M1 and M2 are also collected by the medal collection and transport device 1. On the other hand, at the other end in the longitudinal direction of each installation island I1, medals M1 and M2 with different outer diameters collected by the medal collection and transport device 1 are selected into small diameter medals M1 and large diameter medals M2. A supply main body device 5 for supplying the medal supply / conveyance device 2 is provided.

  First, the replenishment main unit 5 will be described with reference to FIGS. The supply body device 5 is housed in a box frame B arranged at the other end of the installation island I1. And from the top to the bottom, the medal sorter 6, the pair of first and second medal storage tanks 7a and 7b for separately storing the small and large diameter medals M1 and M2, respectively, and the first and second medal storage The reversible rotating conveyor 8 and the medal cleaning device 9 are arranged in this order, on which small and large-diameter medals M1 and M2 discharged from the tanks 7a and 7b are placed and conveyed to one end side. Further, on one side in the box frame B, the medal lifting lift 10 is erected vertically. 11a and 11b are medal storage mugs provided on both sides of the box frame B so that the medals M1 and M2 can be taken out. These medal storage mugs 11a and 11b are stored in a storage chamber 60 that is opened and closed by an opening / closing door 60a. Further, a control device E for electrically controlling these devices is arranged above the first and second medal storage tanks 7a and 7b and on one side of the medal sorter 6.

  FIG. 6 is a simplified diagram showing the flow of medals in the replenishment main unit. Briefly explaining the flow of medals, the medals M1 and M2 having different outer diameters discharged from the two types of gaming machines S1 and S2 and the medal counter 4 are conveyed by the medal collecting and conveying device 1 while being mixed, It is supplied to the cleaning device 9 and cleaned. The cleaned medals M1 and M2 are lifted by the medal lifting lift 10 and supplied to the medal sorter 6. In the medal sorter 6, the small diameter medal M1 having a small outer diameter and the large diameter medal M2 are sorted, and the selected medals M1 and M2 are switched by the path switching means described later, respectively. The first and second medal storage tanks 7a and 7b, the respective transport lines 3a and 3b, or the medal storage mugs 11a and 11b are supplied. The medals M1 and M2 discharged from the first and second medal storage tanks 7a and 7b and placed on the upper surface of the reversible rotary conveyor 8 are supplied to the medal cleaning device 9 according to the forward / reverse rotation direction of the reversible rotary conveyor 8. Or, it is lifted by the medal lifting lift 10 and supplied to the medal sorter 6.

  The supply body device 5 will be described in more detail. As shown in FIGS. 7 to 9, the medal sorting machine 6 is fixed to the upper surface of the horizontal substrate 12 provided in the box frame B, and these medals M1, M2 are mixed in a state where medals M1, M2 having different diameters are mixed. A medal sending part 13 that aligns and sends M2 one by one and a medal discharge passage part 14 connected to the medal sending part 13 are provided. A circular chamber 15 is formed in the medal delivery section 13. A throwing hook 16 communicating with the circular chamber 15 is provided on one side of the circular chamber 15, and a drive motor 17 is provided on the other side. A delivery disk 18 is disposed in the circular chamber 15 so as to be inclined at an angle of about 60 degrees with respect to a horizontal plane and connected to a motor shaft (not shown) of the drive motor 17. A plurality of protrusions 19, 19,... Arranged at equal intervals in the circumferential direction at intervals slightly wider than the diameter of the large-diameter medal M 2 are formed on the surface of the delivery disk 18. It is provided slightly more inwardly. Each of the medals M1, M2 is disposed one by one between the protrusions 19, 19,... With one side surface in contact with the surface of the delivery disk 18. When the drive motor 17 is driven, the delivery disk 18 rotates at a constant speed, and the medals M1 and M2 disposed between the projections 19 and 19 are guided to the medal discharge passage portion 14.

  The medal discharge passage unit 14 holds the medals M1 and M2 received from the medal sending unit 13 in a substantially upright state, sorts the medals M1 and M2 into the small-diameter medal M1 and the large-diameter medal M2, respectively. It is for feeding into one of the 1 and 2 medal storage tanks 7a and 7b, the transfer lines 3a and 3b, and the medal storage mugs 11a and 11b. Then, as shown in FIG. 10, the cross section is formed to be slightly thicker than the medals M1 and M2, and the width is slightly wider than the diameter of the large diameter medal M2. That is, a pair of spacing members 20, 20 formed slightly thicker than the medals M1, M2 are arranged in parallel with a spacing slightly wider than the diameter of the large diameter medal M2, and the spacing members 20, 20 are arranged in parallel. Plate-shaped side wall plates 21a and 21b are fixed to both side surfaces so as to close the space between them. The medals M1 and M2 in the medal discharge passage portion 14 flow down in the medal discharge passage portion 14 with both side surfaces sandwiched between the side wall plates 21a and 21b. The front side wall plate 21b is formed of a light-transmitting synthetic resin material.

  In the medal discharge passage portion 14, the side wall plates 21a and 21b are inclined at an angle of about 60 degrees with respect to the horizontal plane from the upstream side, and further inclined at an angle of about 30 degrees with respect to the horizontal plane within the inclined plane. A speed increasing area 22a, a screening area 22b that is continuous with the speed increasing area 22a, has side walls 21a, 21b curved upward in a vertical plane, and a lower portion thereof is inclined at an angle of about 30 with respect to a horizontal plane, and the screening area 22b, and a large diameter medal flow area 22c in which only the large diameter medal M2 flows down. In the sorting area 22b, a long hole-shaped drop port 23 is formed along the longitudinal direction of the side wall plate 21a located on the lower side (the side on which one side of the medal slides). The opening width in the direction orthogonal to the longitudinal direction of the drop opening 23 is formed wider than the diameter of the small diameter medal M1 and narrower than the diameter of the large diameter medal M2. Since the passage width of the medal discharge passage portion 14 is set to be slightly wider than the diameter of the large diameter medal M2, a part of the side wall plate 21a is formed on both outer sides in the width direction of the drop opening 23 as shown in FIG. The narrow portions 24 and 24 are left.

  At the lower end of the large-diameter medal flow area 22c in the medal discharge passage portion 14, a large-diameter medal discharge rod 25 as a path is provided as shown in FIG. Also, a small-diameter medal discharge rod 26 as a path communicating with the drop port 23 is provided below the sorting area 22b in the medal discharge passage portion 14 as shown in FIG. As a result, the small-diameter medal M1 dropped from the dropping port 23 enters the small-diameter medal discharge rod 26 and flows down. However, a first branch port 27 is opened at the bottom of the small-diameter medal discharge rod 26. The first branch port 27 communicates with a first transport line discharge rod 28 as a path connected to the transport line 3a for transporting the small diameter medal M1. The first branch port 27 is provided with an opening / closing member 29 as a route switching means. The opening / closing member 29 is bent downwardly in a U-shape and is pivotally mounted at the upper end so as to rotate in a vertical plane. A first solenoid 30 is disposed on one side of the opening / closing member 29 so that the plunger 30a faces upward. A support member 61 is pivotally attached to the distal end portion of the plunger 30a on one side by a support shaft 31 and rotated in a vertical plane. Further, the distal end of the support member 61 is bent on the back surface of the opening / closing member 29. A trochanter 61a that is always in contact with the upper side of the part is attached. Therefore, when the first solenoid 30 is excited, it contracts against the urging force of a compression spring (not shown) in which the plunger 30a is housed as shown by the solid line in FIG. The first branch port 27 is closed by pushing the opening / closing member 29 with the trochanter 61a. On the other hand, when the first solenoid 30 is demagnetized, the plunger 30a is extended by the urging force of the compression spring as shown by the chain line in FIG. 9, the support member 61 returns to its original position, and the opening / closing member 29 also rotates by its own weight. The branch port 27 is opened.

  On the other hand, in the large-diameter medal flow area 22c in the medal discharge passage portion 14, as shown in FIGS. 8 and 9, one spacing member 20 is cut out on one side thereof to form a second branch port 33. . The second branch port 33 communicates with a second transport line discharge rod 34 as a path connected to the transport line 2b that transports the large-diameter medal M2. In addition, a guide member 35 serving as a path switching unit is disposed on the other spacing member 20 so as to face the second branch port 33. The guide member 35 is pivotally supported at one end by a support shaft 36 and is rotated along the inner surfaces of the side wall plates 21a and 21b by excitation and demagnetization of the second solenoid 37 as shown by solid lines and chain lines in FIG. It appears in the discharge passage portion 14. Further, when the guide member 35 enters the medal discharge passage portion 14, the guide surface 35a facing the flow direction of the large-diameter medal M2 gradually advances in the second branch port as the large-diameter medal M2 moves in the flow-down direction. It inclines so that the distance with 33 may become short. Therefore, the large-diameter medal M2 sorted by the upstream sorting area 22b flows down as it is when the guide member 35 is retracted from the medal discharge passage portion 14, reaches the lower end of the large-diameter medal discharge rod 25, and is guided. When the member 35 enters the medal discharge passage portion 14, it abuts on the guide surface 35 a, the course is bent, and flows into the second transport line discharge rod 34 through the second branch port 33.

  A first detection sensor 49 for detecting small and large diameter medals M1 and M2 passing through the speed increasing area 22a is disposed and fixed in the speed increasing area 22a of the medal discharge passage portion 14. Similarly, the second detection sensor 50 for detecting the large-diameter medal M2 passing through the large-diameter medal flow area 22c is fixedly disposed in the large-diameter medal flow area 22c of the medal discharge passage portion 14. For example, in the gaming machines S1 and S2, when the number of medals M1 and M2 decreases and the small diameter medal M1 or the large diameter medal M2 needs to be replenished, the first branch port 27 or the second branch leading to the transport lines 3a and 3b The opening 33 is opened, and a predetermined amount of medals M1 and M2 are placed on the transport lines 3a and 3b via the first and second transport line discharge rods 28 and 34 and supplied to the predetermined gaming machines S1 and S2. At this time, by detecting the number of medals passed by the first detection sensor 49 and the second detection sensor 50, how many of the small diameter medals M1 or the large diameter medals M2 are in the gaming machines S1 and S2 requesting the medals. It is convenient to know whether it has been replenished, and it is easy to manage. The number of small diameter medals M1 is calculated by subtracting the count number by the second detection sensor 50 from the count number by the first detection sensor 49. In this way, the required amount of medals M1, M2 can always be supplied to the gaming machines S1, S2.

  At the lower end of the small and large diameter medal discharge rods 26 and 25, two first and second distribution rods 38 and 39 respectively communicating with these are arranged in parallel as shown in FIGS. The lower end of each flow is connected to the first medal storage tank 7a and the second medal storage tank 7b, respectively. An upstream opening 42 that communicates with the left-hand mug discharge rod 40 and a downstream opening 43 that communicates with the right-hand mug discharge rod 41 are opened along the flow direction of the first and second distribution rods 38 and 39. The upper and downstream openings 42 and 43 are pivotally mounted on the downstream side by the support shaft 44 and the upstream side and the downstream side are rotated by a third and fourth solenoids 45 and 46 in a plane perpendicular to the bottom surface thereof. Switching members 47 and 48 for opening and closing the openings 42 and 43 are arranged, respectively. When the third solenoid 45 or the fourth solenoid 46 is excited to rotate the switching member 47 or the switching member 48 to open the upstream opening 42 or the downstream opening 43 as shown in FIG. 47 and 48 block the first distribution rod 38 or the second distribution rod 39, and small and large diameter medals M1 and M2 flowing down the first distribution rod 38 or the second distribution rod 39, respectively. Guide to left side mug discharge rod 40 or right side mug discharge rod 41.

  As shown in FIG. 13 (b), the left mug discharge rod 40 passes the left first medal storage tank 7a up and down, and the lower end of the left side medal storage tank 7a is disposed below the first medal storage tank 7a. It communicates with the mug 11a. The right mug discharge rod 41 passes through the right second medal storage tank 7b up and down, and its lower end communicates with the right medal storage mug 11b disposed below the second medal storage tank 7b. . Therefore, for example, the third solenoid 45 of the first distribution rod 38 is excited to rotate the switching member 47 upward to open the upstream opening 42 and the fourth solenoid 46 of the second distribution rod 39 is excited. When the switching member 48 is rotated upward to open the downstream opening 43, the small-diameter medal M1 is stored in the left medal storage mug 11a via the left mug discharge rod 40. Further, the large-diameter medal M2 is stored in the right medal storage mug 11b via the right mug discharge rod 41. Conversely, the fourth solenoid 46 of the first distribution rod 38 is excited to rotate the switching member 48 to open the downstream opening 43 and the third solenoid 45 of the second distribution rod 39 is excited to switch. When the member 47 is rotated upward to open the upstream opening 42, the large-diameter medal M2 is stored in the left medal storage mug 11a via the left mug discharge rod 40. Further, the small-diameter medal M1 is stored in the right medal storage mug 11b via the right mug discharge rod 41.

  As shown in FIGS. 12, 13 (b) and 13 (b), the first and second medal storage tanks 7 a and 7 b are communicated with the first sorting rod 38 by the left first medal storage tank 7 a as viewed from the front. The small diameter medal M1 is stored. Further, the second medal storage tank 7b on the right side when viewed from the front is in communication with the second sorting rod 39, and the large-diameter medal M2 is stored. Each of the first and second medal storage tanks 7a and 7b is formed in a substantially rectangular parallelepiped shape, and the periphery thereof is sealed. The bottom surface of the first and second medal storage tanks 7a and 7b is narrowed in a funnel shape toward the lower side. An exit 51 is established. Correspondingly, the drive motor 53 is attached to the top plate 52a. The drive shaft 53a of the drive motor 53 intervenes in the first and second medal storage tanks 7a and 7b, and the center axis of the drive motor 53 coincides with the center of the discharge port 51 on the same vertical line. A helical stirring coil 54 is attached to the drive shaft 53a, and the lower end of the stirring coil 54 faces the discharge port 51 from above. As a result, when the drive motor 53 is stopped, the lower end of the stirring coil 54 closes the discharge port 51 so that the small diameter medal M1 or the large diameter medal M2 does not fall down from the discharge port 51. . On the other hand, when the drive motor 53 is driven, the stirring coil 54 rotates about the central axis, stirs the internal small diameter medal M1 or the large diameter medal M2 and breaks them, and discharges them from the discharge port 51. A front plate 52b that closes a part of each of the first and second medal storage tanks 7a and 7b is formed of a transparent material, and the inside can be visually recognized through the front plate 52b.

  The reversible rotating conveyor 8 is arranged below the discharge ports 51, 51 of the first and second medal storage tanks 7a, 7b as shown in FIGS. The lengths of the medals M1 and M2 are set so as to be carried. A driving roller 56 having a reversible rotation motor 55 attached to one end is disposed, and a driven roller 57 is disposed to the other end. An endless belt 58 is wound between the driving roller 56 and the driven roller 57. On the side of the driven roller 57, a cleaning device discharge rod 59 whose lower end faces a medal collecting box 62 described later on the medal cleaning device 9 is disposed. On the other hand, on the drive roller 56 side, a first throwing chute 63 facing each bucket 90 described later is disposed. Therefore, when the reversible rotation motor 55 is rotating forward, the medals M1 and M2 discharged from either the left or right first and second medal storage tanks 7a and 7b are conveyed to the cleaning device discharge rod 59 side, They fall on the cleaning device transporting tub 59 and are cleaned in the order in which they are stored in the medal collection box 62 of the medal cleaning device 9. On the other hand, when the reversible rotation motor 55 is rotating in the reverse direction, the medals M1 and M2 discharged from either of the first and second medal storage tanks 7a and 7b are conveyed to the medal lifting lift 10 side. At that end, it is discharged to the first charging chute 63.

  As shown in FIGS. 15 to 19, the medal cleaning device 9 includes a first cleaning unit W1 and a second cleaning unit W2, and the small-diameter medal M1 and the large-diameter medal M2 housed in the medal collecting box 62 are the first cleaning unit W1 and the second cleaning unit W2. By passing through the cleaning unit W1 and the second cleaning unit W2, the medals M1 and M2 are sequentially cleaned one by one. The 1st washing | cleaning part W1 and the 2nd washing | cleaning part W2 are formed in the front surface of the assembly | attachment board 64 supported vertically. 65a shows the conveyor of the 1st washing | cleaning part W1, 65b shows the conveyor of the 2nd washing | cleaning part W2. The medal collecting box 62 has an open top surface and a bottom surface 62a formed as an inclined surface, and a lower end portion of the conveyor 65a of the first cleaning unit W1 faces the inclined lower side surface.

  The endless conveyance belt 66a of the conveyor 65a is formed of a constant width belt-like rubber cloth belt, and the height is slightly lower than the thickness of the small diameter medal M1 and the large diameter medal M2 (height 1.4 mm) as shown in FIG. A large number of engaging portions 67 having a diameter of about 3 mm are formed side by side in the width direction of the belt surface at intervals of 22 mm narrower than the diameter of the medals M1 and M2, and the medal M1 is formed in the longitudinal direction of the belt surface. It is formed continuously at an interval of 35 mm wider than the diameter of M2. 68a and 69a are a driving roller and a driven roller of the conveyor 65a around which the conveyor belt 66a is wound. The conveyor 65a is supported such that the conveying surface of the conveying belt 66a is inclined upward (standing angle: about 70 degrees) from the medal collecting box 62, and the conveying belt 66a is in the direction indicated by the arrow in FIG. , The medals M1 and M2 in the medal collection box 62 are engaged with each other between the pair of adjacent engaging portions 67 and 67 and carried out obliquely upward.

  Reference numeral 70a designates an endless belt-shaped wet wipe 71a impregnated with a cleaning liquid, which is stretched in parallel with a distance from the transport surface of the transport belt 66a, and travels in a fixed direction. This is a wiping cloth supporting mechanism that wipes the surfaces of the medals M1 and M2 with the wet wiping cloth 71a. In the wiping cloth support mechanism 70a, the wet wiping cloth 71a is wound around the guide roller 72a, the guide roller 73a, and the driving rubber roller 74a, and the tension roller 75a is pressed against the wet wiping cloth 71a, thereby the wet wiping cloth 70a. 71a is stretched in parallel with the conveying surface of the conveying belt 66a, and the driving rubber roller 74a rotates to move the wet wipe 71a in the direction indicated by the arrow in FIG. The traveling speed of the wet wipe 71a is set to be lower than the traveling speed of the conveyor belt 66a (about 1/10 speed). In this way, when the wet wipe 71a is run in the same direction as the medal conveyance direction and at a lower speed than the conveyance belt 66a, the wet wipe 71a applies an excessive load to the medal being conveyed due to friction, and the medal Is prevented from jumping out on both sides of the conveyor belt 66a.

  The guide roller 72a is connected to a cleaning liquid tank (not shown) via a tube and a solenoid valve. When the timer is activated, the solenoid valve is opened, for example, every 5 minutes, and the cleaning liquid is transferred to the guide roller 72a from the cleaning liquid tank. By replenishing 3 cc at a time, the wet wiping cloth 71a is always maintained in an appropriate wet state. A wet sensor for detecting the wet state of the wet wipe 71a may be provided so that the cleaning liquid is automatically supplied from the cleaning liquid tank by the detection, so that the wet wipe 71a is maintained in an appropriate wet state. .

  As shown in FIGS. 18 and 19, 76 a is a wiping cloth pressing mechanism provided to elastically press the wet wiping cloth 71 a against the surfaces of the medals M <b> 1 and M <b> 2 conveyed by the conveying belt 66 a. The wiping cloth pressing mechanism 76a has a synthetic resin pressing plate 78a having a plurality of longitudinal grooves 77a formed on the surface at appropriate intervals on the inner side of the cover plate 79a, and is fixed to the back surface of the pressing plate 78a. The support shaft 80a is inserted into the cover plate 79a, and an elastic body 81a such as a coil spring is interposed between the pressing plate 78a and the cover plate 79a in a compressed state, and the cover plate 79a is attached to the frame of the conveyor 65a. A plurality of knob screws 82a are detachably assembled. And it is comprised so that this press board 78a can press the wet wiping cloth 71a from the back surface by the elasticity of this elastic body 81a. The cover plate 79a and the pressing plate 78a are detached from the conveyor frame by loosening the knob screw 82a so that the wet wipe 71a can be replaced as necessary.

  In the second cleaning section W2, the conveyor 65b and the wiping cloth support mechanism 70b are arranged in a relationship where the top and bottom of the first cleaning section W1 are turned upside down, and the conveyor belt 66b of the conveyor 65b and the wet wiping cloth 71b of the wiping cloth support mechanism 70b. The conveyance surface formed by is inclined obliquely downward (downward tilt angle: about 30 degrees). 83 is a distance between the conveyor belt 66b of the second cleaning unit W2 and the wet wiping cloth 71b by receiving the medals M1 and M2 discharged from the upper end of the conveyor 65a of the first cleaning unit W1 and taking the medals M1 and M2 under their own weight. It is a transfer board provided in a slanting shape to guide to. For this reason, the conveyor 65a of the 1st washing | cleaning part W1 and the conveyor 65b of the 2nd washing | cleaning part W2 are arrange | positioned on the front surface of the assembly | attachment board 64 so that it may continue in a front "H" shape via the transfer board 83. The conveyor 65b is formed by winding a conveyor belt 66b made of a constant-width rubber belt around a driving roller 68b and a driven roller 69b, like the conveyor 65a, and the conveyor belt 66b is on the surface of the conveyor belt 66a. Such an engaging portion is not formed, and the surface having fine irregularities is used, so that high frictional properties are obtained with respect to the medal surface. For this reason, the medals M1 and M2 sliding down from the transfer plate 83 are transported obliquely downward between the wet wipes 71b by driving the transport belt 66b in the direction indicated by the arrow in FIG. Thus, since the engaging portion like the conveying belt 66a is not formed on the conveying belt 66b, there is no possibility that the medals M1 and M2 ride on the engaging portion in the second cleaning portion W2, and the first cleaning is performed. There is no trouble that the medals M1 and M2 sent from the part W1 stay, and the medals M1 and M2 can always be transported smoothly.

  Further, in the wiping cloth support mechanism 70b, the wet wiping cloth 71b is wound around the guide roller 72b, the guide roller 73b and the driving rubber roller 74b in the same manner as the wiping cloth supporting mechanism 70a, and the driving rubber roller 74b moves in the direction indicated by the arrow in FIG. Traveled. The traveling speed of the conveyor belt 66b is set slightly higher than the traveling speed of the conveyor belt 66a. This is to prevent the medals transported by the transport belt 66a from collecting on the transfer plate 83. Similarly to the wiping support mechanism 70a, the wiping support mechanism 70b has a wet wiping cloth 71b wound around a guide roller 72b, a guide roller 73b, and a driving rubber roller 74b, and is driven by the driving rubber roller 74a in the direction indicated by the arrow in FIG. It travels at a lower speed (about 1/10 speed) than the traveling speed of the conveyor belt 66b.

  The drive rollers 68a and 68b, the drive rubber rollers 74a and 74b, and the like are connected to transmission mechanisms such as sprockets, chains, and gears of a gear box (not shown) provided on the back side of the assembly plate 64. The motor (not shown) is driven to rotate at the predetermined speed by using a drive source. The guide roller 72b is replenished with the cleaning liquid from the cleaning liquid tank in the same manner as the guide roller 72a, and the wet wiping cloth 71b is always maintained in an appropriate wet state. Further, the wiping cloth pressing mechanism 76b is configured in the same manner as the wiping cloth pressing mechanism 76a, and the pressing plate 78b presses the wet wiping cloth 71b, and the surfaces (lower surfaces) of the medals M1 and M2 conveyed downward by the conveying belt 66b. ) Elastically press the wet wipe 71b.

  In the medal cleaning device 9, medals having different diameters of the small diameter medal M1 and the large diameter medal M2 can be transported by engaging with the engaging portion 67 of the transport belt 66a, and a wet wipe is applied to the surfaces of the medals M1 and M2. When 71a is pressed by the pressing plate 78a with an appropriate pressing force, the medals M1 and M2 can be reliably wiped off. Further, after passing through the first cleaning unit W1, the medals M1 and M2 reach the second cleaning unit W2 and are transported obliquely downward by friction with the transport belt 66b, and wet wipes 71b are placed on the lower surfaces of the medals M1 and M2. , The medals M1 and M2 can be cleaned cleanly one side at a time. For this reason, according to the medal cleaning device 9, the small diameter medal M1 and the large diameter medal M2 can be cleaned continuously and neatly, and there is no need to provide two cleaning devices for each medal size as in the prior art. The size of the frame B can also be reduced. Thus, the medals M1 and M2 cleaned by the medal cleaning device 9 are discharged to the second throwing chute 86 and carried into the medal lift 10.

  The engaging portion 67 of the conveyor belt 66a is a short cylindrical projection. However, in the present invention, the engaging portion 67 is not limited to this shape, and the small diameter medal M1 and the large diameter medal M2 are transferred to the conveying belt 66a. As long as it can be locked to the surface, it may be formed in other forms, for example, a U-shaped frame-like engaging portion is formed. Moreover, although the fine unevenness | corrugation (concave part or convex part) illustrated in the said embodiment was formed in the conveyance belt 66b like a striped pattern, the friction coefficient with the small diameter medal M1 and the large diameter medal M2 can be raised. Thus, other forms may be formed.

  As shown in FIGS. 4 and 5, the medal lift 10 has an endless chain 89 wound between a driving sprocket 88a and a driven sprocket 88b provided at the upper and lower portions in a rectangular casing 87. A plurality of buckets 90 for placing the medals M1 and M2 on the endless chain 89 are mounted at equal intervals. A first throwing chute 63 facing one end of the reversible rotary conveyor 8 is provided on one side of the casing 87 and closer to the lower part, and one end of the conveyor 65b on the second cleaning unit W2 side in the medal cleaning device 9 is provided at the lower end. A second input chute 86 is provided. On the other hand, a lead-out rod 91 connected to the medal delivery unit 13 in the medal sorter 6 is connected to the upper end outlet of the casing 87. A drive motor 92 is disposed on one side of the upper portion of the casing 87 and drives the drive sprocket 88a. Therefore, when both the sprockets 88a and 88b are rotated by the drive motor 92 and the buckets 90 are moved up, the medals M1 and M2 in the first throwing chute 63 or the second throwing chute 86 are scooped by the bucket 90 and lifted. Then, it is supplied to the medal sending unit 13 of the medal sorter 6 from the lead-out rod 91 at the upper end.

  As shown in FIG. 2, the medal collecting and conveying apparatus 1 is configured by winding an endless collecting belt 94 around a driving roller 93a and a driven roller 93b disposed at both ends in the longitudinal direction of the installation island I1, One end of the collection belt 94 on the side of the driven roller 93b enters the box frame B through the opening B1 provided on the side wall of the box frame B. Then, the drive roller 93a is rotated by the drive motor 93c so that the small diameter medal M1 and the large diameter medal M2 discharged from the respective gaming machines S1 and S2 are mixed and placed on the upper surface of the collecting belt 94, Transport to B side. In the box frame B, as shown in FIGS. 4 and 14, an accumulation box 95 that receives the medals M1 and M2 conveyed by the collection belt 94 is disposed. The accumulation box 95 has a bottom wall inclined substantially downward toward the center, and a collection lift 96 is disposed on one side thereof. The collection lift 96 is erected obliquely on the bottom surface of the box frame B, and the lower end opening 95 a of the bottom wall of the accumulation box 95 faces the top surface of the collection lift 96. A contact rod 97 for receiving the medals M1 and M2 discharged from the upper end of the recovery lift 96 and dropping them into the medal collection box 62 of the medal cleaning device 9 is disposed below the upper end of the recovery lift 96. . Thereby, the medals M1 and M2 having different outer diameters collected by the collecting belt 94 are received in the accumulation box 95 and are transported by the collecting lift 96, and fall from the upper end portion to the contact rod 97 to be medal washing apparatus. 9 is poured into the medal collection box 62.

  As shown in FIG. 3, of the two transport lines 3a, 3b in the medal supply transport device 2, one transport line 3a transports a small-diameter medal M1 having an outer diameter of 25 mm. Are arranged on the transport line 3a side for transporting the small diameter medal M1. The other transport line 3b transports a large diameter medal M2 having an outer diameter of 30 mm, and a plurality of gaming machines S2 having the large diameter medal M2 as a game medium are arranged on the transport line 3b side for transporting the large diameter medal M2. The Each of the transport lines 3a and 3b is formed in a long groove shape, and as shown in FIG. 2, drive pulleys 98a are arranged at both ends along the longitudinal direction on the medal counter 4 side, and on the box frame B side. A driven pulley 98b is arranged. An endless transport belt 99 is wound between the driving pulley 98a and the driven pulley 98b. As shown in FIGS. 21 and 22, a bottom plate 100a is stretched on the bottom surface of each of the transport lines 3a and 3b, and the transport belt 99 moves while sliding on the top surface of the bottom plate 100a. The driven pulley 98b is located in the box frame B, and the lower end of the first transport line discharge rod 28 in the medal sorter 6 faces the upper side corresponding to the transport line 3a, and the second transport is above the transport line 3b. The lower end of the line discharge rod 34 faces. A pair of branch units 101a and 101b are provided on the transfer lines 3a and 3b for the respective gaming machines S1 and S2. The pair of branch units 101a and 101b are juxtaposed along the transfer lines 3a and 3b.

  Each of the transport lines 3a and 3b is divided into a certain equal length along the longitudinal direction of the side walls that are far from each other in the width direction, and as shown in FIG. 22, the predetermined length (in the transport lines 3a and 3b). The side plate 100b having the same length as the support frame 103, which will be described later, is formed by screwing and connecting to the conveying lines 3a and 3b with screws 102 and 102, respectively. By removing the screws 102 and 102, the side plates 100b can be freely connected. Can be removed. The pair of branch units 101a and 101b will be described in more detail. The branch units 101a and 101b of the transport line 3a for the small diameter medal M1 and the branch units 101a and 101b of the transport line 3b for the large diameter medal M2 have the same configuration. Therefore, for convenience, the branch units 101a and 101b of the transport line 3a for the small diameter medal M1 will be described. Among these, the branch unit 101a to which the transported small-diameter medal M1 reaches first is for supplying the small-diameter medal M1 into the gaming machine S1 corresponding to the branch unit 101a, and the other branch units 101b are This is for supplying the medal M1 to the medal lending unit D1 attached to the gaming machine S1. Since the pair of branch units 101a and 101b have the same structure, the first branch unit 101a will be described, and the description of the subsequent branch unit 101b will be omitted.

  The preceding branch unit 101a has the following configuration. That is, as shown in FIGS. 21 and 22, the branch unit 101a includes a support frame 103 attached so as to straddle the upper side of the transport line 3a, a rotating member 104 attached to the support frame 103, And a branch chute 105 for receiving the small-diameter medal M1 guided by the rotating member 104. The support frame 103 has a pair of parallel support plates 103a and 103b having the same length as the side plate 100b along the conveying line 3a and a height higher than the side plate 100b. An opening 106 is opened at the center of the pair of support plates 103a and 103b on the opposite side of the support plate 103b opposite to the adjacent conveyance line 3b. Further, as shown in FIG. 23 (a), screw insertion holes 107, 107 are provided on both sides of the support plate 103b, and screw holes provided on the side surface of the conveying line 3a corresponding to the screw insertion holes 107, 107. The support frame 103 is attached by screwing the screws 102, 102 to 108, 108. Therefore, by removing each screw 102, it can be easily attached to the opposite conveyance line 3b.

  As shown in FIGS. 24 (A) and 24 (B), a support shaft 109 is horizontally mounted between a pair of support plates 103a and 103b in the support frame 103, and one end of the rotating member 104 is pivoted on the support shaft 109. The other end can be turned up and down in a plane parallel to the conveying direction. Further, the lower part of the rotating member 104 is perpendicular to the bottom surface of the conveying line 3a when rotated downward and has a V-shaped cross section (opening angle of about 90 degrees) and crosses the conveying line 3a. In this way, a branch plate 104a for blocking is provided. In addition, the top of the branch plate 104 a faces the opening 106. As a result, of the both side surfaces 104b and 104b of the branch plate 104a, the surface 104b facing the transport direction of the transport line 3a is always inclined so that the distance from the opening 106 gradually becomes smaller as it proceeds in the transport direction. Yes. A solenoid 110 in which a plunger 110a is provided along the transport line 3a is disposed above the rotating member 104 and between the support plates 103a and 103b. The tip of the plunger 110a of the solenoid 110 is interposed via a link 111. The rotating member 104 is attached to the upper surface on the tip side. The link 111 is pivotally attached to a side face-shaped first link 111a that is pivotally attached to a support shaft 112 that is horizontally mounted between the support plates 103a and 103b, and a first end that is pivotally attached to the tip of the first link 111a. The second link 111b is pivotally attached to the proximal end of the first link 111a, and the distal end of the plunger 110a of the solenoid 110 is pivotally attached to the pivot member 104.

  A branch chute 105 is disposed on the outer surface of the support plate 103b located on the outer side, that is, on the opposite side to the other transport line 3b so as to communicate with the opening 106. The inner bottom surface of the branch chute 105 is funnel-shaped, and a flexible supply pipe 114 connected to the gaming machine S1 is connected to the lower end of the branch chute 105. The branch chute 105 is disposed between a pair of holding pieces 115 and 115 that protrude from both sides of the opening 106 on the outer surface of the outer support plate 103b as shown in FIG. The holding pieces 115, 115 and the side wall 105a of the branch chute 105 are provided with screw insertion holes 116, 116 which communicate with each other, and the screw 117a is inserted into the screw insertion holes 116, 116 and a nut 117b is screwed into the screw 117a. By doing so, the branch chute 105 is attached.

  When the solenoid 110 is demagnetized, the plunger 110a is advanced by the urging force of the internal compression spring as shown by the solid line in FIG. 24 (a), and the other end of the rotating member 104 is pulled up and held. . In this state, the rotating member 104 is stopped with the lower end edge of the branch plate 104a separated from the conveying surface of the conveying belt 99 by a distance of at least about 2 to 3 times the thickness of the tokens M1 and M2. Therefore, the small-diameter medal M1 conveyed on the upper surface of the conveyance belt 99 flows without being supported by the branch plate 104a. On the other hand, when the solenoid 110 is energized, the plunger 110a is retracted against the bias of the internal compression spring, and the other end of the rotating member 104 is held down as shown by the chain line in FIG. . In this state, the rotating member 104 stops at a position where the lower edge of the branch plate 104a is substantially in contact with the transport surface of the transport belt 99, and the small-diameter medal M1 transported on the upper surface of the transport belt 99 is placed on one of the branch plates 104a. It is received by the side surface 104 b and guided to the opening 106. The small diameter medal M1 guided to the opening 106 falls into the branch chute 105 through the opening 106, and is further supplied to the gaming machine S1 through the supply pipe 114. The medal lending unit D1 is similarly supplied with the small-diameter medal M1 from the branch unit 101b.

  A medal supply control device 118 is attached to each of the branch units 101a and 101b. The medal replenishment control device 118 detects when the number of small medals M1 in the gaming machine S1 or medal lending unit D1 corresponding to the branch units 101a and 101b is smaller than a predetermined number (not shown). The signal is output to the control device E arranged in the box frame B so as to replenish the gaming machine S1 or the medal lending unit D1 with the small diameter medal M1.

  Here, for example, when exchanging the gaming machine S1 using the small diameter medal M1 as a gaming medium and the gaming machine S2 using the large diameter medal M2 as a gaming medium, as shown in FIG. As shown in FIG. 26, the branch unit 101a attached to the transfer line 3a for use is replaced with the opposite large-diameter transfer line 3b. In this case, the screws 102 on both sides of the support plate 103b are removed and the branch unit 101a is removed. Further, the side plate 100b at a predetermined position in the conveyance line 3b for the large-diameter medal on the opposite side is also removed by removing the screw 102, and the branch unit 101a is disposed at the same position and the screws 102, 102 are moved to the conveyance line 3b. Install by screwing. At this time, the direction of the solenoid 110 along the transport direction of the transport line 3b is reversed, but the branch plate 104a has a V-shaped cross section, and the medals M1 and M2 have either side surface 104b, Even if it collides with 104b, it will be guided to the opening 106, so that the large diameter medal M2 transported on the transport line 3b can also be guided to the branch chute 105 by the branch plate 104a. The branch unit 101b connected to the medal lending unit D2 is also replaced in the same manner. The supply pipes 114 and 114 in each branch unit 101a and 101b are connected to the newly replaced gaming machine S2 and medal lending unit D2. As described above, even when the exchange between the gaming machines S1 and S2 occurs in one installation island I1, the branch units 101a and 101b are detachably attached. . For example, when a gaming machine S using medals of the same size as game media is installed on the installation island I, the branch units 101a and 101b that have been attached to both sides of the transfer lines 3a and 3b until then are installed. The branch units 101a and 101b attached to one of the transfer lines 3a and 3b are all replaced with the other transfer lines 3a and 3b. As a result, even if all the gaming machines S on the installed island I are changed to ones using any one of the medals M1 and M2 as gaming media, the gaming machine can be used by using only one of the transport lines 3a or the transport lines 3b. S can be replenished with the small diameter medal M1 or the large diameter medal M2.

  The medal counter 4 is arranged on one outer side along the longitudinal direction of the installation island I1, and the medal counter 4 is installed on the upper surface of the box car 120 that is closed as shown in FIG. An opening 121 having a predetermined size is opened on the top plate 120a of the cart 120 so as to face the lower surface of the medal counter 4. A discharge lift 122 that is inclined toward the medal collecting and conveying apparatus 1 is installed in the box car 120. A recovery chute 123 whose lower end opening is located on the upper surface of the recovery belt 94 of the medal recovery transport device 1 is connected to the upper end of the discharge lift 122. Thereby, the small-diameter medals M1 and the large-diameter medals M2 with different outer diameters that are input into the medal counter 4 are dropped into the box car 120, and are transported by the discharge lift 122 and also by the recovery chute 123. It rides on the upper surface of the recovery belt 94 of the medal recovery transfer device 1 and is transferred to the box frame B side at the other end of the installation island I1. In addition, casters 119 are attached to the four corners of the lower surface of the box car 120 so that the box car 120 can be moved freely.

  In addition, distribution towers 124a to 124c for distributing small and large diameter medals M1 and M2 to other installation islands I are erected on the installation islands I1 to I3 at positions close to the box frame B. Each of the distribution towers 124a to 124c is formed in a rectangular column shape that is long in the vertical direction, and a lifting lift is erected in the interior thereof although not shown. These lifts are supplied with small and large diameter medals M1 and M2 from the transfer lines 3a and 3b. In addition, distribution conveyors 125a and 125b for transferring small and large diameter medals M1 and M2 between the distribution towers 124a to 124c are bridged between the distribution towers 124a to 124c on the respective installation islands I1 to I3. . The small and large diameter medals M1 and M2 discharged from the distribution conveyors 125a and 125b are supplied to the transfer lines 3a and 3b and replenished to the installation islands I1 to I3. As a result, not only the supply / distribution of small / large diameter medals M1, M2 to each gaming machine S1, S2 on each installed island I1-I3, but also the supply of small / large diameter medals to each installed island I1-I3 Distribution can be performed, and supply management of the small and large diameter medals M1 and M2 to the gaming machines S1 and S2 in the entire hall becomes possible. Note that the replenishment management is controlled by the control device E or a hall computer (not shown) that controls the entire hall.

  The medal circulation system of the game hall according to the present invention has the above configuration, and the operation thereof will be described next. During operation of the installed islands I1 to I3, the medals M1 and M2 discharged from the respective gaming machines S1 and S2 and having different outer diameters fall on the upper surface of the recovery belt 94 of the medal recovery transport device 1, and the recovery belt 94 causes the box frame to be dropped. B is conveyed into B. The medals M1 and M2 conveyed by the collection belt 94 are collected in the accumulation box 95.

  Therefore, for example, when cleaning the small and large medals M1 and M2, the recovery lift 96, the medal cleaning device 9, the medal lift 10, the medal sorter 6, the first and second medal storage tanks 7a and 7b, reversible The carousel 8 is activated. The small and large diameter medals M1 and M2 in the accumulation box 95 are sequentially lifted by a collection lift 96, fall downward from the upper end thereof, and collect in a medal collection box 62 on the medal cleaning device 9 side through a contact rod 97. It is done. The medals M1 and M2 collected in the medal collection box 62 in this way are firmly polished on both sides through the first cleaning unit W1 and the second cleaning unit W2 in the medal cleaning device 9. The medals M1 and M2 discharged from the second cleaning unit W2 are collected by the second throwing chute 86 and are sequentially beaten and transported by the bucket 90. The medals M1 and M2 that have reached the upper end of the endless chain 89 are supplied to the medal sending unit 13 of the medal sorter 6 via the lead-out rod 91. The medals M1 and M2 are sorted by the medal sorter 6 into a small diameter medal M1 and a large diameter medal M2. The small diameter medal M1 and the large diameter medal M2 sorted by the medal sorter 6 are stored in the first and second medal storage tanks 7a and 7b via the first and second sorting rods 38 and 39, respectively. The stored medals M1 and M2 are discharged from the first and second medal storage tanks 7a and 7b to the reversible rotating conveyor 8 that rotates in the forward direction, fall from one end thereof, and are collected in the medal collection box 62. It is cleaned by the cleaning device 9 and is lifted by the medal lifting lift 10 and again sorted by the medal sorter 6. In this way, the medals M1 and M2 are automatically circulated and washed.

  Further, when storing the small and large diameter medals M1 and M2 in the medal storage mugs 11a and 11b, the switching members 47 and 48 in the first and second sorting rods 38 and 39 are operated so that the upper and lower openings 42 and 43 are opened. By opening, the small and large diameter medals M1 and M2 sorted by the medal sorter 6 are stored in the medal storage mugs 11a and 11b on both sides. For example, the small diameter medal M1 is stored in the medal storage mug 11a positioned on the left side in FIG. 6, that is, the large diameter medal M2 is stored in the medal storage mug 11b positioned on the right side in FIG. Conversely, the large diameter medal M2 may be stored in one medal storage mug 11a, the small diameter medal M1 may be stored in the other medal storage mug 11b, and both the small medal storage mugs 11a and 11b may have a small diameter. The medal M1 or the large-diameter medal M2 can be stored.

  When a signal that the small-diameter medal M1 has become insufficient in a certain gaming machine S1 is output from the corresponding medal supply control device 118 to the control device E during operation of the installed islands I1 to I3, the medal sorter 6 The first solenoid 30 is demagnetized and the opening / closing member 29 is rotated to open the first branch port 27. Thus, the selected small diameter medal M1 is supplied to the small diameter medal M1 transport line 3a via the first transport line discharge rod 28. The small diameter medal M1 discharged to the small diameter medal transport line 3a is transported by the transport line 3a toward the gaming machine S1 that needs to replenish the small diameter medal M1. On the other hand, in the branch unit 101a corresponding to the gaming machine S1 that needs to be replenished, the solenoid 110 is excited, the rotating member 104 is lowered, the branch plate 104a reaches the upper surface of the transport belt 99, and the small diameter medal M1 that is transported. Is introduced into the branch chute 105 through the opening 106. The small diameter medal M1 guided to the branch chute 105 is supplied to a predetermined gaming machine S1 through the supply pipe 114. If necessary after the replenishment of the small diameter medal M1 in the previous branch unit 101a, the solenoid 110 in the subsequent branch unit 101b is excited, and the small diameter medal M1 is similarly replenished to the medal lending unit D1.

  When urgent replenishment of medals is required, for example, when urgent replenishment of small-diameter medals M1, the second-medal storage tank 7b is stopped while the first-medal storage tank 7a is operated, and the large-diameter medals M2 are discharged. Stop. Further, the reversible rotary conveyor 8 is reversed. Thereby, the small-diameter medal M1 discharged from the first medal storage tank 7a falls from the other end of the reversible rotary conveyor 8 to the first throwing chute 63. The small-diameter medal M1 dropped on the first throwing chute 63 is lifted by the bucket 90 of the medal lifting lift 10 and supplied from the upper end portion thereof to the medal sending portion 13 of the medal sorter 6 via the lead-out bar 91. At this time, the medal cleaning device 9 is stopped, and supply of medals from the medal cleaning device 9 to the medal lifting lift 10 is stopped. Therefore, the medals lifted by the medal lift 10 are almost only the small diameter medal M1 and the ratio of the small diameter medal M1 is increased, and the ratio of the small diameter medal M1 inevitably discharged from the medal sorter 6 is also increased. These small-diameter medals M1 are supplied to the conveyance line 3a for the small-diameter medals M1 via the first conveyance line discharge rod 28. In this way, it is possible to sufficiently meet the demand for prompt medal replenishment. When the large-diameter medal M2 is insufficient in the gaming machine S2 using the large-diameter medal M2 as a game medium, rapid replenishment is performed in the same manner.

  In the rare case where medals M1 and M2 need to be replenished urgently, medals filled with small-diameter medals M1 or large-diameter medals M2 are stored in the storage chamber 60 in the box frame B. It is also possible to carry the storage mugs 11a and 11b by hand and supply the medals M1 and M2 to a predetermined gaming machine S1 or gaming machine S2.

  Regarding the increase / decrease of small and large medals M1 and M2 between the installed islands I1 to I3, it is necessary to determine which installed islands I1 to I3 have more or less biased small and large medals M1 and M2. The distribution towers 124a to 124c and the distribution conveyors 125a and 125b are actuated so as to uniformly supply and distribute them.

  As described above, the medal circulation system of the game hall according to the present invention has two kinds of gaming machines S1 and S2 each having a small-diameter medal M1 and a large-diameter medal M2 as game media arranged in one island I. A medal collection and transfer device 1 that collects medals M1 and M2 discharged from the respective gaming machines S1 and S2 and having different outer diameters is disposed at the lower part of the installation island I. A medal supply transport device 2 having a pair of transport lines 3a and 3b for transporting the medals M1 and M2 separately and supplying the medals M1 and M2 to the gaming machines S1 and S2 is disposed, and the longitudinal direction of the installation island I The medals M1 and M2 with different outer diameters collected at the end of the medal by the medal collecting and conveying apparatus 1 are sorted into the small diameter medal M1 and the large diameter medal M2, and the small and large diameter medals M1 and M2 are respectively supplied to the medal supply and conveying apparatus. 2 Transport line 3a, and to provide a supply main device 5 supplying the 3b. Then, the collected medals M1 and M2 are sorted into those having the same outer diameter, and the sorted medals M1 and M2 are transported on the transport lines 3a and 3b to be supplied to the gaming machines S1 and S2. Therefore, even if two kinds of gaming machines S1 and S2 having medals M1 and M2 having different outer diameters as a game medium are mixed and arranged on one installation island I, the outer diameter can be obtained with one facility. Medals of different sizes can be automatically circulated, the equipment can be easily manufactured and constructed, and the equipment cost can be reduced.

  The replenishment main body device 5 includes a medal lifting lift 10 for lifting medals M1 and M2 collected by the medal collecting and conveying device 1, and medals M1 and M2 discharged from the medal lifting lift 10 as small diameter medals M1. The medal sorter 6 for sorting the large diameter medal M2 and the first and second medal storage tanks 7a, 7b for separately storing the small and large diameter medals M1, M2 are selected by the medal sorter 6. The small-diameter medal M1 and the large-diameter medal M2 are supplied to the first and second medal storage tanks 7a and 7b or the respective transport lines 3a and 3b by switching the path by the path switching means. Thus, for example, when a certain gaming machine S1, S2 is requested to supply a small-diameter medal M1 or a large-diameter medal M2, the medals M1, M2 are concentrated from the medal storage tanks 7a, 7b corresponding to the medals M1, M2. Can be supplied to the gaming machines S1 and S2 via the corresponding transfer lines 3a and 3b, and even in an emergency where the medals M1 and M2 should be replenished .

  Further, if the medal washing device 9 for washing the small and large diameter medals M1 and M2 discharged from the first and second medal storage tanks 7a and 7b is arranged in the replenishing main body device 5, the outer diameter is increased. Different medals can be cleaned at the same time, which is preferable. In the present invention, the medal counter 6 is disposed at the end of the installation island I opposite to the box frame B, but may be disposed adjacent to the box frame B. In this case, the counted small and large diameter medals M1 and M2 are supplied to the medal cleaning device 9.

DESCRIPTION OF SYMBOLS 1 Medal collection conveyance apparatus 2 Medal supply conveyance apparatus 3a Conveyance line 3b Conveyance line 5 Supply body apparatus 6 Medal sorter 7a First medal storage tank 7b Second medal storage tank 9 Medal washing apparatus 10 Medal lifting lift 25 Path (large diameter) Medal discharge 樋)
26 Route (Small Diameter Medal Discharge)
28 route (first transport line discharge rod)
29 Route switching means (opening / closing member)
34 route (second transport line discharge 樋)
35 Route switching means (guidance member)
I (I1-I3) Installation island M1 Small diameter medal M2 Large diameter medal S1 Game machine S2 Game machine

Claims (3)

Two types of gaming machines that use small-diameter medals and large-diameter medals as game media are lined up on an installation island,
A medal collecting and conveying device that collects medals discharged from each gaming machine along the longitudinal direction and having different outer diameters along the longitudinal direction is disposed at the lower part of the installation island,
A medal supply and transport device for supplying medals to each gaming machine having a pair of transport lines that individually transport medals of different outer diameters along the longitudinal direction thereof at the top of the installation island;
The medals with different outer diameters collected by the medal collecting and transporting device at the end in the longitudinal direction of the installation island are sorted into small diameter medals and large diameter medals, and these small and large diameter medals are respectively selected in the medal supply and transport device. A medal circulation system for a game hall, characterized in that a supply main body device is provided to supply each of the transfer lines.   The replenishment main unit includes a medal lifting lift that lifts the medals collected by the medal collecting and transporting device, and a medal sorting machine that sorts medals discharged from the medal lifting lift into small diameter medals and large diameter medals. And first and second medal storage tanks for separately storing the small and large diameter medals, respectively, and the path switching means switches the path between the small diameter medal and the large diameter medal selected by the medal sorter. 2. A game medal circulation system according to claim 1, wherein the first and second medal storage tanks are supplied to each of the transfer lines.   3. A game medal circulation system according to claim 1 or 2, wherein a medal cleaning device for cleaning small and large diameter medals discharged from the first and second medal storage tanks is arranged in the replenishment main unit.

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