JP5280048B2 - Game ball supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a game ball feeder which does not need a large installation space and does not incur cost increase. <P>SOLUTION: The game ball feeder 1 which is provided in a bank 100 of game machines where a plurality of game machines are arrayed in the longitudinal direction and supplies game balls to the respective game machines comprises: a conveying belt 12 arranged in the longitudinal direction of the bank 100 of game machines and trained on two rollers; a drive source 13 for circulating the conveying belt 12; a replenishing gutter 27 provided with a plate part 28a provided with a gap right below the conveying belt 12, for moving the game balls in a loose state between the plate part 28a and the conveying belt 12; a plurality of replenishing chutes 40 provided along the longitudinal direction of the replenishing gutter 27, for guiding the game balls moving through the replenishing gutter 27 to the respective game machines; and a speed imparting means provided on the conveying belt 12, for imparting a speed to the game balls in the loose state accompanying the circulation of the conveying belt 12. <P>COPYRIGHT: (C)2009,JPO&amp;INPIT

Description

  The present invention relates to a game ball supply device that is provided on a game island and supplies game balls to game machines.

  In a conventional game hall, a plurality of gaming machines are arranged along the longitudinal direction of the gaming island, and a supply device for supplying gaming balls to each gaming machine is provided at the upper part of the gaming island.

  In general, such a supply device is provided with a basket tilted in the longitudinal direction of the game island, and a game ball is rolled by its own weight with the kite and supplied to each gaming machine.

Further, in Patent Document 1, a game ball is conveyed by rotation of an endless belt in a state where the game ball is sandwiched between an endless belt whose bottom surface is horizontal and a conveyance path disposed below the endless belt. However, a horizontal transfer device that replenishes the gaming machine is disclosed.
JP-A-2005-279711

  However, in the case of a device that rolls a game ball with its own weight and supplies the game ball to each gaming machine, it is necessary to incline the cage, so that a large installation space is required in the height direction. For this reason, there is a problem that the game hall becomes narrow or the lighting is blocked and it becomes dark.

  In the case of the horizontal conveyance device disclosed in Patent Document 1, a large installation space is not required in the height direction, but the game ball is conveyed with the game ball held between the endless belt and the conveyance path. As a result, the load applied to the drive source increases. Therefore, there is a problem that a drive source having a large output is required and the cost is increased.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a game ball supply device that does not require a large installation space and does not increase costs.

A first aspect of the present invention is a gaming ball supply device that is provided on a gaming island in which a plurality of gaming machines are arranged in the longitudinal direction and that supplies gaming balls to each gaming machine, and is arranged at intervals in the longitudinal direction of the gaming islands Two rollers having a rotation shaft extending in the short direction of the game island, an endless conveyance belt wound around the two rollers, one of the rollers is driven to rotate, and the conveyance belt is circulated. A replenishing rod for moving a game ball in a loosely-fitted state between the flat plate portion and the transport belt, and a replenishment rod that moves between the flat plate portion and the transport belt. A plurality of supply chutes that are provided along the longitudinal direction of the kite and guide the game balls that move the supply kit to each gaming machine, and are provided on the conveyor belt, and are loosely fitted as the conveyor belt circulates. With speed to give speed to game balls in state And means, wherein the conveyor belt, the lateral direction is arranged to be inclined at a predetermined inclination angle, the supply gutter is disposed to be inclined at the same inclination angle with the conveyor belt, the replenishment A chute is provided on the lower side of the replenishment basket, and gaming machines are arranged in a short-sided state in the short direction on the gaming island, and the replenishment chute is a game ball that moves on the flat plate portion, A first supply chute to be supplied to a gaming machine located on the lower side of the supply basket and a second supply to supply a game ball moving on the flat plate portion to a gaming machine located on the higher side of the supply basket. It includes a chute, the characterized by Rukoto.

The second invention is characterized in that the replenishing rod is formed such that the inclination angle on the low side in the flat plate portion is larger than that on the high side.

According to a third aspect of the present invention, the speed imparting means is a magnetic body provided on a belt surface, and the game ball of the replenishing basket receives the action of the magnetic body, and the transport belt circulates, It moves on a flat plate part.

According to a fourth aspect of the present invention, the speed imparting means is a projecting wall that is erected in the belt short direction and is arranged at a predetermined interval in the belt longitudinal direction. As the conveyor belt circulates, the protruding wall contacts and moves on the flat plate portion.

According to a fifth aspect of the present invention, the speed imparting means is a plurality of hemispheres provided so as to protrude from the belt surface of the transport belt, and the game ball of the replenishment basket is accompanied by the rotation of the transport belt. The hemisphere contacts and moves on the flat plate portion.

The sixth invention is characterized in that the hemispheres are arranged in a staggered manner.

  According to the first invention, since the speed is applied to the game ball by the speed applying means provided on the conveyor belt, it is not necessary to incline the game ball supply device in the longitudinal direction, and a large installation space is required in the height direction. And not. In addition, the game balls are transported in a loosely fitted state between the transport belt and the flat plate portion provided immediately below by the action of the speed imparting means, and are supplied to each gaming machine. Thus, since the game ball is transported without being pinched by the transport belt, the load applied to the drive source is suppressed and the cost is not increased.

In addition , since the conveyor belt and the replenishing rod are disposed to be inclined in the lateral direction, it is not necessary to level the conveyor belt and the replenishing rod in the short direction, and the conveyor belt and the replenishing rod are simply disposed. be able to.

In addition , the supply chute is provided on the low side of the supply basket, and the game balls moving on the supply basket are distributed from the low side to the short side and supplied to the gaming machines arranged in a back-facing state. . Therefore, it is possible to evenly distribute the game balls to the gaming machines arranged in the back-facing state.

According to the second aspect of the invention, the game ball that has moved the supply basket and moved to the low side by its own weight is less likely to be affected by the speed imparting means due to the large inclination, and is smoothly guided to the supply chute.

According to the third aspect of the present invention, the game balls of the replenishment basket are sandwiched between the transport belts because they are affected by the magnetic body provided on the transport belt and move on the flat plate portion as the transport belt circulates. And the load on the drive source is suppressed.

According to the fourth aspect of the present invention, the supply ball game ball moves on the flat plate portion with the protruding wall abutting as the conveyor belt circulates, so that the driving source is not pinched by the conveyor belt. The load applied to the is suppressed.

According to the fifth aspect of the present invention, the supply ball game ball is driven without being pinched by the transport belt because the hemisphere contacts and moves on the flat plate portion as the transport belt circulates. The load on the source is suppressed.

According to the sixth invention, since the hemispheres are arranged in a staggered manner, the game balls can escape to the gap between the hemispheres adjacent in the short direction, and the occurrence of clogging of the balls is prevented.
Further, the game ball that has escaped into the gap comes into contact with the subsequent hemisphere, and is given a speed in the belt longitudinal direction.

  Embodiments of the present invention will be described below with reference to the drawings.

  First, with reference to FIG. 1, the game island 100 provided with the game ball supply device 1 according to the present embodiment will be described. FIG. 1 is a perspective view showing the internal structure of the game island 100.

  The amusement island 100 is installed in a game arcade, and is provided with a plurality of gaming machines (not shown) and incidental facilities.

  The gaming island 100 has a plurality of gaming machine installation openings 5 arranged in two rows in the longitudinal direction. A gaming machine is installed in the gaming machine installation opening 5. Thereby, the gaming machines are arranged in the longitudinal direction of the gaming island 100, and are arranged in the back direction in which the respective back surfaces are combined in the short direction.

  Below the gaming machine on the gaming island 100, a lower tank 2 for storing gaming balls used for gaming is provided. The game balls in the lower tank 2 are guided to the lifting device 3 provided at the approximate center in the longitudinal direction of the game island 100.

  The lifting device 3 is a device that lifts the game ball upward while polishing the game ball, and the game ball lifted by the lifting device 3 is guided to the upper tank 4 installed at the upper part of the lifting device 3. It is written.

Each of the right and left sides of the upper tank 4, the gaming machine game balls of the upper tank 4, and the game ball supply to supply feed to the spherical lending machine (not shown) for dispensing game ball juxtaposed to each game machine The device 1 is connected. In FIG. 1, only the game ball supply device 1 connected to one side of the upper tank 4 is shown. In the following, left and right refer to the longitudinal direction of the game island 100, and front and rear refer to the short direction of the game island 100.

  The gaming balls supplied from the gaming ball supply device 1 to the gaming machine are paid out to the player as prize balls from the gaming machine, and the paid gaming balls are set in a ball counter installed on the gaming island 100. (Not shown) and collected in the lower tank 2.

  The game balls supplied from the game ball supply device 1 to the ball lending machine are used for games in the game machines, and the game balls discharged from the game machines are collected in the lower tank 2. In the present embodiment, the lower tank 2 is provided with a storage function for the collection basket that collects the game balls discharged from the gaming machine and guides it to the lifting device 3, and is located downstream of the collection basket. An opening / closing member (not shown) is provided.

  As described above, the game balls in the game island 100 circulate in the game island 100.

  Next, the game ball supply device 1 will be described in detail mainly with reference to FIGS. 2 is a perspective view of the upstream end (upper tank 4 side) of the game ball supply device 1, FIGS. 3 and 4 are perspective views of the downstream end of the game ball supply device 1, and FIG. 5 is a game ball supply device. 6 is a front view of the upstream end of FIG. 1, FIG. 6 is a longitudinal sectional view of the upstream end of the gaming ball supply device 1, and FIG. 7 is a longitudinal sectional view of the downstream end of the gaming ball supply device 1. FIG. 9 is a cross-sectional view in the short direction of the game ball supply device 1.

  The game ball supply device 1 rotates an endless transport belt 12 wound around two rollers 10 and 11 (see FIGS. 6 and 7) provided on the upstream side and the downstream side, and a roller 11 on the downstream side. A drive motor 13 (see FIGS. 3 to 5) is provided as a drive source for driving and circulating the conveyor belt 12.

  The conveyor belt 12 is horizontally disposed in the longitudinal direction of the game island 100, and as shown in FIGS. 6 and 7, the lower portion 12a and the upper portion 12b on the flat plate, the arc-shaped upstream arc portion 12c and the downstream side It is comprised from the circular arc part 12d.

  The game ball supply device 1 includes a support member 15 that supports the transport belt 12. The support member 15 extends in the longitudinal direction of the game island 100 and is attached to and fixed to the upper portion of the game island 100. The

  As shown in FIGS. 8 and 9, the support member 15 is formed so as to stand on both ends of the bottom portion 16 a and the bottom portion 16 a disposed along the lower surface of the upper portion 12 b of the transport belt 12. A supporting portion 16 having a U-shaped cross section having a standing wall 16b surrounding the vertical wall 16b, and a flange portion 17 extending horizontally from each of the front and rear standing walls 16b and attached to the upper part of the game island 100.

  As described above, the support member 15 is attached and fixed to the upper portion of the game island 100 via the flange portion 17, and supports the upper portion 12 b of the transport belt 12 by the support portion 16.

  As shown in FIGS. 3 to 5, the drive motor 13 is supported by a motor support member 18 fixed to the game island 100. The output shaft 13 a of the drive motor 13 is connected to the first pulley 19, the shaft 11 a of the roller 11 is connected to the second pulley 20, and the first pulley 19 and the second pulley 20 are linked via a belt 21. A bearing 22 (see FIG. 3) that supports the shaft 11 a of the roller 11 is supported by a downstream support member 23 attached to the downstream end of the support member 15.

  The roller 11 is rotationally driven by rotationally driving the drive motor 13, and the conveyor belt 12 circulates between the roller 11 and the roller 10. Thus, the roller 11 is the main drive side, and the roller 10 is the driven side.

  As shown in FIGS. 2 and 5, the bearing 24 that supports the shaft 10 a of the driven roller 10 is supported by an upstream support member 25 attached to the upstream end of the support member 15.

  Directly below the lower portion 12a of the conveyor belt 12, as shown in FIGS. 6 to 9, a supply rod defining member 28 that forms a supply rod 27 in which a game ball moves between the lower portion 12a and the lower portion 12a. Extending along the line.

  The supply rod defining member 28 is attached and fixed to the upstream support member 25 and the downstream support member 23 at both ends.

  As shown in FIG. 8 and FIG. 9, the replenishing bowl defining member 28 has a flat plate portion 28a disposed at a predetermined distance from the lower portion 12a of the conveyor belt 12, and both ends of the flat plate portion 28a. It is a U-shaped member having a U-shaped cross section composed of an upright wall 28b for preventing a game ball that is standingly formed and moves on the supply basket 27 from falling.

  The conveyor belt 12 is a known magnetic belt having a magnetic body (not shown) provided on the belt surface (see JP-A-3-46942). The magnetic bodies are formed so as to extend in the belt longitudinal direction, and are arranged at predetermined intervals in the belt lateral direction. Further, the S pole and the N pole are alternately arranged in the short direction of the belt. The replenishing bowl defining member 28 is made of a nonmagnetic material.

  As shown in FIG. 6, a communication passage 29 communicating with the upper tank 4 is connected to the upstream end of the replenishment rod 27, and the game ball guided from the upper tank 4 to the communication passage 29 passes through the inlet portion 27a. Into 27. Since the interval between the lower portion 12a of the conveyor belt 12 and the flat plate portion 28a of the replenishing bowl defining member 28 is set slightly larger than the diameter of the game ball, the game ball guided from the upper tank 4 The portion 27a smoothly flows into the replenishment rod 27 and is guided onto the flat plate portion 28a. There is a slight gap between the upper end of the game ball that has flowed into the supply basket 27 and the lower surface of the lower portion 12a. In this way, the game ball flowing into the replenishing basket 27 is guided onto the flat plate portion 28a in a loosely fitted state without being sandwiched between the flat plate portion 28a and the lower portion 12a of the conveyor belt 12.

  The game ball that has flowed into the replenishment basket 27 is subjected to the action of the magnetic body provided on the transport belt 12, and moves on the flat plate portion 28a at a speed in the belt longitudinal direction as the lower portion 12a moves. As described above, the magnetic force of the magnetic material of the transport belt 12 is set to such a magnitude that the game ball is not attracted to the transport belt 12 but moves on the flat plate portion 28 a by the movement of the transport belt 12.

  The magnetic body provided on the conveyor belt 12 corresponds to speed imparting means for imparting a speed to the loosely-fitted game ball between the lower portion 12a and the flat plate portion 28a as the conveyor belt 12 circulates. . The game ball is given a speed by the action of the magnetic body and moves the replenishment rod 27 in a loosely fitted state. Since the game ball is nipped by the conveyor belt 12 and conveyed without being pumped, the load on the drive motor 13 increases. There is nothing.

  Here, the loosely-fitted game ball is a state in which there is a gap between the upper end of the game ball and the lower part 12a as described above, and since the tension of the conveyor belt 12 is small, the lower part 12a This includes a state where the ball is bent downward and is in contact with the upper end of the game ball.

  The game ball moving on the supply basket 27 is guided from the supply chute 40 shown in FIG. The replenishment chute 40 will be described in detail later.

  As shown in FIGS. 3, 4, and 7, an arcuate curved member 31 is disposed at the downstream end of the conveyor belt 12 along the outer periphery of the downstream arc portion 12 d of the conveyor belt 12. The bending member 31 forms an end rod 30 to which the game ball moves with the downstream arc portion 12d.

  The bending member 31 is provided with a predetermined interval from an arcuate body 31a attached and fixed to the downstream support member 23, and a downstream arc 12d of the conveyor belt 12 provided on the inner periphery of the body 31a. And a curved portion 31b.

The curved portion 31b is formed of urethane resin, and the interval between the curved portion 31b and the downstream arcuate portion 12d is set slightly smaller than the diameter of the game ball. Accordingly, among the game balls that move on the supply basket 27, the game balls that have not been supplied from the supply chute 40 to the gaming machine and the ball rental machine reach the downstream end of the conveyor belt 12 and flow into the end cage 30. To do. The game ball that has flowed into the end cage 30 is sandwiched between the curved portion 31b and the downstream arc portion 12d, and moves on the inner periphery of the curved portion 31b by the movement of the downstream arc portion 12d of the conveyor belt 12. It is guided onto the upper part 12 b of the belt 12.

As shown in FIGS. 8 and 9, the upper part 12b is surrounded by the standing wall 16b of the support member 15 and the weight of the game ball guided on the upper part 12b is disposed below the upper part 12b. Is supported by the bottom 16a. Thus, the upper portion 12b by the supporting portion 16, the upper trough 35 which game balls to move by the movement of the upper portion 12b is formed.

  In the upper basket 35, the direction in which the game ball moves is opposite to that of the supply basket 27, that is, upstream and downstream of the supply basket 27 are reversed. The game ball of the upper basket 35 moves in a direction toward the upper tank 4.

  The game ball moving on the upper basket 35 is guided from the auxiliary chute 41 provided on the upper basket 35 to the supply chute 40 shown in FIG. The auxiliary chute 41 will be described in detail later.

  Of the game balls moving on the upper basket 35, the game balls that are not led from the auxiliary chute 41 to the supply chute 40 reach the downstream end of the upper basket 35 and fall from the upper basket 35 to the communication path 29. The game ball that has fallen into the communication path 29 flows again into the replenishment rod 27 through the inlet 27a.

  Thus, out of the game balls guided from the upper tank 4 to the replenishment rod 27, it is not guided to any of the replenishment chute 40 provided on the replenishment rod 27 and the auxiliary chute 41 provided on the upper reed 35. The game balls that have not been supplied to the game machine and the ball lending machine do not circulate in the game island 100 but return to the supply cage 27 and circulate in the game ball supply device 1 along the transport belt 12.

  Next, the supply chute 40 provided on the supply rod 27 and the auxiliary chute 41 provided on the upper rod 35 will be described mainly with reference to FIGS. FIG. 10 is a perspective view of the supply chute 40 and the auxiliary chute 41 in the game ball supply device 1.

  The supply chute 40 includes a gaming machine supply chute 40A (40a) for supplying gaming balls to a gaming machine and a ball rental machine supply chute 40B (40b) for supplying gaming balls to a ball rental machine. The supply chute 40A and the ball lending machine supply chute 40B are provided along the longitudinal direction of the supply rod 27. A gaming machine supply chute 40A is provided for each gaming machine, and a ball lending machine supply chute 40B is provided for each ball lending machine. Hereinafter, the replenishment chute 40A (40a) for the gaming machine and the replenishment chute 40B (40b) for the ball lending machine are collectively referred to as the “replenishment chute 40”.

  The auxiliary chutes 41 are provided corresponding to all the replenishing chutes 40 along the longitudinal direction of the upper flange 35. That is, the same number of auxiliary chutes 41 as the replenishing chutes 40 are provided on the upper rod 35.

  As shown in FIGS. 5, 8, and 9, the conveyance belt 12 is disposed to be inclined at a predetermined inclination angle in the lateral direction. Specifically, the front side shown in FIG. 1 is high and the back side is low. Thereby, the upper collar 35 is formed to be inclined in the lateral direction. Further, since the flat plate portion 28a of the replenishing rod defining member 28 is also inclined and arranged at the same inclination angle as the conveyor belt 12, the replenishing rod 27 is also inclined and formed in the short direction.

  As described above, the transport belt 12, the replenishing rod 27, and the upper collar 35 are disposed horizontally while being inclined in the lateral direction, while being horizontal in the longitudinal direction.

  Since the supply basket 27 and the upper basket 35 are formed to be inclined in the short direction, the supply chute 40 and the auxiliary chute 41 are provided so that the game balls can be supplied to the gaming machine and the ball lending machine by their own weight. Provided on the lower side of the replenishment rod 27 and the upper rod 35.

  In other words, the game balls moving on the replenishment rod 27 and the upper reed 35 move in a state where the game balls approach the low place due to their own weight, and the game is played through the supply chute 40 and the auxiliary chute 41 disposed on the low place side. Supplied to machines and ball lending machines.

  Since the game balls moving on the replenishment rod 27 and the upper reed 35 move toward the low side, the game balls that fall from the upper reed 35 and return to the replenishment reed 27 again, and the communication path from the upper tank 4 In the vicinity of the entrance 27a of the supply basket 27 where the game balls flowing into the supply basket 27 through 29 are joined, there is a possibility that the game balls will be jammed and a ball will be clogged. In order to avoid this, as shown in FIG. 2 and FIG. 5, a game ball approaching the low side of the upper rod 35 is guided to the high side on the low side of the downstream end of the upper rod 35. A guide plate 36 is provided for guiding the supply rod 27 to the inlet 27a. The guide plate 36 is attached to the standing wall 16 b of the support portion 16 and is formed to extend obliquely toward the center of the upper flange 35. By providing the guide plate 36 on the lower side of the downstream end of the upper basket 35, the flow of game balls in the vicinity of the inlet 27a of the supply basket 27 is made uniform, thereby preventing the game balls from being clogged.

  Further, as shown in FIGS. 5, 8, and 9, the replenishing rod 27 is formed such that the inclination angle on the low side of the flat plate portion 28 a of the replenishing rod defining member 28 is larger than that on the high side. Specifically, the lower end portion 28c of the flat plate portion 28a is bent to have a large inclination angle. Therefore, the game ball which has moved the replenishment rod 27 and moved to the lower side by its own weight is guided toward the replenishment chute 40 by the large inclination of the end portion 28c, and has a large distance from the magnetic conveying belt 12. Therefore, it is less likely to be affected by the magnetic force from the conveyor belt 12, so that it is smoothly guided to the supply chute 40. Note that the shape of the end portion 28c is not limited to a flat plate shape as illustrated, and may be a curved surface shape.

  The gaming machines are arranged in the short direction of the gaming island 100 in a back-facing state in which the respective back surfaces are combined. For this reason, one of the pair of gaming machines arranged in the back-facing state is positioned on the low side of the replenishment rod 27 and the other is positioned on the high side.

For replenishing chute 40 is provided in the low-income side of the supply trough 27, for the game machine and the sphere rental machine located on low-income side of the supply trough 27, as the game ball is supplied through supply chute 40. On the other hand, as shown in FIGS. 5 and 10, for a gaming machine and a ball lending machine located on the high side of the supply basket 27, a supply basket defining member connected to the outlet portion 42 of the supply chute 40 is used. A game ball is supplied through a connecting rod 49 disposed across the lower portion of the 28 flat plate portions 28a.

  In this way, the game balls moving on the supply rod 27 are distributed from the low side of the supply rod 27 in the front-rear direction through the supply chute 40 provided on the low side of the supply rod 27, and arranged in a back-facing state. Supplied to the game machines and ball lending machines. Therefore, it is possible to evenly distribute gaming balls to gaming machines and ball lending machines arranged in a back-facing state.

As described above, a pair of gaming machines and ball lending machines arranged in a back-facing state are as shown in FIG. 10 with respect to the gaming machines and ball lending machines located on the low side of the replenishment basket 27. A replenishment chute 40A and a ball lending machine replenishment chute 40B for supplying balls, and a replenishment chute 40a for a gaming machine for supplying gaming balls to the gaming machines and ball lending machines located on the high side of the replenishment basket 27 In addition, a total of four supply chutes 40 including a ball lending machine supply chute 40b are provided.

  Since the auxiliary chutes 41 are provided corresponding to all the replenishing chutes 40, a total of four auxiliary chutes 41 are provided in a pair of gaming machines and ball lending machines arranged in a back-facing state, like the replenishing chutes 40.

  As shown in FIG. 10, the supply chute 40 includes a housing 43 attached to the standing wall 28 b on the lower side of the supply basket defining member 28 and a cover 44 that seals the housing 43. Note that the gaming machine supply chutes 40A and 40a in FIG. 10 are views with the cover 44 removed.

  The housing 43 is formed with an inlet 45 that communicates with an opening formed in the standing wall 28 b on the lower side of the supply basket defining member 28 and receives a game ball from the supply basket 27.

  The bottom surface of the housing 43 is formed so as to incline downward, and is configured as a guide path 46 that guides the game ball flowing in from the inlet portion 45 to the outlet portion 42 provided at the downstream end.

  The inlet portion 45 is formed such that the longitudinal dimension of the replenishing basket 27 is such that a plurality of game balls can pass therethrough. The outlet portion 42 is formed to a size that allows one game ball to pass through. In addition, the guide path 46 is formed with a width that allows the game ball to roll with one line.

  In the middle of the guide path 46, a leveling member 47 is provided for leveling the game balls rolling on the guide path 46 up and down. Accordingly, the game balls that have flowed into the housing 43 from the inlet 45 fall onto the guide path 46 and roll on the guide path 46, and are leveled up and down one level by the leveling member 47. It is discharged from the part 42. The game ball discharged from the outlet 42 is supplied to a game machine or a ball lending machine.

  The upper portion of the housing 43 is formed by being opened without being sealed by the cover 44, and the outlet portion 42 of the auxiliary chute 41 communicates with the opening.

  Immediately below the outlet portion 42 of the auxiliary chute 41 in the housing 43 of the replenishment chute 40, a guide path 48 that guides the game ball discharged from the outlet portion 42 of the auxiliary chute 41 to the guide path 46 is inclined downward. Established.

  Therefore, the game ball discharged from the outlet portion 42 of the auxiliary chute 41 and flowing into the housing 43 of the supply chute 40 is guided from the guide path 48 to the guide path 46 and discharged from the outlet section 42.

  Thus, in the housing 43 of the replenishment chute 40, the game ball that has flowed from the inlet 45 of the replenishment chute 40 and the game ball that is guided from the guide path 48 merge. However, since the merge portion where the game balls merge is provided on the upstream side of the leveling member 47, the game balls are prevented from being clogged at the outlet portion 42 of the supply chute 40.

  The supply chute 40 is configured as described above, and the gaming machine supply chute 40A and the ball lending machine supply chute 40B are similarly configured.

  The auxiliary chute 41 has an inlet 45 that receives a game ball from the upper basket 35, and the inlet 45 is formed to communicate with an opening formed in the standing wall 16 b on the lower side of the support 16. Other configurations of the auxiliary chute 41 are the same as those of the supply chute 40, and the same reference numerals are given to the same configurations as the supply chute 40.

  Since the auxiliary chute 41 is provided on the lower side of the upper basket 35, the game ball moving on the upper basket 35 is guided to the supply chute 40 from the lower side. Therefore, the game balls moving on the upper basket 35 are evenly distributed to the replenishment shoots 40.

  As described above, among the game balls circulating in the game ball supply device 1 along the conveyor belt 12, the game ball moving on the supply basket 27 is guided to the low place side by its own weight and is supplied from the supply chute 40 to the game machine. Alternatively, the game balls that are supplied to the ball lending machine and move along the upper basket 35 are also guided to the low place by their own weight, led to the supply chute 40 through the auxiliary chute 41, and supplied to the game machine or ball lending machine. The

  Here, when the operation of the gaming machines arranged on the gaming island 100 is small, the number of game balls circulating in the game ball supply device 1 may increase and become excessive. As a countermeasure against this, the upper basket 35 is provided with an overflow chute 50 that guides excess game balls moving on the upper basket 35 to the lower tank 2.

  The overflow chute 50 will be described below with reference to FIGS. 9 and 11 to 13. 11 is a perspective view of the overflow chute 50 in the game ball supply device 1, FIG. 12 is a block diagram of a transport control device 55 that controls the operation of the transport belt 12, and FIG. 13 is a flow of control by the transport control device 55. It is a flowchart which shows.

  About one or two overflow chutes 50 are provided on the high side of the upper flange 35.

  The casing 43 of the overflow chute 50 is formed with an inlet 45 that communicates with an opening formed in the upright wall 16 b of the support 16 and receives a game ball from the upper basket 35.

  The game ball discharged from the outlet portion 42 of the overflow chute 50 is guided to the lower tank 2. The outlet portion 42 is provided with a sensor 51 (game ball detecting means) that detects a game ball passing therethrough.

  In the present embodiment, the game balls discharged from the outlet portion 42 of the overflow chute 50 are guided to the lower tank 2 in which the collection basket has a storage function, but are guided to the collection basket having no storage function. You may be allowed to be. In addition, the game balls discharged from the gaming machine are discharged to a collection basket that does not have a storage function, guided to the lifting device 3 through the collection basket, while the game balls discharged from the outlet portion 42 of the overflow chute 50 are Alternatively, the tank may be led to a tank that does not have the function of a recovery tank. In addition, if it is a tank which does not have a function of a collection tank, it is not necessary to provide in the lower part of the game island 100, For example, you may provide in the circumference | surroundings of the lifting apparatus 3. FIG.

  Other configurations of the overflow chute 50 are the same as those of the replenishment chute 40, and the same reference numerals are given to the same configurations as the replenishment chute 40.

  When there are many operations of the gaming machines arranged on the game island 100, there are relatively few game balls circulating in the game ball supply device 1, and the replenishment rod 27 and the upper cage 35 are in a state where they are close to the low side. Moving. However, when the number of game machines operating is small, the number of game balls circulating in the game ball supply device 1 may increase and become excessive. In that case, the game balls in the replenishment basket 27 and the upper basket 35 are filled up to the high place side, and are led from the overflow chute 50 provided on the high place side of the upper bowl 35 to the lower tank 2.

A transport control device 55 is mounted on the game island 100, and the transport control device 55 operates the drive motor 13 that drives the transport belt 12 according to the number of game balls guided to the lower tank 2 through the overflow chute 50. Control. Next, the conveyance control device 55 will be described.

  As shown in FIG. 12, the transport control device 55 includes a state determination unit 56 that determines the excess degree in the upper rod 35 based on the signal output from the sensor 51, and the drive motor 13 based on the determination result of the state determination unit. Drive signal output means 57 for outputting a drive signal to control the rotational speed of the drive motor 13. The state determination unit 56 and the drive signal output unit 57 correspond to the control unit.

  Next, the flow of control by the transport control device 55 will be described with reference to FIG. FIG. 13A is a flowchart showing the flow of state determination processing by the state determination means 56, and FIG. 13B is a flowchart showing the flow of drive signal output processing by the drive signal output means 57.

  First, the flow of state determination processing by the state determination unit 56 will be described with reference to FIG.

  When the state determination process is started, the power is turned on in step 101, and the transport control device 55 is initialized in step 102.

  In step 103, the timer is turned on and elapsed time counting is started.

  In step 104, the previous data counted based on the detection result detected by the sensor 51 is cleared.

  In step 105, the number of game balls passing through the outlet portion 42 is counted based on the detection result detected by the sensor 51 provided at the outlet portion 42 of the overflow chute 50.

  In step 106, it is determined whether or not the elapsed time of the timer has reached a predetermined time. If it is determined that the predetermined time has not been reached, the counting of the number of game balls in step 105 is continued.

  If it is determined in step 106 that the elapsed time of the timer has reached the predetermined time, the process proceeds to step 107, and the counting of the number of game balls in step 105 is ended. According to the above procedure, the number of game balls that have passed through the outlet portion 42 of the overflow chute 50 within a predetermined time is counted.

  In step 108, the number of game balls counted in step 105 is compared with a predetermined reference value.

  In step 108, if the counted number of game balls is equal to or greater than the reference value, the process proceeds to step 109, where it is determined that the game balls in the upper basket 35 are in an overflow state, and the overflow state is set.

  If the counted number of game balls is less than the reference value in step 108, the process proceeds to step 110, where it is determined that the game balls in the upper basket 35 are not in an overflow state, and the overflow state is canceled. .

  Next, the flow of drive signal output processing by the drive signal output means 57 will be described with reference to FIG.

  When the drive signal output process is started, power is turned on in step 201.

  In step 202, it is determined whether or not the game ball in the upper basket 35 is in an overflow state. If an overflow state is set in step 109 in the state determination process by the state determination unit 56, the process proceeds to step 203 and a slow drive signal is output to the drive motor 13. Thereby, the rotational speed of the drive motor 13 is controlled to be low.

  Further, when it is set in step 110 in the state determination process by the state determination means 56 that the overflow state is cancelled, the process proceeds to step 204 and a normal drive signal is output to the drive motor 13. Thereby, the rotational speed of the drive motor 13 is controlled to a normal rotational speed.

  As described above, the rotational speed of the drive motor 13 is controlled by the excess degree of the game balls in the upper basket 35. That is, when the operating rate of the gaming machine on the gaming island 100 is high and the excess degree of the game balls in the upper basket 35 is not high, the rotation speed of the drive motor 13 is set to a normal rotation speed. On the other hand, when the operating rate of the gaming machines on the gaming island 100 is low and the excessive degree of gaming balls in the upper basket 35 is high, the rotational speed of the drive motor 13 is set low.

  Thus, since the rotational speed of the drive motor 13 is set according to the operating rate of the gaming machines on the gaming island 100, the useless operation of the gaming ball supply device 1 can be suppressed. That is, when the operating rate of the gaming machine on the game island 100 is low, the conveyor belt 12 is operated in the energy saving mode.

  According to the above embodiment, the following operational effects are obtained.

  Since the conveyor belt 12 is disposed horizontally in the longitudinal direction of the game island 100, a large installation space is not required in the height direction.

  Further, the game ball moving on the replenishing rod 27 moves in a loosely fitted state between the lower portion 12a of the conveying belt 12 and the flat plate portion 28a by the action of the magnetic body provided on the conveying belt 12, and the replenishing chute 40 Supplied to gaming machines and ball lending machines. As described above, the game ball moving on the replenishing basket 27 is transported without being pinched by the transport belt 12, so that the load applied to the drive motor 13 is suppressed and the cost is not increased.

  The game balls that have not been supplied from the supply basket 27 to the gaming machine and the ball lending machine are guided to the upper basket 35 through the end basket 30 and guided to the inlet 27a of the supply basket 27 by the movement of the upper part 12b. It is burned. In this way, the game balls that have not been supplied from the supply basket 27 to the gaming machine and the ball rental machine are guided to the inlet 27a of the supply basket 27 again without circulating through the game island 100. Therefore, useless circulation of game balls in the circulation device of the game island 100 does not occur, and the operating rate of the lifting device and the like is prevented from increasing, so that the running cost of the circulation device can be kept low.

  In addition, since the game ball moving on the upper basket 35 is supplied to the game machine and the ball rental machine through the auxiliary chute 41, the game ball can be stably supplied to the game machine and the ball rental machine.

  Further, since the conveyor belt 12, the replenishing rod 27, and the upper collar 35 are formed to be inclined in the lateral direction, it is not necessary to level the conveyor belt 12, the supplemental collar 27, and the upper collar 35 in the lateral direction. Further, the conveyor belt 12, the replenishing rod 27, and the upper rod 35 can be easily arranged.

  Further, since the replenishment chute 40 and the auxiliary chute 41 are provided on the low side of the replenishment rod 27 and the low side of the upper reed 35, respectively, the game balls moving on the replenishment reed 27 and the upper reed 35 are from the low side. It is distributed in the front-rear direction and supplied to gaming machines and ball lending machines arranged in a back-facing state. Therefore, it is possible to evenly distribute gaming balls to gaming machines and ball lending machines arranged in a back-facing state.

  Further, in the replenishment rod 27, the game ball tends to flow into the replenishment chute 40 provided on the upstream side, and the game ball tends to hardly flow into the replenishment chute 40 provided on the downstream side. Similarly, in the upper basket 35, the game ball tends to easily flow into the auxiliary chute 41 provided on the upstream side, and the game ball tends to hardly flow into the auxiliary chute 41 provided on the downstream side. Since the supply rod 27 and the upper rod 35 are opposite to each other upstream and downstream, the game ball from the auxiliary chute 41 hardly flows into the upstream supply chute 40 that easily flows into the supply rod 27. The game balls from the auxiliary chute 41 easily flow into the supply chute 40 on the downstream side that is difficult to flow in. Therefore, the game balls are evenly distributed to the supply chute 40 arranged in the longitudinal direction.

  Further, when the game balls moving on the upper basket 35 are led to the lower tank 2 through the overflow chute 50, the excess degree of the game balls on the upper basket 35 is determined according to the number of overflowed game balls, Since the rotational speed of the drive motor 13 is controlled based on the determination result, the rotational speed of the drive motor 13 can be set according to the operating rate of the gaming machine on the gaming island 100. Therefore, since the useless operation of the game ball supply device 1 can be suppressed, the running cost of the game ball supply device 1 can be suppressed low.

  Next, another form of the present embodiment, specifically, another form of speed giving means for giving a speed to the game ball moving the supply basket 27 will be described.

  (1) Instead of providing a magnetic body on the conveyor belt 12, as shown in FIG. 14, a protruding wall 60 erected on the belt surface of the conveyor belt 12 in the belt transverse direction is spaced at a predetermined interval in the belt longitudinal direction. You may make it open and provide.

  The height of the protruding wall 60 is formed to be about 2 mm, and the predetermined interval between the adjacent protruding walls 60 is formed for several game balls, specifically, for about 4 or 5 game balls.

  By providing the protruding wall 60 on the conveyor belt 12, the protruding wall 60 comes into contact with the upper part of the loosely-fitted game ball between the lower portion 12a and the flat plate portion 28a as the conveyor belt 12 circulates. As a result, a speed in the belt longitudinal direction is given to the game ball on the flat plate portion 28 a, and the game ball moves on the supply basket 27.

  As described above, the game ball moving on the replenishing basket 27 is transported without being pinched by the transport belt 12, so that the load applied to the drive motor 13 is suppressed and the cost is not increased.

  (2) Instead of providing a magnetic body on the conveyor belt 12, as shown in FIG. 15, a plurality of bowl-shaped hemispheres 61 protruding from the belt surface of the conveyor belt 12 may be formed. The radius of the hemisphere 61 is about 2 mm.

  As the arrangement of the hemispheres 61, it is desirable to arrange them in a staggered manner as shown in FIG. Specifically, the hemisphere 61 forms a hemisphere row arranged at a predetermined interval in the short direction, and the hemisphere row is adjacent to the hemisphere row at a predetermined interval in the longitudinal direction. Each hemisphere is arranged in a staggered pattern. The predetermined interval in the short direction of the hemisphere 61 and the predetermined interval in the longitudinal direction of the hemisphere row are formed to be about one or two game balls.

  By providing the hemispherical body 61 on the conveyor belt 12, the hemispherical body 61 comes into contact with the upper part of the loosely-fitted game ball between the lower portion 12a and the flat plate portion 28a as the conveyor belt 12 circulates. As a result, a speed in the belt longitudinal direction is given to the game ball on the flat plate portion 28 a, and the game ball moves on the supply basket 27.

  As described above, the game ball moving on the replenishing basket 27 is transported without being pinched by the transport belt 12, so that the load applied to the drive motor 13 is suppressed and the cost is not increased.

  Further, when a protrusion is provided on the conveyor belt 12, there is a possibility that a game ball may be clogged between the protrusion and the flat plate portion 28a in the vicinity of the inlet portion 27a of the replenishing rod 27. However, since the hemispheres 61 are arranged at intervals in the short direction, the game balls can escape into the gaps between the hemispheres 61 adjacent in the short direction, and the occurrence of clogging of the balls is prevented. Further, since the hemispheres of adjacent hemisphere rows are arranged in a zigzag pattern, the hemisphere 61 of the subsequent hemisphere row is in contact with the game balls that have escaped into the gap, and the longitudinal direction of the belt Speed is granted.

  The present invention is not limited to the above-described embodiment, and it is obvious that various modifications can be made within the scope of the technical idea.

  For example, in the above embodiment, among the game balls guided from the upper tank 4 to the supply basket 27, the game balls are not guided to the supply chute 40 provided in the supply basket 27 but supplied to the game machine and the ball lending machine. It was explained that the game balls that were not present were led from the end cage 30 to the upper cage 35 and circulated in the game ball supply device 1. However, the game balls that have not been guided to the supply chute 40 among the game balls that move on the supply basket 27 are dropped from the downstream end of the supply basket 27 to the lower tank 2 and circulated in the game island 100. May be.

  The game ball supply device of the present invention can be applied as a device for supplying game balls to game machines. Note that the gaming machine is not limited to the pachinko gaming machine as shown in the above embodiment, and for example, other pachinko gaming machines, arrange ball gaming machines, sparrow ball gaming machines, etc. are used. Applicable to all gaming machines.

It is a perspective view which shows the internal structure of amusement island. It is a perspective view of the upstream end in the game ball supply apparatus concerning an embodiment of the invention. It is a perspective view of the downstream end in the game ball supply apparatus which concerns on embodiment of this invention. It is a perspective view of the downstream end in the game ball supply apparatus which concerns on embodiment of this invention. It is a front view of the upstream end in the game ball supply apparatus which concerns on embodiment of this invention. It is longitudinal direction sectional drawing of the upstream end in the game ball supply apparatus which concerns on embodiment of this invention. It is longitudinal direction sectional drawing of the downstream end in the game ball supply apparatus which concerns on embodiment of this invention. FIG. 2 is a cross-sectional view in the short-side direction in the game ball supply device according to the embodiment of the present invention, and is a cross-sectional view of a portion provided with a supply chute and an auxiliary chute. FIG. 3 is a cross-sectional view in the short-side direction in the game ball supply device according to the embodiment of the present invention, and is a cross-sectional view of a portion where an overflow chute is provided. It is a perspective view of a supply chute and an auxiliary chute in a game ball supply device concerning an embodiment of the invention. It is a perspective view of the overflow chute in the game ball supply device concerning an embodiment of the invention. It is a block diagram of the conveyance control apparatus which controls operation | movement of a conveyance belt. It is a flowchart which shows the flow of control by a conveyance control apparatus. It is a perspective view which shows the other form of a speed provision means. It is a perspective view which shows the other form of a speed provision means.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Game ball supply apparatus 2 Lower tank 3 Lifting apparatus 4 Upper tank 10,11 Roller 12 Conveying belt 12a Lower part 12b Upper part 12c Upstream arc part 12d Downstream arc part 13 Drive motor 15 Support member 16 Support part 27 Supply rod 27a Inlet portion 28 Supply rod defining member 28a Flat plate portion 30 End portion rod 31 Curved member 35 Upper rod 40 Supply chute 40A, 40a Game machine supply chute 40B, 40b Ball lending machine supply chute 41 Auxiliary chute 42 Outlet portion 45 Inlet Part 47 leveling member 49 communication rod 50 overflow chute 51 sensor 55 transport control device 56 state determination means 57 drive signal output means 60 projecting wall 61 hemisphere 100 game island

Claims (6)

In a gaming ball supply device that is provided on a gaming island in which a plurality of gaming machines are arranged in the longitudinal direction and supplies gaming balls to each gaming machine,
Two rollers having a rotation axis arranged in the longitudinal direction of the game island at intervals and extending in the short direction of the game island;
An endless conveyor belt wound around the two rollers;
A drive source for rotationally driving one of the rollers and rotating the conveyor belt;
A replenishment rod having a flat plate portion provided at an interval directly below the transport belt, and in which a game ball moves in a loosely fitted state between the flat plate portion and the transport belt;
A plurality of replenishment chutes that are provided along the longitudinal direction of the replenishment cage and guide the game balls that move the replenishment cage to each gaming machine;
Speed imparting means provided on the transport belt, for imparting speed to the loosely-fitted game balls as the transport belt circulates;
Equipped with a,
The conveyor belt is disposed at a predetermined inclination angle in the lateral direction,
The replenishment trough is disposed inclined at the same inclination angle as the conveyor belt,
The replenishment chute is provided on the lower side of the replenishment trough,
In the gaming island, gaming machines are arranged in a back-facing state in the short direction,
The supply chute is
A first supply chute for supplying a game ball moving on the flat plate portion to a gaming machine located on a lower side of the supply basket;
A second supply chute for supplying a game ball moving on the flat plate portion to a gaming machine located on the high side of the supply basket;
Game ball supply device, characterized in that it comprises a. 2. The game ball supply device according to claim 1, wherein the replenishment basket is formed such that a lower side inclination angle of the flat plate portion is larger than that of a higher side. The speed applying means is a magnetic body provided on a belt surface of the conveyor belt,
3. The game according to claim 1, wherein the game ball of the replenishment basket receives the action of the magnetic body and moves on the flat plate portion as the conveyor belt circulates. Ball feeder. The speed applying means is a protruding wall that is formed to stand in the belt short direction and is arranged at a predetermined interval in the belt longitudinal direction,
3. The game ball according to claim 1, wherein the game ball of the replenishment basket moves on the flat plate portion with the protruding wall abutting as the conveyor belt circulates. Feeding device. The speed applying means is a plurality of hemispheres provided to project from the belt surface of the conveyor belt,
3. The game ball according to claim 1, wherein the game ball of the replenishing bowl moves on the flat plate portion with the hemisphere abutting as the conveyor belt circulates. Feeding device. The game ball supply device according to claim 5, wherein the hemispheres are arranged in a staggered pattern.

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