JP4045603B2 - Pachinko island stand - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is to collect a used ball discharged from a plurality of pachinko machines arranged in a row and a return ball returned from a ball return device that returns a pachinko ball acquired by a player, a collection basket, a storage tank, a ball lifting The present invention relates to a pachinko island base that is configured to circulate through an apparatus, an upper tank, and a replenishment tub, and is configured to return a ball overflowing from the upper tank to the storage tank.
[0002]
[Prior art]
In recent years, pachinko island platforms in the form of returning prize balls acquired by players to a ball returning device attached to the island edge or the center of the pachinko island platform are being offered to the market. Of these, in particular, when a ball return device is provided on the island edge, for example, as shown in Japanese Utility Model Nos. 5-11896 and 6-32687, the return balls returned from the ball return device are A large tank that is temporarily stored in a small tank that communicates with the ball return device, and then the ball in the small tank is transported to an outrail (also called a recovery rod) by a small lift device and is placed in the center of the island. It was supposed to be supplied to the storage tank.
[0003]
[Problems to be solved by the invention]
However, as described above, in the type in which all the returned balls returned from the ball return device are once stored in the small tank and then supplied to the storage tank via the small lift and the outrail, the small lift is lifted. Because the capacity is extremely small, when a large amount of prizes is returned in a short time, the small tank becomes full and the prize return device is returned to the ball return device in the middle of the return of the prize When the amount of pachinko balls used in the pachinko machine suddenly increases when there is a situation where the return operation cannot be performed, or when the amount of storage in the large storage tank is small, the return is caused by the shortage of the lift capacity of the small lift. Despite the presence of balls, there were situations where the replenishment operation was not in time. The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a pachinko island stand in which a ball return operation and a ball replenishment circulation operation are smoothly performed.
[0004]
[Means for Solving the Problems]
In order to achieve the above-described object, an example of a solution adopted by the present invention will be described with reference to the drawings. Used balls discharged from a plurality of pachinko machines 2 arranged and pachinko balls acquired by a player The return balls returned from the ball return device 4 are used in a circulating manner via the collection baskets 34, 30, the storage tanks 18, 19, the ball lifting device 10, the upper tank 12, and the supply basket 13, and the upper part. In the pachinko island platform 1 configured with a return passage for returning the balls overflowing from the tank 12 to the storage tanks 18 and 19, the pachinko island platform 1 is filled with the stored amount of the storage tanks 18 and 19. A full sensor 20 for detecting that it has reached, an auxiliary tank 31 provided at the lower part of the upstream side of the recovery tanks 34, 30, and an upstream of the recovery tank 34 corresponding to the upper part of the downstream end of the auxiliary tank 31. A stopper device 62 or to flow down toward the downstream side by opening Dropping by preventing falling of the return ball into the auxiliary tank 31 flowing down from, A small reduction machine 50 that lifts the balls stored in the auxiliary tank 31 to the collection basket 30; When the full sensor 20 does not detect that the storage tanks 18 and 19 are full, the stopper device 62 guides downstream without preventing the return ball from flowing down, while the full sensor 20 When it is detected that the storage tanks 18 and 19 are full, the stopper device 62 prevents the return balls from flowing down and drops them into the auxiliary tank 31. Further, the operation of the full sensor 20 is interlocked with the driving of the small reduction machine 50, and the used balls and return balls flowing down the collection basket 30 are more than the balls stored in the storage tanks 18, 19. Preferentially guided to the ball lifting device 10 Thus, the balls returned from the ball return device 4 are preferentially guided to the storage tank 18 via the recovery baskets 34 and 30, and the storage tanks 18 and 19 are not filled until the auxiliary tank 31 is filled. Since the balls are not stored, even if the returned balls are concentrated in a short period of time, the return operation will not be interrupted, and the situation where the returned balls are not in time for the supply circulation operation can be avoided. The return tank 4 returned from the return device 4 can be reliably distributed between the auxiliary tank 31 and the storage tanks 18 and 19.
[0005]
Also ,small It is advantageous in that the drive of the mold reduction machine 50 can be used efficiently and used balls and return balls that have not been polished can be preferentially polished.
[0006]
In addition, the recovery rod 34 has a U-shaped cross-section with an open top and is inclined to the center of the upper portion of the auxiliary tank 31 and falls at a bent portion between the bottom surface and the side wall at an appropriate interval. A mouth 35 is formed, and used balls and return balls that have accumulated on the recovery rod 34 due to the blocking state of the stopper device 62 fall on the drop port 35 and are stored in the auxiliary tank 31. The balls can be uniformly guided from the collection basket 34 to the auxiliary tank 31.
[0007]
Further, the ball lifted by the small reduction machine 50 is formed with a drop port 35 of the recovery basket 34 through a ball discharge space 60 communicating with the recovery basket 30 on the downstream side of the stopper device 62. It is possible to move the balls lifted by the small reduction machine 50 to the collection basket 30 without obstructing the flow of the balls flowing down on the collection basket 30 by being discharged downstream from the existing position. Is advantageous.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. First, the structure of the pachinko island platform 1 according to the embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a perspective view showing an arrangement state of a plurality of pachinko island platforms 1, and FIG. 2 is a partially broken front view showing an internal structure of one pachinko island platform 1. In the figure, the pachinko island stand 1 has a large number of pachinko machines 2 arranged in a back-facing manner, as is well known. The rental machine 3 is sandwiched. Further, in the center of the pachinko island stand 1, a ball feeding device storage box 9 in which a ball lifting device 10 described later is stored is erected. In addition, a ball return device 4 is provided at one end of the pachinko island stand 1 to issue a receipt that numerically records the number of returned balls when the prize balls acquired by the player are returned. Further, the ball return device 4 is provided with a return blocking member 5 that is driven based on detection outputs from upper limit sensors 33a and 33b in an auxiliary tank 31 described later. The return blocking member 5 displays that the return of further balls is stopped when the amount of balls stored in the auxiliary tank 31 reaches a full level. It should be noted that not only the return blocking member 5 but also the return port of the ball return device 4 may be completely closed.
[0009]
Further, in the appearance of the pachinko island stand 1, in addition to the above-described configuration, the storage tanks 18 and 19 and the upper part of the island end are based on detection signals from ball amount sensors 20 to 24, 32, 33a, and 33b described later. A ball amount indicator 7 for displaying the amount of balls stored in the auxiliary tank 31 and a transfer passage 8 which is communicated between the central portions between the pachinko island platforms 1 and exchanges balls with each other are provided. It has been.
[0010]
By the way, as shown in FIG. 2, a ball lifting device 10 that is always driven after power-on is provided in the center of the pachinko island platform 1 as described above. The ball lifting device 10 is configured to rotationally drive an endless transport belt by a lower drive pulley with a built-in motor, and the balls introduced from the introduction rod 11 by the frictional force of the transport belt are used for polishing cloth mounting doors (illustrated). No.), and is finally discharged into the upper tank 12 from the discharge port at the upper end. In addition to the present embodiment, the ball lifting device may be of a type in which the abrasive pellets and the ball are mixed while being mixed by a spiral or a type in which a bucket is fixed to a belt.
[0011]
Left and right replenishing rods 13 that are inclined downward toward both end portions of the pachinko island base 1 are connected to both ends of the upper tank 12, respectively. 2 and a ball separator (not shown) corresponding to the ball lending machine 3 is provided. As a result, the polished balls that have been lifted and polished by the ball lifting device 10 flow out from the both ends of the bottom surface of the upper tank 12 to the replenishing troughs 13, and then are placed on the upper back of each pachinko machine 2 by a ball separator. It is supplied to the well-known prize ball tank and ball lending machine 3 provided. The ball separator is provided with a counting device for counting the number of balls replenished as is well known, and a replenishing ball signal is sent from the counting device to a management computer (not shown) provided at the game hall. It is supposed to be sent.
[0012]
Further, the ball separator 13 a located at the uppermost part of the replenishing basket 13 is supplied with the balls taken in from the ball separator 13 a to the transfer driving device 14 through the supply pipe 15. The transfer driving device 14 has a predetermined frictional force with a ball inside a semicircular semicircular transfer pipe having one end connected to the lower end of the supply pipe 15 and the other end connected to the supply pipe 16. A rubber disk member (not shown) that abuts is provided, and the disk member is configured to be rotationally driven by a single-phase induction motor. The ball that has flowed down the supply pipe 15 is caused to friction between the disk member and the ball. The replenishment pipes 16 are lined up in a single line by force. A supply pipe 17 for supplying balls from other islands is provided in parallel with the supply pipe 16, and the transfer passage 8 is constituted by the supply pipe 16 and the reception pipe 17. Thus, the transfer drive device 14, the supply pipe 15, and the supply pipe 16 described above constitute transfer means. The front end of the receiving pipe 17 is opened toward the upper end of the upper tank 25 of the main storage tank 18 described later, and the front end of the replenishing pipe 16 is the receiving pipe 17 when viewed from the other island side.
[0013]
Incidentally, storage tanks 18 and 19 are provided at the lower part of the pachinko island stand 1 and on the left and right sides of the ball lifting device 10. Among the storage tanks 18 and 19, the storage tank 18 provided inside the island platform on the side where the ball return device 4 is provided constitutes a main storage tank 18 formed in a very large size, and the opposite side. The storage tank 19 constitutes a small subordinate storage tank 19. Specifically, the main storage tank 18 has a capacity capable of storing about 150 to 160,000 balls, and the secondary storage tank 19 has a capacity capable of storing about 2 to 30,000 balls. ing.
[0014]
Thus, the main storage tank 18 is formed with an upper rod 25 inclined downward toward the end of the pachinko island platform 1, and communicates with a collection rod 30 (to be described later) and stores the stored balls. An inclined bottom surface 26 that leads to the 10 introduction rods 11 is formed. A reflux pipe (not shown) that recirculates the balls that have been lifted by the ball lifting device 10 and stored in the upper tank 12 and overflowed from the upper tank 12 faces the upstream portion of the upper basket 25, The balls flowing down from the reflux pipe are guided to the upstream portion of the main storage tank 18. In addition, the inclined bottom surface 26 communicates with the recovery rod 30, but the balls that flow down the recovery rod 30 and enter the main storage tank 18 are guided on the inclined bottom surface 26 of the main storage tank 18. It is guided by a cylinder (not shown) and preferentially guided to the introduction rod 11. Therefore, the balls stored in the storage space of the main storage tank 18 do not store the balls returned from the ball return device 4 as they are, and the returned balls 10 have a very large lifting capacity. The balls immediately transferred to the upper tank 12 and discharged from the upper tank 12 through the return pipe to the upper basket 25 are stored in order from the upstream side, and the storage space is filled with balls. When it becomes, the ball also accumulates in the upper basket 25. When the balls are stored on the upper basket 25, the balls are guided and stored in the sub-storage tank 19 through an overflow basket (not shown). Note that the balls that roll on the upper rod 25 of the main storage tank 18 do not necessarily fall to the inclined bottom surface 26 after reaching the end, but some balls are inclined before reaching the end. Although it falls to the bottom surface 26, most of them fall from the end of the upper ridge 25 onto the inclined bottom surface 26.
[0015]
On the other hand, the secondary storage tank 19 also has an inclined bottom surface 27 that communicates with the recovery rod 29, and a communication rod 28 that communicates with the inclined bottom surface 27 communicates immediately before the portion of the main storage tank 18 to which the introduction rod 11 is connected. It is supposed to be. Also in the secondary storage tank 19, the balls flowing down the recovery basket 29 are preferentially guided to the contact rod 28, and the balls overflowing and stored from the main storage tank 18 are non-prioritized to the contact rod 28. It has a structure.
[0016]
In the above-described main storage tank 18 and sub-storage tank 19, ball amount sensors 20 to 24 for detecting the amount of stored balls (hereinafter, 20 is S1, 21 is S2, 22 is S3, 23 is S4, and 24 is S5. The storage state of the balls is stored in order from the upstream side to the downstream side of the main storage tank 18 as described above, and finally stored in the secondary storage tank 19. Therefore, the ball amount sensor S5 constitutes a lower limit sensor that detects a case where the amount of storage is the smallest, the ball amount sensor S4 constitutes a lower limit release sensor that is higher than the lower limit, and further the ball amount sensor S1. Constitutes a full sensor for detecting that the storage amount of the storage tanks 18, 19 is full. And these ball amount sensors S1-S5 detect the amount of stored balls of the pachinko island stand 1 with ball amount sensors S7-S9 which will be described later, and the amount of balls by the respective operations of the ball amount sensors S1-S9. The indicator 7 is sequentially turned on to notify the amount of stored balls.
[0017]
In the present embodiment, in addition to the main storage tank 18 and the secondary storage tank 19 described above, an auxiliary tank is located on one side of the main storage tank 18 below the pachinko island base 1 and adjacent to the ball return device 4. 31 is provided. The auxiliary tank 31 stores more balls when the storage tanks 18 and 19 are full of stored balls. The detailed structure of the auxiliary tank 31 will be described with reference to FIGS. . FIG. 3 is a perspective view showing the relationship between the storage tanks 18 and 19, the auxiliary tank 31, the ball returning device 4 and the ball lifting device 10, and FIG. 4 is a perspective view showing the structure of the auxiliary tank 31.
[0018]
In the figure, the auxiliary tank 31 is formed in a rectangular parallelepiped shape having an open upper surface, and its bottom plate 37 is inclined downwardly from the front, and a predetermined amount (eg, 100,000 pieces) of balls above the bottom plate 37. The storage space 36 that stores the water is configured. The auxiliary tank 31 has an upper recovery rod 34 whose upper side is connected to a connection rod 42 that guides the balls returned to the ball return device 4 and whose downstream side is connected to the recovery rod 30. Has been handed over. The upper recovery bowl 34 is formed in a U-shape with the upper part opened, and a drop opening 35 is formed at an appropriate interval at the bent part between the bottom surface and the side wall. In the normal state in which the balls are flowing down vigorously from the drop port 35, the balls hardly fall into the storage space 36, but in the staying state where the balls are retained in the upper collection basket 34 by the stopper device 62 described later. It falls into the storage space 36. Further, in the middle of the downstream end of the storage space 36, a pressure release plate 39 that is inclined downward toward the front is provided, and balls stored in the bottom plate below the pressure release plate 39 are stored in the auxiliary tank 31. A guide plate 40 that guides to an outlet 41 formed on one side of the front wall is provided. Further, on one side of the bottom plate 37, a guide cylinder 38 that preferentially guides balls stored on the upstream side to the outlet 41 is laid.
[0019]
In the auxiliary tank 31 configured as described above, the balls that have fallen from the drop port 35 of the upper recovery rod 34 are stored in the storage space 36, and the stored balls roll on the bottom plate 37. It is guided to the outlet 41 by the guide plate 40 and guided to the small reduction machine 50 provided corresponding to the outlet 41. In addition, when the amount of storage in the storage space 36 is extremely large, a press-out plate 39 provided to weaken the ball pressure at the outlet 41 portion acts to guarantee a smooth flow, and to the upstream side The stored balls are preferentially guided to the exit 41 portion via the guide tube 38 so that the balls do not stay for a long time. Then, in order to detect the storage amount in the auxiliary tank 31, as shown in FIG. 2, a ball amount sensor 32 (hereinafter sometimes referred to as S7) is provided in a slightly upstream lower portion of the outlet 41, The ball amount sensors 33a and 33b (hereinafter sometimes referred to as S8 and S9) are provided at a substantially horizontal position slightly below the upper collection basket 34. Among these, the sensor S7 is provided to control the driving of the small reduction machine 50 described below, and the sensors S8 and S9 are that the amount of balls stored in the pachinko island platform 1 has reached the upper limit. The upper limit sensor is detected, and the driving of the ball amount indicator 7 and the return blocking member 5 of the ball returning device 4 and the driving of the transfer driving device 14 are controlled by the detecting operation.
[0020]
The total storage amount of the auxiliary tank 31 and the storage tanks 18 and 19 is about 300,000. This is a sufficient amount of balls for smooth business in the normal pachinko island 1 but the amount of storage in the sub-storage tank 19 is small (this is because the introduction rod 11 of the ball lifting device 10 is one main storage). Despite the fact that the ball amount can be obtained only from the tank 18), the auxiliary tank 31 is provided inside the pachinko island platform 1, not below the ball return device 4. is there.
[0021]
Next, the small reduction machine 50 and the stopper device 62 provided adjacent to the auxiliary tank 31 will be described with reference to FIGS. FIG. 5 is a perspective view of the small reduction machine 50, FIG. 6 is a perspective view of the stopper device 62, and FIG. 7 is a side view showing the operation of the stopper device 62.
[0022]
In the drawing, the small reduction machine 50 is configured by a conveying path standing vertically on the upper part of a substrate 51. The conveying path is configured so that the balls introduced from the introduction rod 56 are lifted and discharged from the upper outlet 57 in the same manner as the ball lifting device 10 by turning the leather belt 55. Further, the V belt 54 is stretched between the motor 52 fixed to the side surface of the conveyance path and the pulley 53 fixed to the outer side of the roller shaft of the lower roller (not shown) around which the leather belt 55 rotates, and the rotation of the motor 52 is performed. The leather belt 55 is turned by force.
[0023]
The small reducing machine 50 configured as described above has its introduction rod 56 connected to the outlet 41 of the auxiliary tank 31 and its upper outlet 57 facing the ball discharge space 60 of the device box 58. The ball feeding capacity of the small reduction machine 50 is not so large as compared with the ball feeding device 10, and a large amount of balls cannot be fed in a short time.
[0024]
The device box 58 located above the small reduction machine 50 is provided with a stopper device 62 described below, and guides the pachinko balls lifted by the small reduction machine 50 to the collection basket 30. That is, a passage space 59 having the same width as the recovery rods 30 and 34 is formed at substantially the center of the device box 58, and the upper recovery rod 34 is inserted and supported from the upstream side of the passage space 59 to a substantially central portion. An upstream passage space 59a is formed, and a downstream side passage plate 59b communicates with the recovery rod 30 from a substantially central portion thereof. Therefore, the upper recovery rod 34 inserted into the upstream passage space 59a (in FIG. 4, the downstream end of the upper recovery rod 34 is not drawn through the front wall of the auxiliary tank 31, but actually penetrates). A stopper device 62 is attached to the downstream end portion. As shown in FIG. 6, the stopper device 62 includes a motor 63 that can rotate forward and backward, a rotating shaft 64 that is rotated by the motor 63, and a stopper piece 65 that is fixed to the rotating shaft 64. As shown in FIG. 7A, when the stopper piece 65 is positioned upward, the ball flowing down on the upper recovery rod 34 rolls downstream as it is, but the motor 63 rotates to stop the stopper piece. When the tip of 65 (tip portion has a waveform) abuts on the upper recovery rod 34, the ball flow down of the upper recovery rod 34 is blocked as shown in FIG. 7B. For this reason, as described above, the balls returned from the ball return device 4 stay on the upper collection basket 34 and fall into the storage space 36 of the auxiliary tank 31 from the dropping port 35, and the balls are stored in the auxiliary tank 31. .
[0025]
In addition to the above-described configuration, the device box 58 has a ball discharge space 60 formed outside the position where the motor 63 is disposed. The ball discharge space 60 is a space from which the balls lifted by the small reduction machine 50 are discharged and has a structure communicating with the downstream passage plate 59b. Therefore, the balls lifted by the small reduction machine 50 are discharged from the ball discharge space 60 to the collection basket 30 through the downstream passage plate 59b. The ball discharge space 60 is provided with a sensor 61 (hereinafter also referred to as S6) for detecting whether or not a ball clogging phenomenon has occurred. This sensor 61 is in a state where the ball discharge space 60 is clogged (when the ball discharge space 60 alone causes clogging, or when continuous clogging occurs from the recovery basket 30 and the downstream passage plate 59b, etc.) ), In order to prevent a failure of the small reduction machine 50 caused by further lifting the ball.
[0026]
As mentioned above, although the structure of the pachinko island stand 1 was demonstrated, the circulation operation | movement of the ball in this pachinko island stand 1 is demonstrated. First, the ball circulation operation when the storage amount of the storage tanks 18 and 19 is appropriate will be described. The balls lifted by the ball lifting device 10 are stored in the upper tank 12 and replenished from the upper tank 12. It is supplied to each pachinko machine 2 and ball lending machine 3 through the cage 13. In addition, the used balls used in the pachinko machine 2 are guided to the left and right collection baskets 29, 30, and 34, and are preferentially guided to the downstream side of the storage tanks 18 and 19, and are lifted by the ball lifting device 10 again. It circulates inside the pachinko island stand 1 by being sent. Further, when the balls that have been lifted and stored in the upper tank 12 overflow and flow through the reflux pipe, they are discharged to the upper tub 25 of the main storage tank 18 and sequentially stored from the upstream side of the main storage tank 18. It is like that. On the other hand, when the prize balls acquired by the player are returned to the ball return device 4, the return balls are guided to the main storage tank 18 via the connection rod 42, the upper recovery rod 34, and the recovery rod 30, and further, The guide cylinder (not shown) provided in the storage tank 18 is preferentially guided to the introduction rod 11 portion of the ball lifting device 10 and immediately transported, and thereafter performs the above-described circulation operation. Therefore, even if the return operation to the ball return device 4 is concentrated in a short time, the return balls are immediately guided to the ball lifting device 10 having a high lifting capacity, so that the ball return device 4 as in the past. It will not be unusable during the return of the ball.
[0027]
By the way, the storage amount of the balls used in the pachinko island stand 1 is not always constant. In other words, when a player puts a prize ball acquired in another pachinko island stand 1 into the ball return device 4 of the pachinko island stand 1 or a player receives a prize ball obtained in the pachinko island stand 1 There is a case where the ball is returned to the ball return device 4 of the table 1. For this reason, when the storage amount of the balls that are circulated and used inside the pachinko island platform 1 increases, as a worst case, the ball return device 4 causes a backflow phenomenon of the balls or the ball lifting device 10. Will fail and will not be able to operate. On the other hand, when the amount of balls that are circulated and used inside the pachinko island platform 1 decreases, as a worst case, normal payout balls cannot be paid out from the pachinko machine 2.
[0028]
Therefore, a structure for avoiding the above-described inconvenience is employed in the pachinko island platform 1 of the present embodiment. First, when the storage amount decreases, only the balls returned from the ball return device 4 increase the storage amount. As described above, the return balls returned from the ball return device 4 are the main ones. Since it is led directly to the storage tank 18, at least the amount of balls returned can be made in time for the replenishment circulation operation. However, since this point is based on the premise that the ball is returned from the ball return device 4, if there is no ball returned from the ball return device 4, this is not a fundamental solution but is solved. For this reason, in this embodiment, in order to equalize the amount of stored balls between the islands, a transfer means having the transfer passage 8 as a constituent element is provided. This will be described in detail later.
[0029]
Next, an operation when the amount of storage in the pachinko island platform 1 starts to increase will be described with reference to FIGS. First, when the main storage tank 18 is full and balls are also stored in the sub-storage tank 19, and finally the full sensor S1 is turned on, the stopper piece 65 of the stopper device 62 is closed as shown in the flowchart of FIG. The ball that flows down on the upper recovery rod 34 is blocked (step 11). As a result, the balls returned from the ball return device 4 fall from the drop opening 35 and are stored in the auxiliary tank 31. When the full sensor S1 is not ON, the stopper piece 65 is in an open state to allow the return balls to be stored in the storage tanks 18 and 19 (step 12). In this way, by linking the driving of the stopper device 62 with the full sensor S1 of the storage tanks 18 and 19, the distribution of the auxiliary tank 31 of the return balls returned from the ball return device 4 and the storage tanks 18 and 19 is ensured. It is advantageous in that it can be performed.
[0030]
When the balls are stored in the auxiliary tank 31 as described above, when the full state of the storage tanks 18 and 19 is resolved, the small reduction machine 50 is driven. The driving is shown in FIG. This is done as shown in the flow diagram. That is, when it is determined at step 20 that the full sensor S1 is OFF (when it is determined that the storage tanks 18 and 19 are not full), when it is determined at step 21 that the ball quantity sensor S7 is ON. (When it is determined that there is a storage ball in the auxiliary tank 31) and when the sensor S6 is not ON in Step 22 (when it is determined that no clogging or the like has occurred in the ball discharge space 60). In step 23, the small reduction machine 50 (displayed as a mini reduction machine) is driven, and when the sensor S1 is ON, the sensor S7 is OFF, and the sensor S6 is ON, the small reduction machine 50 is not driven. In this way, the full sensor S1 that detects the storage state of the storage tanks 18 and 19 and the driving of the small reducing machine 50 are linked, which is advantageous in that the driving of the small reducing machine 50 can be used efficiently.
[0031]
Further, when the amount of balls returned from the ball return device 4 increases and the storage amount in the auxiliary tank 31 gradually increases, and finally the upper limit sensors S8 and S9 are turned ON, as shown in FIG. If it is determined that the return blocking member 5 is driven in step 32 and the ball return device 4 cannot be used (displayed as “counter stopped”), and if it is determined that both are not ON, the ball is returned in step 31. The device is ready for use. The reason why the upper limit is determined by the two sensors S8 and S9 is that there is a possibility that the storage state of the ball in the auxiliary tank 31 is stored like a wave, so that the full state is determined. However, the ball return device 4 may not be used when one of the two sensors is turned on. Further, it is not always necessary to provide two upper limit sensors S8 and S9, and any one of them may be used.
[0032]
As described above, when the auxiliary tank 31 is also filled with the storage balls, the ball return device 4 cannot be used, and such a state continues until the storage amount of the pachinko island stand 1 naturally decreases. In some cases, the ball return device 4 cannot be used for a long time. In order to avoid such an inconvenience, in the present embodiment, the pachinko island platform 1 has a transfer path 8 and a transfer drive device 14 for conveying balls between the island platforms arranged in a row, and the tanks 18 and 19. And the sensors 20 (S1), 23 (S4), 24 (S5), 33a (S8), and 33b (S9) for detecting the amount of balls stored in the auxiliary tank 31 to store the balls between the islands. The amount is equalized.
[0033]
Next, the transfer operation of the amount of accumulated balls between the islands by the transfer drive device 14 and the sensors 20, 23, 24, 33a and 33b will be described with reference to the flowcharts of FIGS. First, in FIG. 11, it is determined whether or not both the upper limit sensors S8 and S9 of the own island are ON in step 40. If it is determined that they are ON, the ball return device 4 (counter) is determined in step 41. ) Is displayed to indicate that it cannot be returned and the replenishment flag is turned ON in step 42. Thereafter, in step 43, a replenishing device control processing subroutine is executed.
[0034]
As shown in FIG. 12A, this replenishment device control process is performed while judging whether the adjacent left and right pachinko islands have reached the upper limit. That is, it is determined in step 60 whether or not the replenishment flag is ON on the left island. If it is ON, it means that the left island has reached the upper limit, and in step 61, the ball is replenished to the left island. The driving of the transfer driving device 14 (displayed as a replenishing device; hereinafter the same) is stopped, and if the left island replenishment flag is not ON, the driving of the transfer driving device 14 that replenishes the left island is started in step 62. . Similarly, in step 63, it is determined whether or not the replenishment flag is ON on the right island, and if it is ON, it means that the right island has reached the upper limit. When the right island replenishment flag is not ON, the drive of the transfer drive device 14 for replenishing balls to the right island is started in step 65.
[0035]
Thus, while the replenishing device control process in step 43 is being executed, it is determined in step 44 whether one of the upper limit sensors S8, S9 has been turned off. Step 42 to 44 are repeated, and when it is determined that one of the upper limit sensors S8 and S9 is OFF, a timer for a certain time (in this embodiment, 10 minutes) is set in Step 45, It is determined in step 46 whether or not the time set by the timer (10 minutes) has elapsed. After 10 minutes have elapsed, the replenishment flag is turned OFF in step 47, and the ball return device 4 is returned in step 48. In step 49, the transfer drive device 14 in the own island is stopped, and the process when the storage amount reaches the upper limit is ended.
[0036]
The transfer driving device 14 is driven for a predetermined time from when the detection outputs from the upper limit sensors S8 and S9 are not derived by the operation realized by the processing of the steps 40 to 49 described above. Since the storage amount at the end of the operation of the drive device 14 can be surely positioned below the upper limit sensors S8, S9, there is some time margin before the upper limit sensors S8, S9 are activated again. Therefore, for example, the return blocking member 5 of the ball return device 4 does not jump out at a short time interval, and the player can smoothly return the prize balls, thereby improving the service. The unusable state of the ball return device 4 does not continue for a long time. Further, if the set time of the timer for measuring a certain time can be changed and adjusted, the remaining storage amount below the upper limit sensors S8 and S9 can be set to a desired amount.
[0037]
On the other hand, when the storage amount in the storage tanks 18 and 19 reaches the lower limit, that is, it is determined in step 10 that the upper limit sensors S8 and S9 are not turned ON, and in step 50 the lower limit sensor S5 is turned ON. When it is determined that there is, the receiving flag is first turned ON in step 51, and then a receiving device control processing subroutine is executed in step 52.
[0038]
As shown in FIG. 12B, this receiving device control process is performed while judging whether the adjacent left and right pachinko islands have reached the lower limit. That is, it is determined in step 70 whether or not the receipt flag is ON on the left island, and if it is ON, it means that the left island has also reached the lower limit. If the left island's receipt flag is not ON, the left island's transfer drive device 14 (shown as a receiving device; hereinafter the same) is stopped. Therefore, the drive of the left island transfer drive unit 14 is started. Similarly, in step 73, it is determined whether or not the receipt flag is ON in the right island. If it is ON, it means that the right island has also reached the lower limit. The right island transfer drive unit 14 is stopped to stop receiving, and if the right island receive flag is not ON, the right island transfer drive unit 14 receives the ball from the right island in step 75. Start driving.
[0039]
Thus, it is determined whether the lower limit release sensor S4 is turned on in step 53 while the receiving device control process is executed in step 52. If not, the process returns to step 51 and returns to step 51. When it is determined that the lower limit release sensor S4 is turned ON, the receipt flag is turned OFF in Step 54, and the transfer drive device 14 in the other island is stopped in Step 55, and the storage amount reaches the lower limit. When the process ends.
[0040]
By the operation realized by the processing of steps 50 to 55 described above, a predetermined amount of balls can be reliably stored, and the lower limit sensor S5 does not operate again after a short time interval.
[0041]
In the above-described embodiment, the transfer driving device 14 has been described in which balls are transferred to another island in a row, but balls may be transferred in a plurality of rows. In this case, for example, the ball take-in by the ball separator 13a may be made into a plurality of rows, and the transfer driving device 14 and the transfer passage 8 may be provided corresponding to each row.
[0042]
As mentioned above, although the structure and effect | action of the pachinko island stand 1 which concern on embodiment were demonstrated, in the said embodiment, although the thing of the form pumped up with the leather belt 55 as a small reduction machine 50 was shown, FIG.13 and FIG. As shown in FIG. 14, it may be a conveyor type lift device. Briefly describing the mini-conveyor device 70, which is a conveyor-type lift device, the mini-conveyor device 70 supports the transport path 72 on the substrate 80 in an inclined manner, and introduces a spear 71 on the lower side of the transport path 72. , And a discharge rod 73 is connected to the other side of the upper part. A conveyor belt 74 in which ball locking strips 75 are formed in parallel is provided in the conveyance path 72 so as to turn, and this turning drive is a pulley fixed to the output shaft of a motor 76 provided on the substrate 80. This is performed by a V-belt 78 that is stretched between 77 and a roller 79 that drives the conveyor belt 74. By placing the mini-conveyor device 70 configured as described above adjacent to the auxiliary tank 31, the balls stored in the auxiliary tank 31 can be smoothly transported onto the collection basket 30 as with the small reduction machine 50. .
[0043]
Further, by providing various decorative members in the transfer passage 8 shown in FIG. 1, the atmosphere of the game hall can be enhanced. For example, as shown in FIGS. 15 to 19, a plate display plate 92, an information display plate 93, and an information display 94 (indicating the model name on the side surface of the pipe storage rod 90 covering the supply pipe 16 and the receiving pipe 17 ( A pachinko machine that is in a special prize state, or a lightning display arch 95 that displays the number of a pachinko machine in a special prize state at the top of the pipe housing 90. What is necessary is just to provide the top lamp 96 which notifies a salesclerk that 2 exists in the said pachinko island stand 1. FIG. Of course, a decorative member other than the above can be attached. In addition, a dust collection collecting rod 91 that collects dust and dust falling from the supply pipe 16 and the receiving pipe 17 so as not to fall downward is attached to the lower portion of the pipe storage rod 91.
[0044]
【The invention's effect】
As described above, as is apparent from the above description, in the present invention, the returned balls returned from the ball return device that returns used balls discharged from a plurality of pachinko machines arranged in line and the pachinko balls acquired by the player. A pachinko island stand that is configured to circulate and use balls through a collection tank, a storage tank, a ball feeding device, an upper tank, and a replenishment tank, and to return a ball overflowing from the upper tank to the storage tank. In the pachinko island platform, a full sensor for detecting that the storage amount of the storage tank has reached a full level, an auxiliary tank provided at an upper lower portion of the recovery tank, and a downstream end of the auxiliary tank A stopper device that prevents the return ball flowing down from the upstream side onto the recovery tank corresponding to the upper part of the recovery tank and dropping it into the auxiliary tank or opening it to flow down toward the downstream side A small reduction machine that lifts the balls stored in the auxiliary tank to the recovery basket; When the full sensor does not detect that the storage tank is full, the stopper device guides downstream without preventing the return ball from flowing down, while the full sensor fills the storage tank. When detected, the stopper device prevents the return ball from flowing down and drops it into the auxiliary tank. Further, the operation of the full sensor is interlocked with the driving of the small reduction machine, and the used balls and return balls flowing down the collection basket are preferentially given up over the balls stored in the storage tank. Led to the feeder As a result, the balls returned from the ball return device are preferentially guided to the storage tank via the recovery basket, and the balls are not stored in the auxiliary tank until the storage tank is full. Even if the return balls are concentrated, the return operation will not be interrupted, and the situation where the return balls are not in time for the supply circulation operation can be avoided. The auxiliary tank and the storage tank can be reliably distributed.
[0045]
Also ,small It is advantageous in that the drive of the mold reduction machine can be used efficiently and the used balls and return balls that have not been polished can be preferentially polished.
[0046]
In addition, the recovery bowl has a U-shaped cross-section with an open top and is inclined to the center of the upper part of the auxiliary tank, and a drop opening is provided at an appropriate interval between the bent part of the bottom surface and the side wall. The used balls and return balls that have been formed and stay on the recovery basket due to the blocking state of the stopper device fall from the drop port and are stored in the auxiliary tank, so that the recovery tank can return to the auxiliary tank. The ball can be guided evenly.
[0047]
Further, the ball lifted by the small reduction machine is located downstream of the position where the recovery port is formed through a ball discharge space communicating with the recovery rod downstream of the stopper device. This is advantageous in that the movement of the ball lifted by the small reduction machine to the recovery rod can be performed without blocking the flow of the ball flowing down on the recovery rod.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an arrangement state of pachinko islands according to an embodiment.
FIG. 2 is a partially broken front view showing an internal structure of one pachinko island base.
FIG. 3 is a perspective view showing a relationship among a ball return device, an auxiliary tank, a storage tank, and a ball lifting device provided on a pachinko island stand.
FIG. 4 is a perspective view of an auxiliary tank.
FIG. 5 is a perspective view of a small reduction machine.
FIG. 6 is a perspective view of a stopper device.
FIG. 7 is a cross-sectional view showing the operation of the stopper device.
FIG. 8 is a flowchart showing control of the stopper device.
FIG. 9 is a flowchart showing control of a small reduction machine.
FIG. 10 is a flowchart showing control of the use state of the ball return device.
FIG. 11 is a flowchart showing a control operation of the transfer drive device.
12 is a detailed flowchart of the subroutine processing shown in FIG. 11. FIG.
FIG. 13 is a partially broken front view showing the internal structure of the pachinko island stand when the mini-conveyor device is used.
FIG. 14 is a perspective view of a mini conveyor device.
FIG. 15 is a front view showing various decorative members provided in the transfer passage.
FIG. 16 is a perspective view of a transfer passage provided with a decorative member.
FIG. 17 is an enlarged view of the right side portion of FIG. 15;
18 is an enlarged view of the left part of FIG.
FIG. 19 is an enlarged view of the central portion of FIG.
[Explanation of symbols]
1 Pachinko island stand
2 Pachinko machines
4 ball return device
5 Return blocking member
8 Transfer passage
10 Ball lifting device
13 Supply bowl
13a Ball separator
14 Transfer drive device
15 Supply pipe
16 Supply pipe
18 Main storage tank
19 Secondary storage tank
20 Ball sensor (full sensor)
23 Ball quantity sensor (Lower limit release sensor)
24 Ball quantity sensor (lower limit sensor)
30 Collection dredging
31 Auxiliary tank
33a, 33b Ball quantity sensor (upper limit sensor)
34 Upper recovery bowl
50 Small reduction machine
62 Stopper device

Claims (3)

The used balls discharged from a plurality of pachinko machines arranged in a row and the returned balls returned from the ball return device that returns the pachinko balls acquired by the player are collected into a collection tank, a storage tank, a ball lifting device, and an upper tank. In a pachinko island stand that is used for circulation through a replenishment trough and is configured to have a return passage for returning the balls overflowing from the upper tank to the storage tank,
Inside the pachinko island stand, a full sensor for detecting that the storage amount of the storage tank has reached a full level, an auxiliary tank provided at the lower upstream side of the recovery tank, and an upper part of the downstream end of the auxiliary tank A stopper device that prevents the return ball from flowing down from the upstream side onto the recovery tank corresponding to the above and drops it into the auxiliary tank or opens it to flow toward the downstream side, and is stored in the auxiliary tank. A small reduction machine that lifts the egg to the collection basket ,
When the full sensor does not detect that the storage tank is full, the stopper device guides downstream without preventing the return ball from flowing down, while the full sensor detects that the storage tank is full The stopper device prevents the return ball from flowing down and falls into the auxiliary tank ,
Further, the operation of the full sensor is linked with the driving of the small reduction machine, and the used balls and return balls that flow down the recovery basket are preferentially transported over the balls stored in the storage tank. pachinko Isle of Eternal Youth, wherein Rukoto directed to apparatus. The recovery rod has a U-shaped cross-section with an open top and is inclined to the center of the upper portion of the auxiliary tank, and a dropping port is formed at an appropriate interval between the bent portion of the bottom surface and the side wall. And
Wherein the recovered spent ball staying in the Higami and return ball by the blocking state of the stopper device, pachinko Isle of Eternal Youth of claim 1 Symbol mounting, characterized in that it is stored in the auxiliary tank to fall the chute. The ball lifted by the small reduction machine flows out downstream from the position where the recovery port is formed through a ball discharge space communicating with the recovery rod downstream from the stopper device. The pachinko island stand according to claim 1 or 2, wherein

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