JP4006767B2 - Pachinko island stand - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention is configured to circulate and use used balls discharged from a plurality of pachinko machines arranged in a line through a circulation path including a collection basket, a storage tank, a ball lifting device, and a supply basket. With, PlayThe present invention relates to a pachinko island stand provided with a ball return device for returning a pachinko ball acquired by an engineer.
[0002]
[Prior art]
  In recent years, pachinko island platforms in the form of returning premium balls acquired by players to a ball return device attached to the edge of the pachinko island or the center of the side are being offered to the market. Of these, in particular, when the ball return device is provided in the center of the side surface of the pachinko island stand, for example, as shown in JP-A-5-31249, the return ball returned from the ball return device is returned as a ball. Once stored in a storage tank that communicates with the device, the ball in the storage tank is then transported to a supply tank by a ball lifting device and supplied to an auxiliary tank disposed on the island edge portion. It was.
[0003]
[Problems to be solved by the invention]
  However, as described above, all the returned balls returned from the ball return device are temporarily stored in the storage tank and then supplied to the auxiliary tank via the ball lifting device and the replenishment basket. When a large amount of prize balls is returned in a short time, the lifting capacity of the ball lifting device cannot keep up with the return of the prize balls, and the storage tank becomes full despite the auxiliary tank having room. As a result, there is a problem that a state in which the return operation to the ball return device cannot be performed occurs during the return of the prize balls. The present invention has been made in view of the circumstances described above, and the object of the present invention is a pachinko island in which the ball return operation is smoothly performed in the pachinko island platform where the ball return device is provided at the center of the side surface. To provide a stand.
[0004]
[Means for Solving the Problems]
  In order to achieve the above object, an example of the solution adopted by the present invention will be described with reference to the drawings. As shown in FIG. 1, used balls discharged from a plurality of pachinko machines 2 arranged in a line. And is configured to be circulated through a circulation path composed of a recovery rod 26, storage tanks 14 and 15, a ball lifting device (not shown), and supply rods 7 and 8., PlayIn the pachinko island stand 1 provided with the ball return device 3 for returning the pachinko balls acquired by the technician, the amount of storage in the storage tanks 14 and 15 further exceeds a certain level inside the pachinko island stand 1. An auxiliary tank 27 that can store return balls returned from the ball return device 3, and provided from the upper part of the storage tank 15 to the auxiliary tank 27 and discharged from the back side of the ball return device 3 to the storage tank 15. The upper basket 17, 25, 38 for guiding the returned return balls to the auxiliary tank 27, and the return balls provided in the middle of the upper basket 25 and returned to the auxiliary tank 27 according to the storage amount of the storage tanks 14, 15 A shutter device 51 that can prevent or allow the inflow of water and a small reduction machine 32 that lifts pachinko balls stored in the auxiliary tank 27 to the circulation path. In its storage amount in the storage tank 14 and 15Less than the upper limitA ball sensor that detects when a certain amount has been reached.S4The ball amount sensorWhen it is detected that S4 has reached the predetermined amountThe shutter device 51Allows the inflow of the return ball and the pachinko ball is stored in the auxiliary tank 27.It is characterized by this.
[0005]
  With this configuration, the pachinko balls returned from the ball return device 3 are guided to the auxiliary tank 27 side via the upper rods 17 and 25, but a shutter device 51 is provided in the middle of the upper rod 25. The storage amount of the storage tanks 14 and 15 isLess than the upper limitConstantamountSince the return ball is prevented from flowing into the auxiliary tank 27 until the above is reached, the return ball is dropped into the storage tank 15. Therefore, the returned balls are stored in the storage tanks 14 and 15 with priority. And the storage amount of the storage tanks 14 and 15 isLess than the upper limitConstantamountIf it becomes above, the ball quantity sensor provided in the storage tank 15S4The shutter device 51 is driven to open in conjunction with this, and the return ball can flow down on the upper basket 25, so the return ball is stored in the auxiliary tank 27. further,The storage amount of the storage tank 15 is less than a certain amountThe amount stored in the auxiliary tank 27 isPredetermined amountWhen this is the case, the ball quantity sensor 31 provided in the auxiliary tank 27 is activated, and in conjunction with this, the small reduction machine 32 is driven efficiently without idling, and the return balls in the auxiliary tank 27 are transferred to the circulation path. Return to. That is, in the pachinko island stand 1 according to the present invention, the return balls returned from the ball return device 3 are first supplied to the storage tanks 14 and 15, and the storage amount of the storage tanks 14 and 15 becomes a certain amount or more. After that, since it is supplied directly to the auxiliary tank 27 without going through the ball lifting device (not shown), the auxiliary tank 27 can be used effectively regardless of the lifting capacity of the ball lifting device, Even if a large amount of free gift balls are returned in a short time, the balls can be returned smoothly..
[0006]
[0007]
DETAILED DESCRIPTION OF THE INVENTION
  Embodiments of the present invention will be described below 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 front view showing the internal structure of the pachinko island platform 1, and FIG. 2 is an enlarged front view showing the internal structure of the central portion of the pachinko island platform 1.
[0008]
  In the figure, as is well known, the pachinko island platform 1 has a large number of pachinko machines 2 arranged in a back-to-back arrangement, and each pachinko machine 2 has a one-to-one correspondence with the pachinko machine 2. A ball lending machine (not shown) is clamped. Further, in the center of the pachinko island stand 1, a ball lifting device (not shown) that is always driven after power-on is provided. This is to rotate the endless conveyor belt by a lower drive pulley with a built-in motor, and the ball introduced from the introduction rod 5 provided under the conveyor belt is brought into contact with the polishing cloth mounting door by the frictional force of the conveyor belt. It is raised while being discharged and finally discharged into the upper tank 6 from the discharge port at the upper end. Furthermore, when a prize ball obtained by the player is returned to one side of the central part of the pachinko island stand 1 (position adjacent to the ball feeding device), a receipt in which the number of returned balls is recorded is issued. A ball return device 3 is provided. The ball return device 3 is provided with a return prevention member 4 that is driven based on a detection output from a ball amount sensor 24 in a non-priority storage tank 15 described later. This indicates that when the amount of balls stored in the storage tanks 14 and 15 and the auxiliary tank 27 reaches full, the return of further balls is stopped. It should be noted that not only the return blocking member 4 but also the return port of the ball return device 3 may be completely closed.
[0009]
  Left and right supply rods 7 and 8 that are inclined downward toward both ends of the pachinko island base 1 are connected to both ends of the upper tank 6, respectively. A ball separator 33 corresponding to a rental machine (not shown) is provided. As a result, the polished balls that have been polished and pumped by the ball pumping device (not shown) are discharged from the both ends of the bottom surface of the upper tank 6 to the replenishing rods 7 and 8, and then each pachinko machine by the ball separator 33. 2 is supplied to a well-known prize ball tank (not shown) and a ball lending machine (not shown) provided on the upper rear surface of No. 2. As is well known, the ball separator 33 is provided with a counting device for counting the number of replenished balls, and the number of replenished balls is sent from this counting device to a management computer (not shown) provided at the game hall. A signal is sent.
[0010]
  Further, on the bottom surface of the upper tank 6, a drop opening (not shown) through which the ball flows out when the ball is full on the replenishing rods 7 and 8 is formed. The reflux passage body 10 is disposed. This reflux passage body 10 uses less prize balls in the pachinko machine 2 and eliminates the need for replenishment of balls to the replenishing rods 7 and 8, and as a result, when the stored balls in the upper tank 6 fall from the dropping port, surplus Are recirculated to the storage tanks 14 and 15 installed on both lower sides of the ball lifting device (not shown). Thus, the priority passage body 11 communicating with one storage tank 14 and the non-priority passage body 12 communicating with the other storage tank 15 are connected to the reflux passage body 10 in the illustrated embodiment. This is because surplus balls that have fallen into the reflux passage body 10 are preferentially guided to the priority passage body 11 and stored in one storage tank 14, and the storage tank 14 becomes full and the priority passage body 11 is also full. When it becomes, it can guide to the non-priority passage body 12 and can be stored in the other storage tank 15. That is, in the illustrated embodiment, the left storage tank 14 functions as a priority storage tank that preferentially stores balls, and the right storage tank 15 functions as a non-priority storage tank. When the priority passage body 11, the non-priority passage body 12, and the reflux passage body 10 are filled with balls, the portion has a capacity for storing about 20,000 balls. Further, an emergency stop sensor (not shown) is provided at the upstream position of the non-priority passage body 12, and when the ball is stored up to that position, the drive motor of the ball feeding device comes to an emergency stop. ing.
[0011]
  Further, the upper end of the reflux passage body 10 is connected to the upper end of the reflux pipe 13 facing below the dropping port (not shown). The recirculation pipe 13 accepts a hit ball falling from the dropping port and is led to the inclined bottom surface 19 slightly downstream of the non-priority storage tank 15. The priority of the flow of the ball into the reflux pipe 13 is the highest priority, and the hit ball that has fallen from the dropping port (not shown) is preferentially guided to the downstream side of the non-priority storage tank 15. It is burned. However, when balls are stored on the downstream side of the non-priority storage tank 15 and reach the outlet of the reflux pipe 13, more balls are not guided and stay in the reflux pipe 13, and the interior of the reflux pipe 13 is completely When the ball is filled with the ball, the ball that has fallen from the dropping port (not shown) to the reflux passage body 10 is guided to the priority passage body 11. In general, however, many stored balls remain on the priority storage tank 14 side, while there are many cases where no stored balls remain on the non-priority storage tank 15 side. There is a disadvantage that the supply of balls to 5 is different on the left and right, and the efficiency of lifting the balls is deteriorated. In order to eliminate such drawbacks, a part of the ball is preferentially guided to the non-priority storage tank 15 side via the reflux pipe 13, thereby affecting the introduction rod 5 of the ball lifting device (not shown). The balls are evenly supplied from the top to improve the efficiency of lifting the balls.
[0012]
  Further, in the above-described priority storage tank 14 and non-priority storage tank 15, 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, 24). May be expressed as S5), but the storage state of the balls is first stored in order from the upstream side to the downstream side of the priority storage tank 14, and then from the upstream side to the downstream side of the non-priority storage tank 15. Are stored in order. Therefore, the ball amount sensor S1 constitutes a lower limit sensor that detects a case where the amount of storage is the smallest, and the ball amount sensor S5 has an upper limit of the storage amount of the priority storage tank 14, the auxiliary tank 27, and the non-priority storage tank 15. This is an upper limit sensor for detecting the fact that the return operation of the ball return device 3 is prohibited. Further, the ball amount sensor S4 disposed upstream of the ball amount sensor S5 controls driving of the shutter device 51, and when the storage amount of the non-priority storage tank 15 reaches a state before reaching the upper limit. In addition, the balls that increase in return are led to the auxiliary tank 27 side. In FIG. 1, a ball amount sensor other than the ball amount sensor with a reference numeral is also drawn, but these ball amount sensors are used only for displaying the storage amount.
[0013]
  On the other hand, in addition to the priority storage tank 14 and the non-priority storage tank 15 described above, an auxiliary tank 27 is provided on one side of the non-priority storage tank 15. The auxiliary tank 27 can store the return balls returned from the ball return device 3 when the storage amounts of the priority storage tank 14 and the non-priority storage tank 15 exceed a certain level. The upper recovery rod 28 that collects used balls discharged from the out ball tank 9 formed in the lower part of each pachinko machine 2 and guides it to the non-priority storage tank 15 side is handed over in an inclined manner. . The upper recovery tank 28 is formed in a U-shape with the upper part open, and its downstream end is communicated with the non-priority storage tank 15 via the recovery tank 26. As is well known, the out ball tank 9 is provided with a counting device for counting the number of replenished balls, and a replenishing ball number signal is sent from this counting device to a management computer (not shown) provided in the game hall. Is to be sent. The auxiliary tank 27 is provided with a ball amount sensor 31 (hereinafter also referred to as S7) for detecting the amount of accumulated balls. This sensor S7 is provided for controlling the driving of the small reduction machine 32 (for preventing idling) described later.
[0014]
  Further, an upper shelf 46 is formed on the uppermost portion of the auxiliary tank 27 in order to further increase the storage amount of the auxiliary tank 27. The upper shelf 46 is attached so as to be inclined downward toward the island end of the pachinko island platform 1, and the upper space of the auxiliary tank 27 can be used as a ball storage space. Specifically, when the upper shelf ball separator 44 is attached in the middle of the replenishing rod 8 and the space below the upper rod 38 described later of the auxiliary tank 27 is filled with balls and cannot be stored, A ball is supplied to the upper shelf 46 through the hose 45. By comprising in this way, since a ball can be stored also in the space above the upper collar 38, the storage amount of the ball as the pachinko island stand 1 whole can further be increased.
[0015]
  As described above, a ball lending machine (not shown) is sandwiched between the pachinko machines 2 arranged on the back side of the pachinko island platform 1 so as to correspond to the pachinko machine 2 on a one-to-one basis. Yes. Therefore, when a player uses a ball lending machine, a coin or a prepaid card may be accidentally dropped inside the pachinko island platform 1. If these foreign substances enter the ball circulation path and damage the ball feeding device (not shown), for example, the balls will not be circulated and will interfere with business in the pachinko island 1. The configuration adopted by the present embodiment to prevent such a situation will be described below with reference to FIG. FIG. 3 is a partially broken perspective view showing a configuration for preventing foreign matter from entering the pachinko island platform 1.
[0016]
  In the figure, a counter stand 41 on which a prize ball box (not shown) or the like is placed is projected at the center of both sides of the pachinko island stand, and the lower part thereof is covered with a waist plate 42. An open gap 57 is formed between the counter tables 41 on both sides, and a circulation path for balls such as the priority storage tank 14, the non-priority storage tank 15, the auxiliary tank 27, and the like is formed in the lower portion of the gap 57 (not shown). Has been. The gap 57 is closed by the protective net 54 so that no foreign matter enters from the gap 57. Specifically, first, a key-like mounting bracket 55 is attached with screws 56 inside the counter tables 41 on both sides at an appropriate interval. Then, the protective net 54 is fitted from above the support 53 and locked to the mounting bracket 55, so that the protective net 54 is placed on the gap 57. With this configuration, the opened gap 57 is closed, so that even if a coin or the like is accidentally dropped into the gap 57, it is blocked by the protective net 54, and the circulation path of the balls such as the storage tanks 14 and 15 etc. Will not affect sales in Pachinko Island 1
[0017]
  Next, detailed structures of the priority storage tank 14, the non-priority storage tank 15, and the auxiliary tank 27 will be described with reference to FIGS. FIG. 4 is a perspective view showing the relationship among the non-priority storage tank 15, the auxiliary tank 27, and the ball return device 3, and FIG. 5 shows the operation of the non-priority storage tank 15, the auxiliary tank 27, and the ball return device 3. It is a top view.
[0018]
  In the figure, the priority storage tank 14 and the non-priority storage tank 15 are formed in a large rectangular parallelepiped shape whose upper surface is open, and each has a capacity capable of storing about 150 to 160,000 balls. The bottoms of the priority storage tank 14 and the non-priority storage tank 15 are formed as inclined bottom surfaces 18 and 19 that guide the stored balls to the introduction rod 5 of a ball lifting device (not shown), and are located in the middle of the downstream end. Are provided with pressure release plates 34 and 35 that are inclined downward toward the front, and balls stored in the inclined bottom surfaces 18 and 19 below the pressure release plates 34 and 35 are front walls of the non-priority storage tank 15. Guiding slats 36 and 37 for guiding to a ball outlet 52 provided on one side are provided. In addition, on the upper part of the priority storage tank 14 and the non-priority storage tank 15, there are provided upper rods 16 and 17 that are inclined downward from the front end toward the rear end. These upper rods 16 and 17 (shown only for one upper rod 17 in FIG. 4, but the other upper rod 16 also has the same structure) are formed by using a plate-like member whose center is opened as a priority storage tank 14 and a non-priority storage tank. 15 is attached to the inside of the upper portion, and the center of the front end thereof is a connecting plate 17a through which pachinko balls recirculated from the priority passage body 11 and the non-priority passage body 12 flow down. A triangular flow dividing plate 17b is projected from the lower center. For this reason, the pachinko balls recirculated from the priority passage body 11 and the non-priority passage body 12 are distributed to the left and right by the flow dividing plate 17b after being dropped on the connecting plate 17a, and are guided to the downstream side through the upper basket 17.
[0019]
  The above-described configuration is the same in the priority storage tank 14 and the non-priority storage tank 15, but the following configuration is added to the non-priority storage tank 15 side in addition to the above-described configuration. That is, as described above, the ball return device 3 is installed on the non-priority storage tank 15 side, so that the balls returned from the ball return device 3 are connected to the bottom of the back side of the ball return device 3 from the connecting rod 50. The ball is discharged to the upper basket 17 and guided downstream. When the ball returned from the ball return device 3 and the ball overflowed from the non-priority passage body 12 overlap, the ball from the non-priority passage body 12 In order to prevent this, the overflow holes 17c are protruded on the left and right sides of the connecting plate 17a. Further, in the non-priority storage tank 15, there is a ball outlet 40 that collects balls that have flowed down from the downstream end of the upper rod 17 at the center of the rear wall and guides the balls collected at the center to the outside of the non-priority storage tank 15. Is formed. The overflow hole 17 c and the ball outlet 40 described above do not exist in the priority storage tank 14. The above-described ball outlet 40 is connected to a connection upper rod 25 having a U-shaped cross section. The connection upper rod 25 is inclined between the ball outlet 40 and a ball inlet 43 opened on the upstream end surface of the auxiliary tank 27. In addition, a shutter device 51 described later is provided in the middle of the connection upper rod 25.
[0020]
  NonThe auxiliary tank 27 provided on one side of the priority storage tank 15 is formed in a large rectangular parallelepiped shape having an open upper surface, similar to the priority storage tank 14 and the non-priority storage tank 15, and an inclined bottom surface 29 is formed below the auxiliary tank 27. It is formed and can store a predetermined amount (for example, 100,000 balls) of balls. In addition, on the upper part of the auxiliary tank 27, an upper ridge 38 inclined downward toward the end of the pachinko island platform 1 is provided. The upper rod 38 has substantially the same structure as the upper rod 17, and is formed on the inner surface of the auxiliary tank 27. The upstream side communicates with the ball inlet 43, and the downstream side is auxiliary. It leads to the front of the downstream end face of the tank 27. Note that a triangular flow dividing plate 47 is attached to the U-shaped portion of the upper rod 38, and the ball that has flowed from the ball inlet 43 is divided into the inner sides of the auxiliary tank 27. It comes to lead to. Further, the height position of the upper rod 38 is provided at a relatively low position because it is provided in an inclined shape continuous from the upper rod 17 of the non-priority storage tank 15. For this reason, the upper space from the upper rod 38 is wasted, and in order to effectively use this idle space, balls are released and stored by the upper shelf ball separator 44, the hose 45, and the like. Yes.
[0021]
  The operation of the non-priority storage tank 15, the auxiliary tank 27, and the ball return device 3 configured as described above will be described below with reference to FIG. First, the balls returned from the ball return device 3 provided at the center of the side surface of the pachinko island stand 1 are discharged to the connecting rod 50 attached to the lower back of the ball return device 3. The balls discharged to the connecting rod 50 and the balls that have fallen through the non-priority passage body 12 roll on the upper rod 17 provided at the upper portion of the non-priority storage tank 15 and inclined downward toward the island end. Then, it is collected at the ball outlet 40 at its downstream end, and is discharged to the connection upper rod 25 connecting the ball outlet 40 on the non-priority storage tank 15 side and the ball inlet 43 on the auxiliary tank 27 side. Further, the ball that has flowed down on the connection upper rod 25 passes through the ball inlet 43 with the shutter device 51 retracted, and is provided at the upper portion of the auxiliary tank 27 and is inclined downward toward the island end. Led to. As described above, the balls introduced into the upper rod 38 are divided and guided to the inner sides of the auxiliary tank 27 by the flow dividing plate 47, and finally fall to the inclined bottom surface 29 formed at the lower portion of the auxiliary tank 27. Thus, it is stored in the auxiliary tank 27.
[0022]
  Next, the shutter device 51 provided in the middle of the connection upper rod 25 will be described with reference to FIGS. FIG. 6 is a side view of the shutter device 51, and FIG. 7 is a perspective view showing an attached state of the small reduction machine 32. In the figure, the shutter device 51 includes a motor 70 capable of rotating in the forward and reverse directions, a shutter plate 71 driven by the motor 70, and a shutter device support 72 that attaches the shutter device 51 to the back surface of the connection upper collar 25. Has been. Thus, when the shutter plate 71 is positioned below, the ball flowing down on the connection upper rod 25 rolls downstream as it is, but the motor 70 is driven and the shutter plate 71 jumps out on the connection upper rod 25. Sometimes, as shown in FIG. 6, the flow of balls on the connection upper rod 25 is blocked. For this reason, when the ball returned from the ball return device 3 and the overflow ball from the non-priority passage body 12 stay on the connection upper rod 25 and the ball is also filled on the upper rod 17 provided in the storage tank 15. The balls that are no longer retained on the upper basket 17 fall to the inclined bottom surface 19 of the non-priority storage tank 15 and are stored in the non-priority storage tank 15.
[0023]
  Next, a small reduction machine 32 that is provided adjacent to the auxiliary tank 27 and transports the balls stored in the auxiliary tank 27 to the collection basket 26 will be described with reference to FIGS. FIG. 8 is a perspective view showing the operation of the small reduction machine 32.
[0024]
  In the figure, a small reduction machine 32 is a conveyor type lift device, which supports a conveyance path 59 on a substrate 64 in an inclined manner, connects an introduction rod 58 on one lower side of the conveyance path 59, and other parts on the upper side. It is constituted by connecting a discharge rod 60 to the side. A conveyor belt 61 in which ball locking protrusions are formed in parallel is provided in the conveyance path 59 so as to turn, and this turning drive is performed by a pulley (which is fixed to an output shaft of a motor 62 provided on a substrate 64 ( This is performed by a V-belt 63 that is stretched between a roller (not shown) that drives the conveyor belt 61 (not shown).
[0025]
  The small reduction machine 32 configured as described above has its introduction rod 58 connected to the ball outlet 52 of the auxiliary tank 27 and its discharge rod 60 formed at the bottom of the box 65 that communicates with the recovery rod 26. It faces the passage plate 66, and the balls stored in the auxiliary tank 27 can be smoothly transported onto the collection basket 26. And the ball | bowl lifting capacity of the small reduction machine 32 is not so large, and a lot of balls | bowl cannot be pumped in a short time.
[0026]
  The configuration of the pachinko island stand 1 has been described above. Next, the ball circulation operation in the pachinko island stand 1 will be described. First, balls polished and lifted by a ball lifting device (not shown) are stored in the upper tank 6, and each pachinko machine 2 or ball lending machine (not shown) is supplied from the upper tank 6 via supply rods 7 and 8. ). In addition, the used balls used in the pachinko machine 2 are guided to the recovery basket 26 (the pachinko machine 2 at a position not corresponding to the priority storage tank 14 and the non-priority storage tank 15) or directly. 14. It is guided preferentially to the downstream side of the non-priority storage tank 15, and is circulated through the pachinko island platform 1 by being lifted again by a ball lifting device (not shown). In addition, when the balls that have been transported and stored in the upper tank 6 overflow and further flow out of the return pipe 13, they are discharged onto the inclined bottom surface 19 of the non-priority storage tank 15 and are non-priority storage tanks. 15 is stored. When it flows out to the reflux passage body 10, it is preferentially guided to the priority passage body 11 and stored in the priority storage tank 14, and then is guided to the non-priority passage body 12 and stored in the non-priority storage tank 15.
[0027]
  Next, the operation of the shutter device 51 and the small reduction machine 32 will be described with reference to FIGS. FIG. 9 is a flowchart showing control of the shutter device 51 and the small reduction machine 32, and FIGS. 10 and 11 are operation explanatory views of the shutter device 51 and the small reduction machine 32. FIG.
[0028]
  First, as shown in FIGS. 9 and 10, when the priority storage tank 14 is full and balls are stored in the non-priority storage tank 15, the amount of balls provided in the non-priority storage tank 15 in step 10. It is determined whether or not the sensor S4 is ON. If the sensor S4 is ON, the shutter plate 71 of the shutter device 51 provided in the middle of the connection upper rod 25 is opened in step 11, and the return ball and overflow are detected. The balls flow down on the connection upper rod 25 and are stored in the auxiliary tank 27. In this case, since a certain amount of balls is stored in the non-priority storage tank 15, the small reduction machine 32 (displayed as a mini lift) that lifts the balls in the auxiliary tank 27 to the non-priority storage tank 15 is not driven. (Step 12).
[0029]
  On the other hand, as shown in FIGS. 9 and 11, even when the priority storage tank 14 is full, the storage amount in the non-priority storage tank 15 does not reach a certain amount, and the ball amount sensor S4 is not ON. In step 13, the motor 70 of the shutter device 51 provided in the middle of the connection upper rod 25 is driven, the shutter plate 71 is closed, and the flow of balls on the connection upper rod 25 is blocked, and the return balls and The overflow ball falls to the inclined bottom surface 19 of the non-priority storage tank 15 and is stored in the non-priority storage tank 15. In this case, since there is room for storing balls in the non-priority storage tank 15, it is determined in step 14 whether or not the ball amount sensor S7 in the auxiliary tank 27 is ON. 15, the small reduction machine 32 is driven, and the balls in the auxiliary tank 27 are transported to the collection basket 26 and stored in the non-priority storage tank 15. On the other hand, when the storage amount in the auxiliary tank 27 is small and the ball amount sensor S7 is not ON, the small reduction machine 32 is not driven (step 16).
[0030]
  As described above, the driving of the shutter device 51 is interlocked with the ball amount sensor S4 of the non-priority storage tank 15, thereby preventing the return balls from flowing into the auxiliary tank 27 according to the storage amount of the non-priority storage tank 15. Or tolerate. Further, by driving the small reduction machine 32 in conjunction with the ball quantity sensor S4 of the non-priority storage tank 15 and the ball quantity sensor S7 of the auxiliary tank 27, the small reduction machine 32 can be driven efficiently without idling. . The small reduction machine 32 may be controlled only by the ball quantity sensor S4, or another sensor (for example, a sensor for detecting the quantity of the ball at the upper part of the small reduction machine 32) instead of S7, and S4, You may control by.
[0031]
  Next, the operation of the ball return device 3 (displayed as a counter) in the pachinko island stand 1 will be described with reference to FIGS. FIG. 12 is a flowchart showing the control of the use state of the ball return device 3, and FIGS. 13 and 14 are operation explanatory views of the ball return device 3.
[0032]
  First, as shown in FIGS. 12 and 13, when the amount of returned balls from the ball return device 3 increases and the amount of storage in the auxiliary tank 27 and the non-priority storage tank 15 becomes near full, non-priority in step 20. It is determined whether or not the ball quantity sensor S5 in the storage tank 15 is ON, and if it is ON, the return blocking member 4 provided in the ball return device 3 is driven in step 21, and the ball return device. It prevents the return of the ball to 3. Then, in step 22, the timer is reset, in step 23, the timer is started, and in step 24, it is determined whether or not the predetermined time has elapsed, and when it is determined that the predetermined time has elapsed, When the return blocking member 4 is driven to open in step 25, the balls can be returned to the ball returning device 3 again. The timer set in steps 22 and 23 is set to a time (for example, 10 minutes) during which the amount of balls stored in the storage tank 15 is sufficiently reduced. You may make it prohibit a return until (for example, S4) turns OFF.
[0033]
  Also, as shown in FIGS. 12 and 14, when almost no balls are stored in any of the priority storage tank 14, the non-priority storage tank 15, and the auxiliary tank 27, first, in step 26, the priority storage tank 14 is set. It is determined whether or not the provided ball amount sensor S1 is OFF. If it is OFF, the return blocking member provided in the ball returning devices 80 and 82 of the pachinko islands (other islands) facing in step 27. 81 and 83 are driven to prevent the return of the balls to the ball return devices 80 and 82, and prompt the player to return the balls to the ball return device 3 on his own island. In step 28, the timer is reset. In step 29, the timer is started. In step 30, it is determined whether or not a predetermined time has elapsed. In step 31, when it is determined that the predetermined time has elapsed. When the return blocking members 81 and 83 on the other islands are driven to open, the balls can be returned to the ball returning devices 80 and 82 on the pachinko islands that face again. The timer set in steps 28 and 29 is set to a time (for example, 10 minutes) in which the amount of balls stored in the priority storage tank 14 is sufficiently increased. You may make it accelerate | stimulate a return until a sensor (for example, S2) turns on.
[0034]
  As described above, the operation of the ball return device 3 is interlocked with the ball amount sensor S5 of the non-priority storage tank 15, and the operation of the ball return devices 80 and 82 facing each other is the ball amount sensor S5 of the non-priority storage tank 15 and By interlocking with the ball quantity sensor S1 of the priority storage tank 14, the quantity of possessed balls can be made uniform between adjacent pachinko islands.
[0035]
  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 (henceforth 1st Embodiment), one auxiliary tank 27 adjoins the non-priority storage tank 15. FIG. Although what was provided was shown, as shown in FIG. 16, two auxiliary tanks 92 and 27 are each provided adjacent to the priority storage tank 14 and the non-priority storage tank 15 (hereinafter referred to as the second embodiment). ). The configuration of the second embodiment in which the two auxiliary tanks 92 and 27 are provided adjacent to the priority storage tank 14 and the non-priority storage tank 15 will be briefly described. Note that, among the configurations according to the second embodiment, detailed description of the configurations common to the first embodiment is omitted.
[0036]
  In the second embodiment, auxiliary tanks 92 and 27 are provided adjacent to the priority storage tank 14 and the non-priority storage tank 15, and the priority storage tank 14 is disposed in the upper center of the auxiliary tank 92 via a recovery rod 91. The upper collection basket 93 communicated with the pipe is inclined. And the upper basket 16 is formed in the inner surface upper part of the priority storage tank 14, and the ball which fell from the priority channel | path body 11 is guide | induced to the downstream. The upper tub 16 is inclined between the priority storage tank 14 and the auxiliary tank 92 and is connected to the inner portion of the auxiliary tank 92 via a connection upper tub 90 provided with a shutter device 96 (C1) in the middle. It communicates with an upper flange 39 formed on the upper side. The ball stored in the auxiliary tank 92 rolls on the inclined bottom surface 94 and is transported to the collection basket 91 by the small reduction machine 95 (K1).
[0037]
  The operation of the shutter devices 96 (C1) and 51 (C2) and the small reduction machines 95 (K1) and 32 (K2) in the pachinko island constructed as described above will be described with reference to FIGS. . FIG. 15 is a flowchart showing control of the shutter devices 96 and 51 and the small reduction machines 95 and 32, and FIGS. 16 to 21 are operation explanatory diagrams of the shutter devices 96 and 51 and the small reduction machines 95 and 32. . In the following description, the auxiliary tanks 92 and 27 are expressed as the first auxiliary tank 92 and the second auxiliary tank 27, the shutter devices 96 and 51 are expressed as the first shutter device 96 and the second shutter device 51, and the small size. The reduction machines 95 and 32 are expressed as a first small reduction machine 95 and a second small reduction machine 32.
[0038]
  First, as shown in FIGS. 15 and 16, when the priority storage tank 14 is full and balls are stored in the non-priority storage tank 15, the amount of balls provided in the non-priority storage tank 15 in step 40. It is determined whether or not the sensor S4 is turned on. If the sensor S4 is turned on, a certain amount of balls has already been stored in the non-priority storage tank 15, so the balls in the second auxiliary tank 27 are not used. The second small reduction machine 32 that is transported to the priority storage tank 15 is not driven (step 41). In step 42, it is determined whether or not the ball amount sensor S6 provided in the first auxiliary tank 92 is ON. If the ball amount sensor S6 is ON, the first auxiliary tank 92 is already full of stored balls. In step 43, the shutter plate 51 of the second shutter device 51 provided in the middle of the connection upper rod 25 is opened, and the balls are allowed to flow into the second auxiliary tank 27 on the opposite side. In addition, as shown in FIG. 17, when the amount of returned balls from the ball return device 3 increases and the storage amount in the non-priority storage tank 15 becomes nearly full, it is determined whether or not the ball amount sensor S5 is ON. When it is discriminated and turned on, the return blocking member 4 provided in the ball return device 3 is driven to prevent the return of the ball to the ball return device 3.
[0039]
  Next, as shown in FIGS. 15 and 18, even when the priority storage tank 14 is full, the storage amount in the non-priority storage tank 15 does not reach a certain amount, and the ball amount sensor S4 is not turned on. In step 44, the shutter plate 71 of the second shutter device 51 is closed, and the flow of balls on the connection upper rod 25 is blocked, and the returned balls are stored in the non-priority storage tank 15. When the storage amount in the non-priority storage tank 15 increases, it is determined in step 45 whether or not the ball amount sensor S3 provided in the non-priority storage tank 15 is ON. Since a certain amount of balls is also stored in the non-priority storage tank 15, the shutter plate of the first shutter device 96 provided in the middle of the connection upper rod 90 is opened in step 46 to the auxiliary tank 92. Let the ball flow in. In this case, since the amount stored in the priority storage tank 14 has already reached near full capacity, the first small reduction machine 95 that lifts the balls in the first auxiliary tank 92 to the priority storage tank 14 is not driven (step 47). . However, if balls remain in the second auxiliary tank 27, the ball quantity sensor S8 provided in the second auxiliary tank 27 in step 48 is used to further increase the number of balls stored in the non-priority storage tank 15. It is determined whether or not it is ON. If it is ON, the second small reduction machine 32 is driven at step 49. In this case, as shown in FIG. 19, when no ball remains in the auxiliary tank and the ball quantity sensor S8 is not ON, the second small reduction machine 32 is not driven (step 50).
[0040]
  Further, as shown in FIG. 15, when the priority storage tank 14 is full, almost no balls are stored in the non-priority storage tank 15, and the ball quantity sensor S3 is not turned ON, the first step 51 is performed. The shutter plate of the one shutter device 96 is closed to prevent the balls from flowing into the first auxiliary tank 92 so that the balls returned from the ball return device 3 are stored in the non-priority storage tank 15. In step 52, it is determined whether or not the ball quantity sensor S8 provided in the second auxiliary tank 27 is ON. If it is ON, the second small reduction machine 32 is driven in step 53, The balls in the second auxiliary tank 27 are lifted to the non-priority storage tank 15. In this case, since the priority storage tank 14 is already full, the first small reduction machine 95 on the opposite side is not driven (step 54). If the ball quantity sensor S8 provided in the second auxiliary tank 27 is not ON, the second small reduction machine 32 is stopped in step 55, and provided in the first auxiliary tank 92 on the opposite side in step 56. It is determined whether or not the given ball amount sensor S7 is ON. When the ball amount sensor S7 is ON, as shown in FIG. 20, the first small reduction machine 95 is driven at step 57, and when it is not ON, as shown in FIG. 1 The small reduction machine 95 is not driven (step 58). In this case, since the balls are hardly stored in any of the priority storage tank 14, the non-priority storage tank 15, the first auxiliary tank 92, and the second auxiliary tank 27, the ball return device 80 that faces the ball is opposed. , 82 are driven to prevent the return of the balls to the ball return devices 80, 82, and prompt the return of the balls to the ball return device 3 to its own island. It is like that.
[0041]
  The control of the pachinko island platform 1 according to the second embodiment has been described above, but this control is summarized as follows. That is, the priority of storage is in the order of the priority storage tank 14 → the non-priority storage tank 15 → the first auxiliary tank 92 → the second auxiliary tank 27, and the first shutter device 96 related to the first auxiliary tank 92 is driven. By interlocking with the ball amount sensor S3 in the non-priority storage tank 15, the inflow of the increased ball amount to the first auxiliary tank 92 according to the storage amount of the non-priority storage tank 15 is prevented or allowed. In addition, the driving of the second shutter device 51 related to the second auxiliary tank 27 is interlocked with the ball amount sensor S4 upstream of the ball amount sensor S3 and the ball amount sensor S6 of the first auxiliary tank 92. Further, it is possible to prevent or allow the increased amount of balls to flow into the second auxiliary tank 27 in accordance with the storage amounts of the first auxiliary tank 92 and the non-priority storage tank 15.
[0042]
  On the other hand, the driving of the first small reduction machine 95 related to the first auxiliary tank 92 is performed by the ball amount sensor S3 in the non-priority storage tank 15, the ball amount sensor S8 in the second auxiliary tank 27, and the balls in the first auxiliary tank 92. By interlocking with the quantity sensor S7, the first small reduction machine 95 can be efficiently driven without idling, and the driving of the second small reduction machine 32 related to the second auxiliary tank 27 is a non-priority storage tank. By linking with the ball quantity sensor S3 in 15 and the ball quantity sensor S8 in the second auxiliary tank 27, the second small reduction machine 32 can be driven efficiently without idling.
[0043]
【The invention's effect】
  As is apparent from the above description, in the present invention, used balls discharged from a plurality of pachinko machines arranged in a row are circulated from a collection basket, a storage tank, a ball lifting device, and a supply basket. Configured to be used recirculating through a pathway, PlayIn the pachinko island stand provided with a ball return device for returning the pachinko balls acquired by the technician, the inside of the pachinko island stand further, from the ball return device when the storage amount of the storage tank becomes a certain amount or more An auxiliary tank that can store return balls to be returned, and an upper basket that guides return balls that are provided from the upper part of the storage tank to the auxiliary tank and that are released from the back side of the ball return device to the storage tank. A shutter device that is provided in the middle of the upper tub and that can prevent or allow the return ball to flow into the auxiliary tank according to the amount of the storage tank, and a pachinko stored in the auxiliary tank. And a small reducing machine that lifts the balls to the circulation path, and the storage tank has a storage amountLess than the upper limitA ball amount sensor is provided to detect that a certain amount has been reached, and the ball amount sensorWhen it detects that it has reached the certain amountThe shutter deviceAllows the return balls to flow and the pachinko balls are stored in the auxiliary tank.Therefore, the returned balls returned from the ball return device are first supplied to the storage tank, and the storage amount of the storage tank isLess than the upper limitAfter it exceeds a certain level, it is supplied directly to the auxiliary tank without going through the ball lifting device, so the auxiliary tank can be used effectively regardless of the lifting capacity of the ball lifting device. Even if a large amount of free gift balls are returned, the ball can be returned smoothly..
[0044]
  Also, the amount of storage in the auxiliary tank isPredeterminedThis ball quantity sensor is equipped with a ball quantity sensor that detects when the quantity has been reached.Detects that the predetermined amount has been reached, andProvided in the storage tankSaidBall quantity sensorDid not detect that the fixed amount was reached.And by said small reduction machineSo that pachinko balls stored in the auxiliary tank are transported to the circulation pathBy controlling the drive, the small reduction machine can be driven efficiently without idling.
[Brief description of the drawings]
FIG. 1 is a front view showing an internal structure of a pachinko island stand.
FIG. 2 is an enlarged front view showing an internal structure of a central portion of the pachinko island stand.
FIG. 3 is a partially broken perspective view showing a configuration for preventing foreign matter from entering a pachinko island platform.
FIG. 4 is a perspective view showing a relationship among a storage tank, an auxiliary tank, and a ball return device.
FIG. 5 is a plan view showing the operation of a storage tank, an auxiliary tank, and a ball return device.
FIG. 6 is a side view of the shutter device.
FIG. 7 is a perspective view showing an attachment state of the small reduction machine.
FIG. 8 is a perspective view showing the operation of the small reduction machine.
FIG. 9 is a flowchart showing control of a shutter device and a small reduction machine.
FIG. 10 is an operation explanatory diagram of a shutter device and a small reduction machine.
FIG. 11 is also an operation explanatory diagram of a shutter device and a small reduction machine.
FIG. 12 is a flowchart showing control of the use state of the ball return device.
FIG. 13 is an operation explanatory diagram of a ball return device.
FIG. 14 is also an operation explanatory diagram of a ball return device.
FIG. 15 is a flowchart showing control of the shutter device and the small reduction machine.
FIG. 16 is an operation explanatory diagram of a shutter device and a small reduction machine.
FIG. 17 is also an operation explanatory diagram of a shutter device and a small reduction machine.
FIG. 18 is also an operation explanatory diagram of a shutter device and a small reduction machine.
FIG. 19 is also an operation explanatory diagram of a shutter device and a small reduction machine.
FIG. 20 is also an operation explanatory diagram of a shutter device and a small reduction machine.
FIG. 21 is also an operation explanatory diagram of the shutter device and the small reduction machine.
[Explanation of symbols]
1 Pachinko island stand
3 Ball return device
4 Return blocking member
6 Upper tank
7,8 Supply bowl
10 Reflux passage body
11 priority passage body
12 Non-priority passage body
13 Return pipe
14 Priority storage tank
15 Non-priority storage tank
16, 17 Upper ridge
25 Connection top
26 Collection dredging
27 Auxiliary tank
28 Upper recovery bowl
32 Small reduction machine
38,39 Upper heel
50 connections
51 Shutter device
80,82 ball return device
90 Connection top
91 Collection dredging
92 Auxiliary tank
93 Upper recovery bowl
95 Small reduction machine
96 Shutter device

Claims (2)

The spent balls discharged from a plurality of pachinko machine to be arrayed, recovery gutter, storage tank, the ball pumped device, and along with configured to recycled through the circulation path comprising the supply trough, Yu technique In pachinko island stand where ball return device to return pachinko ball which person acquired is provided,
Inside the pachinko island stand, an auxiliary tank that can store return balls returned from the ball return device when the storage amount of the storage tank reaches a predetermined level or more, and the auxiliary from the upper part of the storage tank An upper basket that is provided over the tank and that guides the return balls released from the back side of the ball return device to the storage tank to the auxiliary tank, and is provided in the middle of the upper basket and according to the storage amount of the storage tank While providing a shutter device that can prevent or allow inflow of return balls to the auxiliary tank, and a small reduction machine that lifts pachinko balls stored in the auxiliary tank to the circulation path,
The ball quantity sensor for detecting that the storage amount in the storage tank reaches a predetermined amount less than the upper limit amount provided, said shutter device wherein when該玉amount sensor detects that reaches the fixed amount A pachinko island stand in which pachinko balls are stored in the auxiliary tank while allowing inflow of return balls . Wherein the accumulated amount in the auxiliary tank is provided with a ball quantity sensor for detecting that has reached a predetermined amount, said ball quantity sensor The ball quantity sensor is provided on the detected and the storage tank that has reached a predetermined amount claim 1 but which is characterized in that the drive control such that pumped the pachinko balls in which the size reduction machine is stored in the auxiliary tank by a child did not detect that reaches the predetermined amount to the circulation path The pachinko island stand described.

Images