JP4269346B2 - 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 row through a collection basket, a storage tank, a ball lifting device, and a supply basket, and the supply basket The present invention relates to a pachinko island stand provided with a reflux basket for returning excess balls overflowing from the storage tank to the storage tank.
[0002]
[Prior art]
Conventionally, in pachinko islands configured to circulate and use pachinko balls inside, it is disclosed in Japanese Patent Application Laid-Open No. 7-231979 as a technique for overflowing excess balls overflowing from the replenishment basket toward the storage tank. Technology (hereinafter referred to as “conventional technology 1”) and the technology disclosed in Japanese Utility Model Publication No. 53-140584 (hereinafter referred to as “conventional technology 2”) have been proposed. In the prior art 1, a reflux basket is provided below the upper tank, and excess balls from the upper tank are returned to the storage tank. A plurality of regulating walls are alternately arranged on the inner surface of the reflux tank. Protrusions are provided to reduce the flow speed of pachinko balls that flow down the interior. Further, in the prior art 2, as a cylinder for cushioning the fall of the pachinko ball, a bent step portion bent at a predetermined angle is provided above and below the central straight part of the cylinder body so as to reduce the impact caused by the fall of the pachinko ball. ing.
[0003]
[Problems to be solved by the invention]
Therefore, in the above prior art 1, since the flat regulation walls are alternately projected on the inner wall of the reflux basket at a predetermined interval, there are the following problems. First, when the pachinko ball flows down in the reflux bowl, the impact applied to the regulation wall is large, and the regulation wall is damaged or noise is generated. Secondly, when the pachinko balls are filled in the reflux bowl, the pachinko balls near the inner surface on the regulation wall are retained for a long period of time. Thirdly, when replacing a damaged regulation wall, the entire reflux basket is replaced, which is uneconomical and complicated. Fourthly, the reflux speed of the pachinko balls cannot be changed according to the amount of balls stored in the pachinko islands. Further, in the above-described prior art 2, the fourth problem is not only the same as that in the prior art 1, but because of its structure, there is a problem that a large space is occupied in spite of a small amount of stored balls inside the reflux basket. There is. The present invention has been made in view of such circumstances, and an object of the present invention is to stably flow down all pachinko balls in the reflux basket over a long period of time, and it is economical to replace parts. The object is to provide a pachinko island stand that can be easily changed and the reflux speed of the pachinko balls can be changed.
[0004]
[Means for Solving the Problems]
In order to achieve the above-described object, specific means adopted by the present invention will be described with reference to the drawings. As shown in FIGS. 1 and 12, used balls discharged from a plurality of pachinko machines 2 arranged in a row are used for collecting baskets 20 and 21, storage tanks 8 and 9, ball lifting device 5 and supply basket 7. The recirculation reed 70 that recirculates excess balls overflowing from the replenishing reed 7 to the storage tanks 8 and 9 (having the same function as the recirculating reeds 11 and 12 in FIG. 1). In the pachinko island platform 1 provided with a reflux cage 70, the reflux cage 70 is provided with a regulating wall 71 projecting to one side of the inner side surface in order to regulate the linear fall of the reflux ball flowing down inside. Are connected to each other, and the upper surface of the restriction wall 71 is formed on an arcuate arc upper surface 79, and when the plurality of reflux rod members 76 are connected, any Reflux bowl member 76 In Restriction wall 71 of Sudden How to set Direction The protruding direction of the restriction wall 71 in the reflux bar member 76 other than the arbitrary reflux bar member 76 and Different Connect In this way, it is possible to connect the restriction walls 71 where the reflux balls flowing down inside alternately collide with each other at different intervals in the vertical direction. With this configuration, the pachinko balls that have entered the reflux basket 70 from above collide with a plurality of regulation walls 71 that protrude alternately and face the inner surface when flowing down the reflux basket 70. Although the flow velocity is reduced while the flow velocity is reduced, the upper surface of the restriction wall 71 is an arcuate circular arc upper surface 79, so that the pachinko balls flowing down from above are moved horizontally. Since the arc-shaped portion extending in the direction is gradually reduced in speed, it is caused to flow downward again, so that the impact of the pachinko balls flowing down on the regulating wall can be reduced, and the regulating wall 71 can be damaged. No noise is generated. Furthermore, since the upper surface of the regulation wall 71 is an arcuate arc upper surface 79, the pachinko balls do not stay on the regulation wall 71, and the flow of the pachinko balls in the reflux basket 70 can be made smooth. .
[0005]
Also, as shown in FIG. 12, when connecting the plurality of reflux rod members 76, any Reflux bowl member 76 In Restriction wall 71 of Sudden How to set Direction The protruding direction of the restriction wall 71 in the reflux bar member 76 other than the arbitrary reflux bar member 76 and Different Connect As a result, the upper and lower intervals of the restriction wall 71 where the reflux balls flowing down alternately collide alternately can be connected. And Even when the damaged regulation wall 71 is replaced, it is only necessary to replace the reflux bar member 76 having the damaged regulation wall 71 without replacing the entire reflux bar 70, so that it is economical and easy to replace. Furthermore, the reflux speed of the pachinko balls flowing down in the reflux bowl 70 can be changed by connecting the reflux bowl member 76 in consideration of the direction in which the regulation wall 71 protrudes.
[0006]
Further, as shown in FIG. 15, the restriction wall 92 can be detachably attached to the reflux bar 90 so that the entire reflux bar 90 can be replaced even when the damaged regulation wall 92 is replaced. In addition, since only the damaged regulating wall member 92 needs to be replaced, the replacement work is economical and easy. Further, as shown in FIG. 2, an insertion port 48 is provided at the upper end of the reflux baskets 11 and 12 so that an insertion plate 49 for preventing the pachinko balls from entering can be inserted horizontally from the outside. After the insertion plate 49 is inserted into 48 to prevent a new pachinko ball from entering, the inside of the reflux baskets 11 and 12 is emptied while waiting for the pachinko ball stored therein to be discharged. Inspection and repair work can be performed.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. First, a schematic configuration of the pachinko island platform 1 according to the embodiment will be described with reference to FIG. FIG. 1 is a front view showing the internal structure of the pachinko island stand 1.
[0008]
In the figure, the pachinko island platform 1 is, as is well known, a rectangular parallelepiped framework, and a plurality of pachinko machines 2 are arranged in the back in the center in the longitudinal direction side surface. The ball lending machine (not shown) is pinched so as to correspond to the pachinko machine 2 on a one-to-one basis. In addition, a ball lifting device storage portion 4 in which a ball lifting device 5 to be described later is stored and installed is formed in the approximate center of the pachinko island stand 1, and adjacent to the ball lifting device storage portion 4, a player Is provided with a ball return device 3 for issuing a receipt in which the number of returned balls is recorded numerically. The premium balls returned to the ball return device 3 are temporarily stored in a premium ball tank (not shown) provided in the lower portion of the ball return device 3 and then passed through a connecting rod 29 provided on the back surface thereof. Then, it is guided to the upper recovery tank 21 described later and stored in the non-priority storage tank 9. The ball return device 3 is provided with a return prevention member (not shown) that is driven based on the detection output from the ball quantity sensor 35 in the non-priority storage tank 9. When the amount of balls to be stored reaches full, it is prohibited to return any more premium balls. As is well known, the prize ball tank (not shown) is provided with a counting device for counting the number of prize balls, and the prize ball is sent from the counting device to a management computer (not shown) provided in the game hall. A number signal is sent.
[0009]
In addition, an upper tank 6 for temporarily storing the pachinko balls that have been lifted is provided at the upper part of the ball lifting device storage unit 4. Replenishment rods 7 that are inclined downward toward both ends of the pachinko island platform 1 are connected to both ends of the bottom surface of the upper tank 6, and discharged from the discharge ports 25 of the ball lifting device 5 facing above the upper tank 6. The pachinko balls thus made are distributed to the replenishment rods 7 on both sides by a guide plate 26 provided below the discharge port 25. A ball separator 14 is provided at an intermediate portion of the replenishing basket 7 corresponding to each pachinko machine 2 and a ball lending machine (not shown). The ball separator 14 is for taking pachinko balls flowing down on the replenishment basket 7 and supplying them to each pachinko machine 2 and a ball lending machine (not shown).
[0010]
Then, pachinko balls polished and lifted by a ball lifting device 5 to be described later are discharged from the upper tank 6 to the replenishment rod 7 and then separated by the ball separator 14, and the connection pipe 15 and the ball replenisher 16 are connected. Via, it is supplied to a prize ball tank (not shown) and a ball lending machine (not shown) provided at the upper back of each pachinko machine 2. As is well known, the ball separator 14 is provided with a counting device for counting the number of replenished balls. From this counting device, the number of replenished balls is supplied to a management computer (not shown) provided in the game hall. A signal is sent.
[0011]
Further, a drop port 27 through which the pachinko ball flows out when the pachinko ball on the replenishing bowl 7 is full is formed on the bottom surface of the upper tank 6. A saddle box 10 is provided. This reflux basket 10 is used in the pachinko machine 2 with little use of prize balls, so that it is no longer necessary to supply the pachinko balls to the supply basket 7, and as a result, when the stored balls in the upper tank 6 fall from the drop port 27, surplus Are returned to storage tanks 8 and 9 installed on both lower sides of the ball lifting device 5 described later. In addition, the reflux basket box 10 is provided with a priority reflux basket 11 that communicates with one storage tank 8 and a non-priority reflux basket 12 that communicates with the other storage tank 9. This is because surplus balls that have fallen into the reflux basket box 10 are preferentially guided to the priority reflux basket 11 by the branch plate 13 attached to the upper center of the reflux basket box 10 and stored in one storage tank 8. When the storage tank 8 is full and the priority reflux basket 11 is also full, it can be guided to the non-priority reflux basket 12 and stored in the other storage tank 9. That is, in the illustrated embodiment, the left storage tank 8 functions as a priority storage tank that preferentially stores balls, and the right storage tank 9 functions as a non-priority storage tank.
[0012]
In addition, when the entire recirculation basket box 10 including the priority reflux basket 11 and the non-priority reflux basket 12 is filled with balls, the portion has a capacity for storing about 20,000 balls. In addition, an emergency stop sensor 30 is provided at an upstream position of the non-priority reflux basket 12, and when a ball is stored up to that position, the drive motor of the ball lifting device 5 is urgently stopped. .
[0013]
Further, the upper end of the reflux hose 19 facing the lower side of the dropping port 27 is connected to the upper part of the reflux basket box 10. The reflux hose 19 receives a pachinko ball falling from the dropping port 27 and is led to the inclined bottom surface 23 slightly downstream from the non-priority storage tank 9. The priority of the flow of the balls into the reflux hose 19 is the highest priority, and the pachinko balls that have dropped from the drop port 27 are preferentially guided and guided downstream of the non-priority storage tank 9. However, when balls are stored on the downstream side of the non-priority storage tank 9 and reach the vicinity of the outlet of the reflux hose 19, further balls are not guided and stay in the reflux hose 19, and the interior of the reflux hose 19 is completely When the ball is filled with balls, the balls that have fallen from the drop port 27 to the reflux basket box 10 are guided to the priority reflux basket 11.
[0014]
In general, however, many stored balls remain on the priority storage tank 8 side, whereas there are many cases where no stored balls remain on the non-priority storage tank 9 side. There is a drawback in that the supply of balls to 24 is different on the left and right, and the efficiency of lifting the balls deteriorates. In order to eliminate such drawbacks, a part of the pachinko ball is preferentially guided to the non-priority storage tank 9 side through the reflux hose 19 so that the introduction rod 24 of the ball lifting device 5 is evenly distributed from the left and right. The ball is supplied to the ball to improve the efficiency of ball lifting.
[0015]
As described above, the used balls discharged from the pachinko machine 2 and the reflux balls returned from the reflux basket 10 are preferentially stored at the lower part of the pachinko island stand 1 and on both sides of the ball lifting device 5. It is stored in the tank 8 and the non-priority storage tank 9. Both the priority storage tank 8 and the non-priority storage tank 9 have substantially the same structure. That is, these storage tanks 8 and 9 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 pachinko balls. The bottoms of the storage tanks 8 and 9 are formed as inclined bottom surfaces 22 and 23 that guide the stored pachinko balls to the introduction rod 24 of the ball lifting device 5. Furthermore, upper collection tanks 20 and 21 inclined downward toward both ends are provided on the upper portions of the storage tanks 8 and 9. The upper recovery tanks 20 and 21 are plate-like members formed with a width less than half that of the storage tanks 8 and 9 attached to both inner sides of the storage tanks 8 and 9, and their start end portions are the above-mentioned priority reflux. It communicates with the outlet 53 (see FIG. 3) of the basket 11 and the non-priority reflux basket 12. In addition, pachinko balls discharged from the pachinko machine 2 installed on the island edge side are collected by the collection baskets 103 and 104 arranged in the lower part thereof and guided onto the guide bottom surfaces 22 and 23 of the storage tanks 8 and 9. It has come to be.
[0016]
Thus, the used balls discharged from each pachinko machine 2 are temporarily stored in the out ball box 17 and then discharged from the discharge hose 18 and fall onto the upper recovery rods 20 and 21 and the recovery rods 103 and 104. , And they are led downstream. Further, the pachinko balls recirculated from the reflux reeds 11 and 12 are discharged from the discharge port 53 of the recirculation reeds 11 and 12 to the start ends of the upper recovery reeds 20 and 21, and downstream through the upper recovery reeds 20 and 21. Led. Furthermore, as described above, the return balls returned to the ball return device 3 are guided to the downstream side through one upper collection basket 21. As described above, the used balls, reflux balls, and return balls guided to the downstream side through the upper collection baskets 20 and 21 and the collection baskets 103 and 104 are finally formed in the lower part of the storage tanks 8 and 9. It falls on the inclined bottom surfaces 22 and 23 and is stored in the storage tanks 8 and 9. As is well known, the out ball box 17 is provided with a counting device for counting the number of balls discharged, and the number of balls discharged from the counting device to a management computer (not shown) provided in the game hall. A signal is sent.
[0017]
In addition, on the inner side walls of the priority storage tank 8 and the non-priority storage tank 9, ball amount sensors 31 to 35 (hereinafter, 31 for S1, 32 for S2, 33 for S3, 34 may be expressed as S4 and 35 as S5). The pachinko balls stored in the priority storage tank 8 and the non-priority storage tank 9 are first stored in order from the upstream side to the downstream side of the priority storage tank 8, and then in order from the upstream side to the downstream side of the non-priority storage tank 9. It is stored in. Accordingly, the ball amount sensor S1 constitutes a lower limit sensor that detects a case where the storage amount is the smallest, and the ball amount sensor S5 detects that the storage amount of the priority storage tank 8 and the non-priority storage tank 9 has reached the upper limit. The upper limit sensor is configured to prohibit the return operation of the ball return device 3. Based on the detection signals of the ball quantity sensors S1 to S5, the quantity stored in the priority storage tank 8 and the non-priority storage tank 9 is displayed on the ball quantity display 28 attached to both ends of the pachinko island base 1. . The ball amount indicator 28 displays the storage amount in a stepwise manner by turning on display lamps (not shown) built in the color-coded ball amount level display units 28a to 28c.
[0018]
Next, the ball lifting device 5 and the recirculation basket box 10 housed and installed in the ball lifting device housing portion 4 formed at substantially the center of the pachinko island platform 1 will be described with reference to FIG. FIG. 2 is a perspective view of the ball lifting device 5 and the reflux basket box 10 as viewed from the front. In addition, in this embodiment, although the reflux basket box 10 is integrally attached with respect to the ball lifting apparatus 5, the structure and effect | action of the ball lifting apparatus 5 are demonstrated first.
[0019]
In the figure, the ball lifting device 5 has a rectangular tube-shaped lifting cylinder main body 37 standing vertically on an upper portion of a substantially square-shaped support base 36, and the outer periphery in the longitudinal direction of the lifting cylinder main body 37 is arranged at the lower part. A conveyor belt 39 that is looped between a pulley 38 with a built-in motor that is supported by the upper roller and an upper roller (not shown) that is rotatably supported on the upper portion is circulated. In addition, a plurality of rotating rollers (not shown) are rotatably supported in the up and down direction at appropriate intervals in the inside of the lifting cylinder body 37, and a part of the rotating rollers is part of the lifting cylinder body 37. The conveyor belt 39 is guided and supported by protruding outward from the rising side surface. Further, although not shown in detail, the motor built-in pulley 38 is configured as a cylindrical roller having a relatively large diameter, and when the current is supplied, the cylindrical outer periphery rotates to drive the conveyor belt 39 around. It is.
[0020]
Below the motor built-in pulley 38, an introduction starting end rod 40 into which the pachinko balls before being lifted are introduced is fixed, and the introduced pachinko balls are connected to the introduction cylinder end 37 continuously with the introduction starting end rod 40. An inflow arc rod 41 for moving to the lower end is fixed. Although not shown in detail, grooves for aligning the introduced pachinko balls in a plurality of rows are formed inside the introduction starting end rod 40 and the inflow arc rod 41. Further, the mounting structure of the introduction starting end rod 40 and the inflow arc rod 41 is fixed to a mounting plate (not shown) so that one end thereof can move slightly, and the other end is planted on the support base 36. The support pin 42 is slidably supported via a spring (not shown). In other words, the lower end of the introduction start rod 40 and the lower end of the inflow arc rod 41 are inserted through the support pin 42 and secured so as not to come off by the adjusting nut 43, but are always attached by the spring interposed in the support pin 42. It is biased upward. Thus, it is possible to adjust delicate intervals between the conveying belt 39 and the introduction starting end rod 40 and the inflow arc rod 41 according to the tightening degree of the adjusting nut 43, and by adjusting the intervals, the pachinko balls can be smoothly smoothed. Movement can be made possible.
[0021]
In addition, three tension rollers 44 that apply tension to the circulating conveyor belt 39 are rotatably supported and attached to the lifting cylinder main body 37 at the upper part of the motor built-in pulley 38. Although not shown in detail, a spring is interposed in the mounting bracket to which the intermediate tension roller is attached, and a constant tension can always be applied to the transport belt 39 by the biasing force. Here, the motor built-in pulley 38 and each tension roller 44 are in a substantially vertical positional relationship. When the transport belt 39 is attached, the motor built-in pulley 38 is positioned inside the transport belt 39 and the lower tension roller 44. Are positioned outside the conveyor belt 39, an intermediate tension roller (not shown) is positioned inside the conveyor belt 39, and an upper tension roller (not shown) is positioned outside the conveyor belt 39.
[0022]
By the way, a guide rail cover 45 is pivotally supported and attached to the back side of the lifting cylinder main body 37 so as to be freely opened and closed. The guide rail cover 45 is opened when the conveying belt 39 or the cloth belt (not shown) is attached to the ball lifting device 5, and when the conveying belt 39 or the cloth belt is attached, the guide cylinder main body 37 is opened. It is attached in a state facing the lifting cylinder main body 37 by a cover locking metal fitting 46 attached to the side. The cloth belt (not shown) is made of a cloth having a relatively coarse texture in order to exhibit its ball polishing ability, and after being used for a certain period of time, the old part is wound up to form a new part. It can be exchanged.
[0023]
Thus, in the state where the guide rail cover 45 is mounted facing the lifting cylinder main body 37 by the cover locking metal fitting 46, the pachinko balls introduced to the introduction starting end rod 40 are conveyed via the inflow arc rod 41. The discharge port 25 is sandwiched between a belt 39 and a cloth belt (not shown), polished and fed, and fixed to the upper part of the feed cylinder body 37 to bend the ball in the discharge direction, and then through an upper bending rod 47. Will drain the cleaned pachinko balls.
[0024]
Next, the structure of the reflux paddle box 10 that is integrally attached to the ball lifting device 5 will be described. The reflux paddle box 10 is formed in a rectangular parallelepiped shape so as to surround the lifting cylinder main body 37 of the ball lifting device 5, and the support base 36 of the ball lifting device 5 by the legs 10 a provided at the four corners of the bottom surface. It is erected vertically. The ball lifting device 5 and the reflux basket box 10 configured integrally as described above are detachably installed with respect to the ball lifting device storage unit 4 in this state. It is possible to reduce the work labor when installing or removing from the lifting device storage unit 4.
[0025]
A branch box 105 having the branch plate 13 is disposed in the upper part of the reflux tank box 10, and the priority reflux tank 11 and the non-priority reflux tank 12 are disposed on both sides of the lower part. . These are detachably attached to the reflux basket box 10, but as described above, when the ball lifting device 5 and the reflux basket box 10 are stored and installed in the ball lifting device storage unit 4, the reflux basket is provided. The pachinko balls that have fallen from the drop opening 27 established at the top of the box 10 are guided to the priority storage tank 8 and the non-priority storage tank 9.
[0026]
Further, an insertion port 48 is opened horizontally at the upper end portion of each of the priority reflux basket 11 and the non-priority reflux basket 12 so that the insertion plate 49 can be inserted from the front side. This is because the insertion plate 49 is inserted into the insertion port 48 to close the inlet 52 (see FIG. 3) of the priority reflux rod 11 and the non-priority reflux rod 12, and the priority reflux rod 11 and the non-priority reflux rod 12. It is for prohibiting the entry of pachinko balls into. That is, a failure occurs in the priority reflux rod 11 or the non-priority reflux rod 12 during business operation, and it becomes necessary to check or repair, or the reflux velocity is controlled by the reflux rod members 76 and 86 (see FIGS. 10 and 13) described later. When changing, it is not possible to work in a state where pachinko balls are stored inside. Therefore, the insertion plate 49 is inserted into the insertion port 48 to prevent a new pachinko ball from entering, and waiting for the pachinko balls stored therein to be discharged, It is intended to enable inspection and repair work when the interior is empty. Each of the priority reflux basket 11 and the non-priority reflux basket 12 has a capacity capable of storing about 20,000 pachinko balls, and the ball lifting device 5 has about 14,000 pachinko balls per minute. Can be lifted. Accordingly, about 7,000 pachinko balls are introduced into the introduction rod 24 of the ball lifting device 5 from both the priority storage tank 8 and the non-priority storage tank 9 per minute. If any of the reflux baskets 12 are full, it takes about 3 minutes before they become empty.
[0027]
The insertion plate 49 is formed in an L-shape when viewed from the side, and when the insertion plate 49 is inserted into the insertion port 48, a locking portion 49a formed on the front side of the insertion plate 49 is preferentially refluxed. The insertion plate 49 is prevented from entering further by being locked to the front wall portion of the basket 11 or the non-priority reflux basket 12. In the present embodiment, the insertion plate 49 is manually inserted. However, the insertion plate 49 is attached to the insertion port 48 so as to be retractable, and the insertion plate 49 is inserted by an electric drive source. It may be.
[0028]
Next, the structure and operation of the above-described priority reflux basket 11 and non-priority reflux basket 12 will be described with reference to FIGS. 3, 4, 5 and 6. FIG. 3 is a front view showing the internal structure of the priority reflux basket 11 according to the present embodiment, and FIG. 4 is a front view showing the internal state of the pachinko island platform 1 when the amount of stored balls is small. These are front views which show the effect | action of the priority reflux basket 11 which concerns on this embodiment, and FIG. 6 is a front view which shows the effect | action of the conventional priority reflux basket 60. FIG. Note that the priority reflux basket 11 and the non-priority reflux basket 12 are simply arranged so that those having the same structure are bilaterally symmetrical. Only the bag 11 will be described.
[0029]
In FIG. 3, the priority reflux basket 11 is formed in a vertically long rectangular tube shape and is detachably attached to the reflux basket box 10 (see FIG. 2) as described above. The upper end portion of the priority reflux basket 11 is formed as an introduction port 52 for introducing a pachinko ball that has dropped from above, and the lower end portion of the priority reflux basket 11 is opened on one side of the priority reflux basket 11. A guide bottom surface 51 for discharging the pachinko balls from the discharge port 53 is formed. The guide bottom surface 51 is formed in the shape of a spider and can remove foreign substances adhering to the falling pachinko balls. In addition, a plurality of regulating walls 50 for regulating the pachinko balls flowing down the priority reflux basket 11 so as not to fall linearly are alternately opposed to the inner side surface of the priority reflux basket 11 with a predetermined interval. Projecting. As shown in FIGS. 4 and 5, when the amount of balls stored in the pachinko island platform 1 is relatively small, the pachinko balls introduced from the introduction port 52 are placed on the upper surfaces of the plurality of regulating walls 50. While colliding, it falls in the priority reflux basket 11 and is discharged from the guide bottom surface 51 to the discharge port 53. Note that the inner surface of the priority reflux basket 11, the regulation wall 50 (arc upper surface 55 described later), and the upper surface of the guide bottom surface 51 are covered with a sheet 54 made of synthetic resin (for example, ABS resin), and fallen pachinko balls. I try to protect them from shocks.
[0030]
The upper surface of the regulation wall 50 is formed as an arcuate arc upper surface 55 as viewed from the side, and extends in the horizontal direction as the arc upper surface 55 goes downward. Similar to the restriction wall 50, the upper surface of the guide bottom surface 51 is also formed in an arc shape when viewed from the side, and the lower end portion thereof communicates with the discharge port 53. With this configuration, the pachinko balls that have dropped from above do not collide with the restriction wall 50 in a vertical manner, but gradually reduce the speed at the upper surface of the circular arc of the restriction wall 50 that extends in the horizontal direction. After being guided in this way, it is caused to flow downward again, and finally discharged from the guiding bottom surface 51 to the discharge port 53. Therefore, the impact of the pachinko balls falling on the regulation wall 50 and the guide bottom surface 51 can be reduced, so that the regulation wall 50 and the guide bottom surface 51 are hardly damaged or generate noise.
[0031]
On the other hand, as shown in FIG. 6, a conventional reflux basket 60 has a regulation wall 61 formed in a flat plate shape on the inner side surface thereof so as to project substantially vertically. In such a reflux basket 60, the pachinko balls introduced from the introduction port 63 fall in the reflux basket 60 while colliding with the upper surfaces of the plurality of regulating walls 61 in a substantially vertical manner, and finally the induction bottom surface 62. To the discharge port 64. Therefore, the impact of the pachinko balls falling on the regulation wall 61 and the guide bottom surface 62 is large, and the protective resin 61 covering the top surfaces of the regulation wall 61 and the guide bottom surface 62 cannot be completely protected. 62 may be damaged or noise may be generated.
[0032]
Next, the operation of the priority reflux basket 11 and the non-priority reflux basket 12 when the amount of stored balls in the pachinko island platform 1 is large will be described with reference to FIGS. 7, 8 and 9. FIG. 7 is a front view showing the internal state of the pachinko island stand 1 when the amount of stored balls is large, FIG. 8 is a front view showing the operation of the priority reflux basket 11 according to this embodiment, and FIG. It is a front view which shows the effect | action of the conventional priority reflux tank 60. FIG.
[0033]
As shown in FIG. 7, when the use of prize balls in the pachinko machine 2 is small and the amount of balls stored in the priority storage tank 8 reaches the upper limit, the pachinko balls are also filled in the priority reflux basket 11. Therefore, the flow-down speed of the pachinko balls in the priority reflux basket 11 decreases. In this state, in the conventional reflux basket 60, as shown in FIG. 9, pachinko balls (black pachinko balls in the drawing) near the inner surface on the regulation wall 61 and the guide bottom surface 62 are newly added from above. In response to the pressure of the pachinko balls flowing down, it stayed for a long time and could not be refluxed. However, in the priority reflux basket 11 according to the present embodiment, as shown in FIG. 8, the upper surfaces of the regulation wall 50 and the guide bottom surface 51 are formed in an arc shape, and all pachinko balls on the arc upper surface 55 slide down. Therefore, the pachinko balls do not stay on the regulation wall 50 and the guide bottom surface 51 and are not refluxed.
[0034]
As described above, in the priority recirculation basket 11 according to the present embodiment (hereinafter referred to as “first embodiment”), the upper surfaces of the regulation wall 50 and the guide bottom surface 51 are formed as the circular arc upper surface 55, thereby Although the impact due to the flow of the ball is reduced so that the regulation wall 50 and the guide bottom surface 51 are not damaged, even if such a structure is used, the regulation wall 50 and the guide are used due to long-term use, contamination with foreign matter, and the like. The bottom surface 51 may be damaged. An embodiment for dealing with such a case (hereinafter referred to as “second embodiment”) will be described below with reference to FIGS. 10, 11, and 12. FIG. 10 is a front view showing the internal structure of the reflux bar 70 according to the second embodiment, FIG. 11 is a perspective view showing the attachment state of the reflux bar member 76, and FIG. 12 shows the second embodiment. It is a front view which shows the effect | action of the priority reflux basket 70 which concerns.
[0035]
In FIG. 10, the reflux rod 70 according to the second embodiment is configured by connecting a plurality of reflux rod members 76 provided with a regulating wall 71 having an arc upper surface 79 on one side of the inner surface thereof. . In other words, the reflux basket 70 is divided in the lateral direction to form a plurality of reflux basket members 76 that can be attached to and detached from each other, and function as the reflux basket 70 in a state where they are connected. An inlet port 76 a having an inlet 73 formed open is connected to the upper end of the reflux rod member 76, and a discharge bottom 74 and a guide bottom surface 72 communicating with the outlet 74 are connected to the lower end of the reflux rod member 76. The discharge port part 76b in which is formed is connected. The inner surface of the reflux basket 70, the circular arc upper surface 79 of the regulating wall 71, and the upper surface of the guide bottom surface 72 are covered with a sheet 75 made of synthetic resin (for example, ABS resin). To protect.
[0036]
As described above, the reflux barb member 76 is formed to be detachable from each other. The structure for this will be described. As shown in FIG. 11, fitting rails 78 project from the upper end portion of the reflux rod member 76 along both side surfaces of the reflux rod member 76. Further, a fitting groove 77 is formed in the lower end portion of the reflux rod member 76 along both side surfaces of the reflux rod member 76 so as to be fitted to the fitting rail 78. Thus, by fitting the fitting rail 78 formed at the upper end portion of the lower reflux rod member 76 into the fitting groove 77 formed at the lower end portion of the upper reflux rod member 76, The reflux rod member 76 and the lower reflux rod member 76 can be connected easily and appropriately. With such a configuration, even when the regulation wall 71 and the guide bottom surface 72 are damaged due to long-term use, mixing of foreign substances, and the like, the damaged regulation wall 71 and the guide bottom surface 72 are not replaced without replacing the entire reflux basket 70. Since it is sufficient to replace only the reflux rod member 76 having the above, it is economical and the exchange work is facilitated.
[0037]
Further, by adopting the above configuration, when the number of pachinko balls flowing down in the reflux basket 70 is small, the reflux speed can be adjusted. That is, as shown in FIG. 12, the reflux rod 70 according to the present embodiment is configured by connecting a plurality of reflux rod members 76 that are detachable from each other and have a regulating wall 71 on one side of the inner surface thereof. Therefore, the direction in which the regulating wall 71 protrudes can be made different for each reflux rod member 76 to be connected. Therefore, as shown in the figure, when the recirculation basket member 76 is connected so that every other regulating wall 71 is opposed, the reflux speed of the pachinko balls in the reflux bowl 70 can be increased. This is effective as a measure for increasing the circulation speed of the pachinko balls when the amount of stored balls in the pachinko island platform 1 is small.
[0038]
In recent years, there is a pachinko island platform 1 in which an island exchange device (not shown) is installed between the upper tanks 6 of adjacent pachinko island platforms 1 so as to exchange pachinko balls. In the table 1, in addition to the pachinko balls being lifted by the ball lifting device 5, pachinko balls also flow in from the adjacent pachinko island table 1, so that the upper tank 6 tends to be full. Accordingly, the pachinko balls in the upper tank 6 need to flow down as soon as possible. Even in such a case, in the reflux basket 70 according to the present embodiment, the reflux basket member 76 is connected as described above. This is advantageous in that the reflux rate of the pachinko balls in the reflux basket 70 can be increased.
[0039]
In the second embodiment, the connection structure of the reflux rod member 76 is shown by the fitting groove 77 and the fitting rail 78, but is not limited to this, and is fixed by bolts and nuts. It may be a thing. Such an embodiment (hereinafter referred to as a third embodiment) will be described below with reference to FIGS. 13 and 14. FIG. 13 is a front view showing the internal structure of the reflux basket 80 according to the third embodiment, and FIG. 14 is a perspective view showing an attachment state of the reflux basket member 86.
[0040]
In FIG. 13, the reflux rod 80 according to the third embodiment is configured by connecting a plurality of reflux rod members 86 provided with a regulating wall 81 having an arc upper surface 81 a on one side of the inner surface thereof. . That is, the reflux basket 80 is divided in the lateral direction to form a plurality of reflux bowl members 86 that can be attached to and detached from each other, and function as the reflux bowl 80 in a state where they are connected. An inlet port 86 a having an inlet 83 formed open is connected to the upper end of the reflux bar 86, and a discharge bottom 84 and a guide bottom surface 82 communicating with the outlet 84 are connected to the lower end of the reflux bar 86. The discharge port part 86b in which is formed is connected. The inner surface of the reflux basket 80, the circular arc upper surface 81a of the regulating wall 81, and the upper surface of the guide bottom surface 82 are covered with a sheet 85 made of synthetic resin (for example, ABS resin). To protect.
[0041]
As described above, the reflux bowl member 86 is formed to be detachable from each other. The structure for this will be described. As shown in FIG. 14, a connecting protrusion 87 having a connecting hole 87 a through which a bolt 88 is inserted is formed to project from the upper and lower centers of both side surfaces of the reflux rod member 86. Thus, the connecting hole 87a of the connecting protrusion 87 formed at the lower end portion of the upper reflux rod member 86 and the connecting hole 87a of the connecting protrusion 87 formed at the upper end portion of the lower reflux rod member 86 are overlapped. At the same time, bolts 88 are inserted into both connection holes 87a in this state and fastened with nuts 89, so that the upper reflux rod member 86 and the lower reflux rod member 86 are simply and properly connected. be able to. With this configuration, even when the regulation wall 81 and the guide bottom surface 82 are damaged due to long-term use, mixing of foreign substances, etc., the damaged regulation wall 81 and the guide bottom surface 82 are not replaced without replacing the entire reflux bowl 80. Since it is sufficient to replace only the reflux rod member 86 having the above, it is economical and the replacement work is facilitated. In addition to the above, the connection structure of the reflux bar member 86 includes a permanent magnet embedded in the connection part so that they are attracted to each other, or a metal fitting attached to the side surface of the reflux bar member 86. One that can be locked is conceivable.
[0042]
Further, in the second and third embodiments, the reflux rods 70 and 80 are divided in the lateral direction, and a plurality of the reflux rod members 76 and 86 each provided with the regulation walls 71 and 81 are provided. In this embodiment, when the damaged regulation walls 71 and 81 and the guide bottom surfaces 72 and 82 are replaced, it is necessary to replace the reflux rod members 76 and 86 together. In view of such circumstances, an embodiment (hereinafter, referred to as “fourth embodiment”) in which a damaged regulation wall or a guiding bottom surface itself can be replaced will be described below with reference to FIG. FIG. 15 is a perspective view of the reflux basket 90 according to the fourth embodiment as viewed from the front.
[0043]
In the figure, a reflux bar 90 according to the fourth embodiment includes a reflux bar body 91 formed in a vertically long rectangular tube shape, and a regulating wall having an arc upper surface 101 that can be detachably attached to the reflux bar body 91. The member 92 and the guide bottom member 96 are configured. That is, insertion holes 95 having shapes corresponding to the side surface shapes of the regulating wall member 92 and the guide bottom surface member 96 are formed at predetermined intervals on the front side and the back side of the reflux bowl main body 91. In this state, it functions as the reflux bar 90 in a state of being inserted from the front side so as to penetrate the regulation wall member 92 and the guide bottom surface member 96. On the front side of the regulation wall member 92, a handle 93 is formed so as to project when attached to / detached from the reflux bowl main body 91. The regulation wall member 92 is provided at a lower portion of the handle 93. A locking piece 94 is formed so as not to penetrate through to the back side when inserted into the back. Similarly, a handle 97 is formed to project from the front side of the guide bottom surface member 96, and a locking piece 98 is formed at a lower portion thereof. The inner surface of the reflux paddle body 91, the arc upper surface 101 of the regulating wall member 92, and the upper surface of the guide bottom surface member 96 are covered with a sheet 100 made of synthetic resin (for example, ABS resin), and flow down from the inlet 99. They are designed to protect them from the impact of the pachinko balls that come.
[0044]
As described above, in the present embodiment, the regulation wall itself can be detachably attached to the reflux bowl main body 91 as the regulation wall member 92, so that even when the damaged regulation wall is replaced, the reflux is returned. Since it is only necessary to replace the damaged restricting wall member 92 without replacing the entire ridge 90, it is economical and easy to replace.
[0045]
As mentioned above, although the structure and the effect | action of the pachinko island stand 1 which concern on embodiment were demonstrated, as shown in FIG.1 and FIG.3, according to this embodiment, it discharged | emitted from the several pachinko machine 2 arranged in a line. The used balls are configured to be circulated through the collection baskets 20 and 21, the storage tanks 8 and 9, the ball lifting device 5 and the supply basket 7, and the excess balls overflowing from the supply basket 7 are In the pachinko island platform 1 in which the reflux tanks 11 and 12 that return to the storage tanks 8 and 9 are provided, a plurality of regulating walls 50 that regulate the linear fall of the reflux balls are alternately arranged on the inner surfaces of the reflux baskets 11 and 12. The pachinko balls that have entered the reflux rods 11 and 12 from above are allowed to flow down in the reflux rods 11 and 12 because the upper surface of the restriction wall 50 is formed as an arcuate arc upper surface 55. When facing the inner surface alternately The flow is caused to flow down while colliding with the plurality of restriction walls 50, and the flow velocity is reduced. However, since the upper surface of the restriction wall 50 is an arcuate circular arc upper surface 55, the flow is reduced from above. Since the pachinko balls that flow down are guided to gradually weaken their velocity by the arc-shaped portion extending in the horizontal direction, they are allowed to flow downward again, so that the impact of the pachinko balls flowing down on the regulation wall can be reduced. It does not damage the regulation wall or generate noise. Furthermore, since the upper surface of the restriction wall 50 is an arcuate circular arc upper surface 55, the pachinko balls do not stay on the restriction wall 50, and the flow of the pachinko balls in the reflux rods 11 and 12 is made smooth. Can do.
[0046]
As shown in FIGS. 10 and 13, the reflux rods 70 and 80 are configured by connecting a plurality of reflux rod members 76 and 86 having at least one regulating wall 71 and 81. Thus, even when the damaged regulation walls 71 and 81 are replaced, it is only necessary to replace the reflux bar members 76 and 86 having the damaged regulation walls 71 and 81 without replacing the entire reflux bar 70 and 80. Economical and easy to replace. Furthermore, as shown in FIG. 12, the reflux speed of the pachinko balls flowing down in the reflux basket 70 can be changed by connecting the reflux basket member 76 in consideration of the direction in which the regulation wall 71 protrudes.
[0047]
Further, as shown in FIG. 15, the restriction wall 92 can be detachably attached to the reflux bar 90 so that the entire reflux bar 90 can be replaced even when the damaged regulation wall 92 is replaced. In addition, since only the damaged regulating wall member 92 needs to be replaced, the replacement work is economical and easy.
[0048]
【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 through a collection basket, a storage tank, a ball lifting device, and a supply basket. In a pachinko island platform that is configured to be used and is provided with a recirculation reed for recirculating surplus balls overflowing from the replenishment reed to the storage tank, the recirculation reed is a linear drop of the recirculation balls flowing down inside In order to regulate the flow rate, a plurality of reflux rod members each having a regulating wall projecting toward one side of the inner surface are connected to each other, and the upper surface of the regulating wall is formed in an arc shape so that the plurality of refluxing members are formed. When connecting the eaves member, by changing the direction in which the restriction wall protrudes for each connected recycle eaves member, the interval between the upper and lower directions of the restriction wall where the recirculation balls flowing down the inside alternately collide with each other. To connect differently Since it was made possible to reduce the impact on the regulation wall when the pachinko ball flows down in the reflux bowl, it does not damage the regulation wall or generate noise. Thus, the pachinko balls do not stay on the surface, and the pachinko balls in the reflux basket can flow smoothly.
[0049]
In addition, when the plurality of reflux rod members are connected, the restriction in which the reflux balls flowing down inside alternately collide with each other by changing the direction in which the restriction wall protrudes for each of the reflux rod members to be connected. Since the wall can be connected with different vertical intervals, it is not necessary to replace the entire recirculation basin even when replacing a damaged regulating wall, making it economical and easy to replace. It is possible to change the reflux speed of the pachinko balls flowing down in the reflux basket.
[0050]
Further, since the regulation wall can be detachably attached to the reflux basin, it is not necessary to replace the entire reflux basin even when the damaged regulation wall is replaced, and it is economical and easy to replace. . Furthermore, by opening an insertion port that can be inserted horizontally from the outside into the upper end portion of the reflux bowl, the insertion plate can be inserted into the insertion port to insert a new pachinko ball. After preventing the entry, the inspection and repair work can be performed in a state where the inside of the reflux basket is empty after waiting for the pachinko balls stored therein to be discharged.
[Brief description of the drawings]
FIG. 1 is a front view showing an internal structure of a pachinko island stand.
FIG. 2 is a perspective view of the ball lifting device and the reflux basket box as viewed from the front.
FIG. 3 is a front view showing the internal structure of the priority reflux basket according to the present embodiment.
FIG. 4 is a front view showing an internal state of the pachinko island stand when the amount of stored balls is small.
FIG. 5 is a front view showing the operation of the priority reflux basket according to the present embodiment.
FIG. 6 is a front view showing the operation of a conventional priority reflux tank.
FIG. 7 is a front view showing the internal state of the pachinko island stand when the amount of stored balls is large.
FIG. 8 is a front view showing the operation of the priority reflux basket according to the present embodiment.
FIG. 9 is a front view showing the operation of a conventional priority reflux tank.
FIG. 10 is a front view showing the internal structure of the reflux basket according to the second embodiment.
FIG. 11 is a perspective view showing an attached state of the reflux rod member.
FIG. 12 is a front view showing the operation of the priority reflux basket according to the second embodiment.
FIG. 13 is a front view showing the internal structure of the reflux basket according to the third embodiment.
FIG. 14 is a perspective view showing an attached state of the reflux rod member.
FIG. 15 is a perspective view of a reflux basket according to a fourth embodiment as viewed from the front.
[Explanation of symbols]
1 Pachinko island stand
2 Pachinko machines
4 Ball lifting device storage
5 Ball lifting device
7 Supply bowl
8 priority storage tanks
9 Non-priority storage tank
10 Reflux box
11 Priority Reflux
12 Non-priority reflux
19 Reflux hose
20 Upper recovery bowl
21 Upper recovery bowl
50 Regulatory wall
51 Guide bottom
60 reflux
61 Regulatory wall
62 Guide bottom
70 reflux
71 Restriction wall
72 Guide bottom
76 Refrigeration bowl member
77 Fitting groove
78 Mating rail
80 reflux
81 Restriction wall
82 Guide bottom
86 Refluxing bowl member
87 Connecting protrusion
88 volts
89 nuts
90 reflux
91 Reflux bowl body
92 Restriction wall member
95 Insertion hole
96 Guide bottom member

Claims (3)

The used balls discharged from a plurality of pachinko machines arranged in a row are configured to be circulated through a collection tank, a storage tank, a ball lifting device, and a supply tank, and the surplus overflowing from the supply tank In the pachinko island stand where a recirculation basket for returning balls to the storage tank is provided,
The reflux basket is constituted by connecting a plurality of reflux bowl members, each of which is provided with one regulating wall projecting to one side of the inner surface in order to regulate the linear fall of the reflux ball flowing down inside, The upper surface of the regulation wall is formed in an arc shape,
When connecting the plurality of reflux gutter member, with different collision 設方 direction of the restriction wall at any reflux gutter member and projecting direction of the restriction wall at reflux gutter member other than the arbitrary reflux gutter member the Rukoto be coupled Te, pachinko, characterized in that the refluxing ball flowing down the interior is to be able to be coupled with different vertical spacing of the restriction wall impinging alternately Isle of Eternal Youth.   The pachinko island stand according to claim 1, wherein the regulation wall can be detachably attached to the reflux basket.   The pachinko island stand according to claim 1 or 2, wherein an insertion port through which an insertion plate for preventing a pachinko ball from entering can be horizontally inserted from the outside is provided at an upper end portion of the reflux bowl.

Images