JP4351190B2 - Foreign matter discharge path - Google Patents

Description

  The present invention relates to a foreign matter discharge path configured to discharge foreign matter that has entered a ball passage.

  In an island facility where multiple pachinko machines are installed, there is a discharge basket in the lower area of each pachinko machine. This discharge basket has a required inclination, and is used to roll the game balls (pachinko balls) discharged from each pachinko machine to the lifting device installed on the island facility by rolling on the inclination. It is. Further, in the island facility, the foreign material such as coins and screws that have flowed into the discharge basket and fine dust attached to the game ball is removed at a position downstream of the discharge basket and immediately before the lifting device. A foreign matter discharge path is provided to prevent inflow into the lifter. As this foreign matter discharge path, for example, a foreign substance discharge path as described in Patent Document 1 has been proposed.

  A plurality of ball passages are arranged in parallel in the foreign matter discharge path of Patent Document 1. Each ball passage is formed with a bridge having a necessary minimum width over which a game ball can roll as a bottom surface, and partition walls having a substantially right triangle shape in side view standing on both sides of the bridge. An inclined portion is formed at a position that becomes the oblique side of the partition wall. The inclined portion is formed in a mountain shape in cross-sectional view perpendicular to the flow-down direction of the game ball in the ball passage. That is, the inclined portion is provided with inclined surfaces that are inclined downward from the upper edge of the inclined portion toward both wall surfaces of the partition wall on both sides of the center line that bisects the partition wall in the thickness direction. Further, in each ball passage, a gap is formed between adjacent bridges, and the lower portions of both partition walls forming each ball passage are opened to form a sorting passage.

A large number of game balls that have flowed down from the discharge basket to the foreign matter discharge path are diverted to the spherical passages on both sides of the partition walls by the inclined portions of the plurality of partition walls, and are introduced into the respective spherical passages and foreign matter. Aligned in the discharge channel. Furthermore, the game balls riding on the inclined part are distributed by the inclined surface of the inclined part. Then, the game ball rolls on the distributed slope and falls into one of the ball passages on both sides of the boarded partition wall. The game balls introduced into the ball passage are introduced into the lifting device while being kept aligned by the ball passage. Also, when foreign matter such as coins or screws enters the ball passage, the foreign matter passes through the sorting path from the gap formed between the bridge and the partition wall and is discharged out of the foreign matter discharge path. It is like that. Further, fine dust or the like adhering to the game ball falls from the game ball when the game ball slides against the partition wall, and is discharged out of the foreign matter discharge path from the sorting path.
Utility Model Registration No. 2563566

  By the way, it depends on the balance of the game ball on the inclined part whether the game ball riding on the inclined part of the partition wall rolls on which slope and falls into which of the ball paths on both sides of the partition wall. It is determined. For this reason, for example, there is a possibility that a game ball may fall into one certain ball passage from the inclined portions of both partition walls forming the ball passage. In this way, when game balls fall into one ball passage from both sides, the falling game balls come in contact with each other, or the chances of contact with game balls flowing down on the bridge increase. End up. As a result, the flow speed of the game ball in the ball passage decreases, and the transfer performance of the game ball decreases.

  The present invention has been made paying attention to such problems existing in the prior art, and an object thereof is to provide a foreign matter discharge path capable of preventing a decrease in the transportability of the game ball in the ball path. There is to do.

In order to solve the above-mentioned problems, the invention according to claim 1 is provided in an island facility where a gaming machine is installed, and a plurality of bridges arranged in parallel with a gap, A spherical passage in which a plurality of partition walls are provided on the inner side of a discharge passage body composed of provided side walls, and the bridge is located between adjacent partition walls and a gap is formed between the partition wall and the bridge. Are arranged in parallel, and the foreign substance discharge path is configured to discharge the foreign substance flowing down in the discharge path main body and entering the spherical path from the gap to the outside of the discharge path main body. An inclined portion that inclines upward from the bottom side along the flow-down direction of the game ball is formed on the game ball inlet side of the passage, and the upper edge of each inclined portion is directed in the same direction toward the thickness direction of the partition wall. In addition to forming a downwardly inclined guide surface, the play of the ball passage in the partition wall The entire edge rising from the bottom side along the flow-down direction of the game ball from the tip of the ball inlet side continuously inclines to the guide surface, and the inclined portion rises perpendicularly to the bottom. The ball breaker is connected to the downstream side of the game ball in the flow down direction, and a guide surface that is inclined in the same direction toward the thickness direction of the partition wall is formed continuously on each ball breaker and the guide surface. The gist is that the inclination angle of the surface and the guide surface is the same , and the non-guide surface side in the thickness direction is formed into a flat end surface at the upper edge of the inclined portion without being inclined .

According to a second aspect of the present invention, in the foreign matter discharge passage according to the first aspect, the foreign matter discharge passage according to the first aspect further includes a lid member that covers the upper portion of the discharge passage main body, and a lower surface of the lid member. The partition walls are arranged side by side, the lid member is attached to and detached from the discharge path body, and the partition walls are detachable from the discharge path body, and the lid member is assembled to the discharge path body. The gist is that the bridge is positioned between adjacent partition walls so that a plurality of spherical passages are defined in the discharge passage main body .

  According to the present invention, it is possible to prevent a decrease in transportability of game balls in a ball passage.

DESCRIPTION OF EMBODIMENTS Hereinafter, an embodiment in which the present invention is embodied in a foreign matter discharge path provided in an island facility will be described with reference to FIGS.
As shown in FIG. 1, an island facility 10 installed in a game shop (game room) is lined up with a plurality of pachinko gaming machines (game machines) P facing the back on the installed island platform S. It is installed. Between adjacent pachinko gaming machines P, a ball lending machine N that lends game balls to players by providing coins is installed. Further, in the island facility 10, a ball lifting device 11 is installed at the approximate center in the direction in which the pachinko gaming machines P are arranged (left and right in FIG. 1). The ball lifting device 11 lifts the game ball upward while polishing the game ball via a polishing lift (not shown). Further, the island facility 10 is provided with an island tank 12 on the upper side of the ball lifting device 11 that can store a large number of game balls lifted by the ball lifting device 11. In addition, the island facility 10 is provided with a ball supply basket 14 for distributing and supplying the game balls stored in the island tank 12 to the respective pachinko gaming machines P above the respective pachinko gaming machines P. Yes. The ball feeding rods 14 are provided on both the left and right sides of the ball lifting device 11 in an oblique state with the ball lifting device 11 side as an upstream end.

  On the other hand, in the lower area of each pachinko gaming machine P in the island facility 10, there is provided a discharge basket 15 for receiving and rolling and transferring game balls (such as out balls) discharged from each pachinko gaming machine P. ing. The discharge rods 15 are provided on both the left and right sides of the ball lifting device 11 in an oblique state with the ball lifting device 11 side as the downstream end. In addition, a ball collection tank 19 for collecting the game balls rolled and transferred by the discharge rod 15 is provided below the ball lifting device 11 of the island facility 10. Further, in the island facility 10, a foreign matter discharge path 20 is provided between the downstream end of the discharge basket 15 and the ball collection tank 19 to prevent foreign matters from entering the ball collection tank 19. The upstream end of the foreign matter discharge path 20 is connected to the downstream end of the discharge basket 15, while the downstream end of the foreign matter discharge path 20 is connected to the ball collection tank 19. The foreign matter discharge path 20 is provided on both the left and right sides of the sphere collection tank 19 in an oblique state with the sphere collection tank 19 side as a downstream end.

  Then, the game balls discharged from the pachinko gaming machine P pass through the discharge basket 15 and the foreign matter discharge path 20 and are discharged into the ball collection tank 19. At this time, due to a player's mischief or the like, from between the ball lending machine N and the pachinko gaming machine P to the back side of the pachinko gaming machine P, coins that have entered the discharge basket 15 or from the pachinko gaming machine P Screws that have come off and enter the discharge bowl 15 and foreign matters such as fine dust adhering to the game ball B are discharged to the outside of the foreign matter discharge passage 20 while flowing down the foreign matter discharge passage 20. Then, the game ball B released into the ball collection tank 19 is taken into the ball lifting device 11 and is transported to the island tank 12. Further, the game balls lifted to the island tank 12 are distributed and supplied from each ball supply basket 14 to each pachinko gaming machine P through a plurality of ball distribution chutes (not shown).

  Next, the foreign matter discharge path 20 will be specifically described. 2 and 3, the direction in which the game ball B flows down from the upstream side to the downstream side of the foreign matter discharge path 20 is the flow-down direction of the game ball B. As shown in FIGS. 2 and 3, the foreign matter discharge path 20 is roughly composed of a discharge path main body 30 that forms an outline of the foreign substance discharge path 20 and a cover member C that covers the entire upper portion of the discharge path main body 30. Has been. First, the discharge path main body 30 will be described. As shown in FIG. 2, the discharge path main body 30 has a long outer shape, and side walls 32 are erected on both sides of a main body bottom portion 36 that forms the bottom of the discharge path main body 30. The side wall 32 is bent at a substantially right angle so that its upper side extends to the inside of the discharge passage main body 30, and a plurality of screw holes 32 a for screwing the cover member C are formed in the bent portion.

  With this configuration, the foreign matter discharge path 20 is configured so as to receive the game ball B that is guided to roll the discharge rod 15 in the state where it is installed on the island facility 10 and to roll and guide the game ball B to the ball collection tank 19 side. Can take. In addition, since the passage formed by the foreign matter discharge passage 20 is divided into two types of passages for each function, the two types of passages are referred to as a “rolling passage” and a “rectifying passage” for easy understanding. 2 and FIG. 3, “33” is assigned to the “rolling path” and “34” is assigned to the “rectifier path”. The rolling path 33 is a passage on the upstream side (the discharge basket 15 side) of the foreign matter discharge path 20, receives the game ball B that is guided to roll by the discharge basket 15, and flows down the game ball B to the rectifying path 34 side. Roll along the direction. On the other hand, the rectification path 34 is connected to the rolling path 33 and is a passage on the downstream side of the foreign matter discharge path 20 (on the side of the ball collection tank 19), and the rolling path 33 is rolled and guided in a messy state. The game balls B are straightened (aligned), and the game balls B are guided to roll along the flow-down direction in an aligned state on the ball collection tank 19 side. In the foreign matter discharge path 20 of the present embodiment, foreign matters are discharged when passing through the rectifying path 34.

  The main body bottom portion 36 includes a bottom portion of the rolling path 33 and a bottom portion of the rectifying path 34. The bottom of the rolling path 33 is formed by a flat bottom plate 31 that is installed between the side walls 32, and a mat M is laid on the bottom plate 31. On the other hand, the bottom of the rectifying path 34 is formed by laying a bottom forming member 39 and a mat M side by side along the flow-down direction on a pair of support members 35 laid between the side walls 32. Of the pair of support members 35, one support member 35 is provided immediately downstream of the bottom plate 31, and the other support member 35 is provided on the downstream end side of the foreign matter discharge path 20. As described above, by providing the support members 35 only on both ends of the rectifying path 34, the portion where the bottom forming member 39 is disposed in the rectifying path 34 (the lower surface part of the foreign matter discharge path 20) is opened. .

  As shown in FIG. 4, the bottom forming member 39 includes a plurality of long plate-like bridges 37, a pair of long plate-like positioning members 38 welded and fixed to both sides of the bridges 37, and a plurality of bridges. A long plate-like reinforcing plate 29 fixed to the center of the path 37 by welding is formed into a lever shape. In the pair of positioning members 38, recesses 38b are formed between the adjacent bridges 37 (seven in this embodiment). Further, on both sides and the center of each positioning member 38, screwing holes 38d for screwing the bottom forming member 39 to the support member 35 are formed.

  In the bottom forming member 39, a gap K is formed between the adjacent bridges 37. Note that the width of the gap K is set to be wider than the diameter of the game ball B and through which only one game ball B can pass. A plurality (seven in this embodiment) of gaps K are formed in the bottom forming member 39, and the arrangement site of the bottom forming member 39 of the discharge path main body 30 is open. For this reason, in the main body bottom portion 36 of the foreign matter discharge path 20, substantially the entire rectification path 34 penetrates in the vertical direction except for the bridge 37, and foreign matters are discharged out of the foreign matter discharge path 20 when passing through the rectification path 34. Is done.

  Next, the cover member C will be described. In FIG. 2, the first lid member 40 of the cover member C is not shown, and in FIG. 3, the first lid member 40 is indicated by a two-dot chain line. As shown in FIGS. 2 and 3, the cover member C includes a first lid member 40, a second lid member 41, and a third lid member 51.

  The first lid member 40 covers the rolling path 33 of the foreign matter discharge path 20, and the second lid member 41 and the third lid member 51 cover the rectifying path 34 of the foreign substance discharge path 20. Is. The first lid member 40 is formed in a flat plate shape. The entire second lid member 41 is formed of a synthetic resin material having self-lubricating properties such as nylon, polycarbonate, polyacetal, and the like. As shown in FIG. 5, the second lid member 41 includes a lid plate 42, four long plate-like first rectifying walls 43 integrally formed on the lower surface of the lid plate 42, and three sheets A long plate-shaped second rectifying wall 44 is formed. That is, the second lid member 41 is provided with two types of rectifying walls having different shapes of the first rectifying wall 43 and the second rectifying wall 44. The first rectifying wall 43 and the second rectifying wall 44 are covered so that the first rectifying walls 43 are located on both sides of the lid plate 42 and the first rectifying walls 43 and the second rectifying walls 44 are alternately arranged. It is provided on the plate 42. The intervals between the adjacent first rectifying walls 43 and the second rectifying walls 44 are all the same, and the interval is wider than the diameter of the game balls B, and is set to an interval at which the game balls B can pass in a row.

  As shown in FIGS. 5, 6 </ b> B, and 6 </ b> C, a first spherical breaker 43 a that extends vertically from the lower surface of the cover plate 42 is formed at the edge of the first rectifying wall 43. . Furthermore, a first inclined portion 43b is formed at the edge of the first rectifying wall 43. The first inclined portion 43b is continuously inclined downward from the lower end of the first spherical breaker portion 43a. On the other hand, at the edge portion of the second rectifying wall 44, a second spherical break portion 44a is formed that extends vertically from the lower surface of the lid plate 42. Further, a second inclined portion 44b is formed at the edge of the second rectifying wall 44. The second inclined portion 44b is continuously inclined downward from the lower end of the second spherical break portion 44a. In addition, a horizontal portion 44c extending horizontally from the second inclined portion 44b is formed at the edge of the second rectifying wall 44, and further downwardly inclined linearly from the horizontal portion 44c. A second inclined portion 44b is formed at the position. That is, the second rectifying wall 44 is formed with second inclined portions 44b on both upper and lower sides of the horizontal portion 44c, and the length of each second inclined portion 44b is shorter than the length of the first inclined portion 43b.

  As shown in FIG. 6C, the first rectifying wall 43 and the second rectifying wall 44 are arranged on the cover plate 42 so that the first spherical breaker 43a and the second spherical breaker 44a are displaced forward and backward. It is installed side by side. In addition, the first ball breaker 43a and the second ball breaker 44a are formed to have different lengths in the vertical direction, and the length in the vertical direction of the first ball breaker 43a is the second ball breaker. The part 44a is formed longer than the length in the vertical direction.

  Further, the first rectifying wall 43 and the second rectifying wall 44 are formed so that the inclination angles of the first inclined portion 43b and the second inclined portion 44b are different from each other. Here, in FIG. 6C, a straight line extending along the lower edges of the first rectifying wall 43 and the second rectifying wall 44 is defined as an imaginary line J. The angle formed between the imaginary line J and the extended line of the first inclined part 43b is the inclined angle θ1 of the first inclined part 43b, and between the imaginary line J and the extended line of the second inclined part 44b. Are formed as the inclination angle θ2 of the second inclined portion 44b. The inclination angle θ1 and the inclination angle θ2 are different. Due to the difference between the inclination angles θ1 and θ2, the first inclined portion 43b and the second inclined portion 44b are arranged along the parallel arrangement direction of the first and second rectifying walls 43 and 44. There is a difference in height. Specifically, the difference in height between the front end side of the first inclined portion 43b and the front end side of the second inclined portion 44b is such that the first and second inclined portions 43b and 44b are located on the lid plate 42 side relative to the front end side. It gradually becomes smaller toward the portion 44c. There is also a position where there is no difference in height between the two. Further, the difference in height between the horizontal portion 44c of the second rectifying wall 44 on the side of the cover plate 42, that is, the proximal end side of the first inclined portion 43b and the proximal end side of the second inclined portion 44b is the difference in height on the distal end side. Is bigger than. Since the horizontal portion 44c is formed between the upper and lower second inclined portions 44b of the second rectifying wall 44, a difference in height is also formed between the first inclined portion 43b and the horizontal portion 44c.

  As shown in a cross-sectional view taken along the line 7b-7b in FIG. 6B (FIG. 7B), the first and second ball breaking portions 43a and 44a are the lengths of the first and second rectifying walls 43 and 44, respectively. The sectional view in the direction is formed in a tapered shape. Here, let a pair of wall surface which opposes the thickness direction of the 1st and 2nd rectifying walls 43 and 44 be the right wall surfaces 43A and 44A as one wall surface, and the left wall surfaces 43B and 44B as the other wall surface. The first and second ball collapse parts 43a, 44a gradually widen from the right wall surface 43A, 44A side to the left wall surface 43B, 44B side from the distal end to the proximal end side of each of the ball collapse parts 43a, 44a. Inclined. And the guide surface A is formed in the site | part which inclined in the 1st and 2nd ball breaking parts 43a and 44a. That is, the guide surface A is formed to be inclined toward the thickness direction of the first and second rectifying walls 43 and 44.

  Here, a straight line that bisects the first and second rectifying walls 43 and 44 in the thickness direction is a bisector Q. Then, the guide surface A is inclined so as to widen from the position closer to the right wall surfaces 43A, 44A than the bisector Q toward the left wall surfaces 43B, 44B. That is, the guide surface A has more than half of the thickness of the first and second spherical breakers 43a and 44a (first and second rectifying walls 43 and 44). In addition, when a plane passing on the guide surface A is a virtual plane U and a plane passing through the right wall surfaces 43A and 44A is a virtual plane UA, an acute angle of angles formed between the virtual plane UA and the virtual plane U is Is defined as an angle θA. Then, since the guide surface A and the right wall surfaces 43A and 44A are formed along the virtual plane U and the virtual plane UA so as to form the angle θA, the guide surface A is an acute angle with respect to the right wall surfaces 43A and 44A. Are formed in the first and second ball breaking parts 43a, 44a. And in all the 1st and 2nd rectifying walls 43 and 44, the guide surface A inclines at the same angle to the same direction.

  On the other hand, the first and second inclined portions 43b and 44b are formed by the lengths of the first and second rectifying walls 43 and 44, as shown in the sectional view taken along the line 7a-7a in FIG. 6C (FIG. 7A). A cross-sectional view orthogonal to the vertical direction is formed in a tapered shape. The first and second inclined portions 43b and 44b are formed so as to be inclined downward from the right wall surfaces 43A and 44A toward the left wall surfaces 43B and 44B as they go downward from the upper edges thereof. And the guide surface G is formed in the site | part inclined in the upper edge of all the 1st and 2nd inclination parts 43b and 44b. That is, the guide surface G is formed so as to be inclined downward toward the thickness direction of the first and second rectifying walls 43 and 44 as it goes downward from the upper edges of the inclined portions 43b and 44b.

  The guide surface G is inclined downward from the position closer to the right wall surfaces 43A and 44A than the bisector Q to the left wall surfaces 43B and 44B. That is, the guide surface G has more than half the thickness of the first and second inclined portions 43b and 44b (first and second rectifying walls 43 and 44). In addition, when a plane passing on the guide surface G is a virtual plane V and a plane passing through the right wall surfaces 43A and 44A is a virtual plane VA, an acute angle of angles formed between the virtual plane VA and the virtual plane V is Is defined as an angle θV. Then, since the guide surface G and the right wall surfaces 43A and 44A are formed along the virtual plane V and the virtual plane VA so as to form the angle θV, the guide surface G is an acute angle with respect to the right wall surfaces 43A and 44A. Are formed in the first and second inclined portions 43b and 44b. And in all the 1st and 2nd rectification walls 43 and 44, all the guide surfaces G incline at the same angle to the same direction. The horizontal portion 44c is also formed with a guide surface G that is inclined downward from the right wall surface 43A, 44A side to the left wall surface 43B, 44B side as it goes downward from its upper edge. Moreover, as shown in FIG. 5, the 1st and 2nd inclined part 43b, 44b is connected with the 1st and 2nd spherical breaker part 43a, 44a, respectively. And the guide surface A is continuously formed in the 1st and 2nd ball breaking parts 43a and 44a by the guide surface G. FIG.

  Next, the third lid member 51 will be described. As shown in FIGS. 2 and 3, the entire third lid member 51 is made of a synthetic resin material having self-lubricating properties such as nylon, polycarbonate, polyacetal, and the like. As shown in FIG. 9, the third lid member 51 includes a lid plate 52 and seven guide walls 53 integrally formed on the lower surface of the lid plate 52. All the intervals between the adjacent guide walls 53 are the same. The interval between the adjacent guide walls 53 is the same as the interval between the adjacent first rectifying walls 43 and the second rectifying walls 44. Further, the interval between the adjacent guide walls 53 is wider than the diameter of the game balls B, and is set to an interval at which the game balls B can pass in one row.

  In order to form the foreign matter discharge path 20 from the discharge path main body 30 and the cover member C having the above configuration, first, as shown in FIG. 3, a mat M is laid on the bottom plate 31, and the mat M is attached to the bottom plate. Fix to 31. Subsequently, both positioning members 38 of the bottom forming member 39 are supported on the pair of support members 35, and each positioning member 38 is screwed to the support member 35 by a screwing hole 38 d. Then, all of the plurality of bridges 37 and the pair of positioning members 38 are assembled between the side walls 32 by one operation of assembling the bottom forming member 39 to the support member 35. Subsequently, the mat M is laid on the other support member 35 on the downstream side of the bottom forming member 39, and the mat M is fixed to the support member 35.

  As a result, the rolling path 33 including the mat M, the bottom forming member 39 and the rectifying path 34 including the mat M are formed, and the bottom of the main body 36 is formed from the bottom of the rolling path 33 and the bottom of the rectifying path 34. Is configured. The main body bottom portion 36 is provided with positioning members 38 so that concave portions 38b are provided at a plurality of locations. The discharge path main body 30 is constituted by the main body bottom 36 and the side wall 32 erected from the main body bottom 36. Note that the upper surface of the mat M of the rolling path 33 is positioned above the upper end of each bridge 37, and the upper end of each bridge 37 is positioned above the upper surface of the mat M of the rectifying path 34. And the height difference is formed in the discharge channel main body 30 as it goes from the upstream side to the downstream side. That is, the height difference between the upper surface of the mat M of the rolling path 33 and the upper end of each bridge 37, or the height difference between the upper end of each bridge 37 and the upper surface of the mat M of the rectifying path 34 may be reversed. The height of each member is set so as not to exist. As a result, the height difference is reversed due to the manufacturing error of the mat M of the rolling path 33, the bridge 37, or the mat M of the rectifying path 34, the assembly error, etc., and the game ball B may be clogged. Is prevented.

  Subsequently, the first lid member 40, the second lid member 41, and the third lid member 51 are each placed on the bent portion above the side wall 32. When the second lid member 41 is assembled to the discharge path main body 30, the first and second inclined portions 43 b and 44 b are inserted into the concave portions 38 b of the positioning member 38. Thereafter, the screw 60 is fixed to the screw hole 32a through the first lid member 40, the second lid member 41, and the third lid member 51. Then, the entire upper portion of the discharge path main body 30 is covered with the first lid member 40, the second lid member 41, and the third lid member 51. As a result, the cover member C is assembled to the discharge path main body 30, and the foreign matter discharge path 20 including the discharge path main body 30 and the cover member C is configured.

  In the foreign matter discharge path 20 configured as described above, as shown in FIG. 2, guide walls 53 are connected to the downstream side of the first and second rectifying walls 43 and 44 in the discharge path main body 30. It is installed. Further, part of the free ends of the first and second inclined portions 43b, 44b of the first and second rectifying walls 43, 44 are respectively inserted into the recesses 38b of the positioning member 38, and the first and second rectifying walls 43 are inserted. , 44 are restricted from moving in the lateral direction. Further, in the first and second rectifying walls 43 and 44, a part of the free ends of the first and second inclined portions 43b and 44b enter the inside of the gap K, and the remaining free ends that do not enter the inside of the gap K. Is located above the gap K. Further, the guide wall 53 has all of its free ends positioned above the gap K.

  A plurality of first and second rectifying walls 43 and 44 serving as partition walls and a plurality of guide walls 53 serving as partition walls are arranged in parallel inside the discharge passage body 30, and the first and second rectifying walls are provided. The inside of the discharge path main body 30 is partitioned by 43 and 44 and the guide wall 53. Specifically, the inside of the discharge passage body 30 is partitioned into a plurality of sections by the first rectifying wall 43 and the downstream guide wall 53, and the second rectifying wall 44 and the downstream guide wall 53. The inside of the discharge passage body 30 has one bridge 37 as a bottom surface, and the first rectifying wall 43 and the downstream guide wall 53 and the second rectifying wall 44 and the downstream guide wall 53 are connected to the bridge. A plurality of ball passages 56 (six rows in the present embodiment) are provided side by side as walls on both sides of the passage 37. That is, in the discharge channel main body 30, the bridge 37 is located between the adjacent first rectifying wall 43 and the second rectifying wall 44 and between the adjacent guide walls 53. Each spherical passage 56 includes a plurality of bridges 37 arranged in parallel with a gap K between each other, first and second rectifying walls 43 and 44 arranged in parallel at a predetermined interval, and a guide wall 53. It is formed by combining so as to be positioned alternately.

  A game ball introduction port 56 a of a ball passage 56 that opens to the upstream side in the flow direction of the game ball B is formed at a position that becomes the upstream end of the rectifying passage 34. In the first and second rectifying walls 43 and 44, first and second inclined portions 43b and 44b are provided on the game ball introduction port 56a side. The first and second inclined portions 43b and 44b are inclined upward from the main body bottom 36 side as the bottom along the flow direction of the game ball B.

  Further, as shown in FIG. 8, the guide surfaces G at the upper edges of the first and second inclined portions 43 b and 44 b are formed to be inclined downward in the thickness direction of the first and second rectifying walls 43 and 44. ing. Specifically, each guide surface G is inclined downward toward one (left in FIG. 8) of the bridges 37 on both sides adjacent to the first and second inclined portions 43b and 44b. Is formed. That is, the first and second inclined portions 43b and 44b are inclined downward from the upper end edges of the first and second inclined portions 43b and 44b so as to go to the bridge 37 adjacent to the left wall surfaces 43B and 44B. .

  Furthermore, as shown in FIG. 2, the first and second ball breaking portions 43 a and 44 a are connected to the downstream side in the flow direction of the first and second inclined portions 43 b and 44 b. Moreover, the 1st and 2nd ball breaking parts 43a and 44a have stood up so that it may make perpendicular | vertical with respect to the main body bottom part 36 as a bottom part. And the 1st ball breaking part 43a and the 2nd ball breaking part 44a are displaced by the front-back alternately along the flow-down direction. That is, the 1st ball breaking part 43a is located in the flow direction front side rather than the 2nd ball breaking part 44a. Further, as shown in FIG. 8, the guide surfaces A of the first and second spherical breakers 43 a and 44 a are formed to be inclined toward the thickness direction of the first and second rectifying walls 43 and 44. . Specifically, each guide surface A is widened toward one (left in FIG. 8) of the spherical passages 56 on both sides adjacent to the first and second spherical breakers 43a and 44a. Inclined. That is, the first and second ball breaking parts 43a, 44a are balls whose left wall surfaces 43B, 44B face the inside of the spherical passage 56, and whose one bridge bridge (the left side in FIG. 8) forms the bottom surface. It inclines so that it may go to the center of the channel | path 56. FIG.

  Each ball passage 56 is formed such that a plurality of game balls B can flow down in a state of being aligned in a line in the flow-down direction. Further, as shown in FIG. 9, in each ball passage 56, between each bridge 37, the first rectifying wall 43, the second rectifying wall 44, and the guide wall 53 located on the side of the bridge 37. Each has a gap T formed therein. Further, the passage width of each ball passage 56 is such that the game ball B forms a ball passage 56 on the wall surface of one of the adjacent first rectifying wall 43 and the second rectifying wall 44 or the adjacent guide wall 53. It is set so that a gap Y is formed between the other wall surface and the game ball B when flowing down on the bridge 37 while sliding.

  On the other hand, in the foreign matter discharge path 20 having the above configuration, the screws 60 are removed from all the cover members 40, 41, 51, and all the cover members 40, 41, 51 are assembled from the discharge path main body 30, thereby removing the cover member C. The assembly can be removed from the discharge passage main body 30. That is, since all the lid members 40, 41, 51 are detachable from the discharge path main body 30, the cover member C is formed to be detachable from the discharge path main body 30. Further, the bottom forming member 39 can be detached from the support member 35 by releasing the screwing to each support member 35. The direction in which the bottom forming member 39 is assembled is the same as the direction in which all the lid members 40, 41, 51 are assembled from the discharge path main body 30.

  Now, when the foreign substance discharge path 20 having the above-described configuration is provided in the island facility 10, a large amount of the game balls B flowing down from the discharge basket 15 enter the foreign substance discharge path 20. A large amount of game balls B roll down on the mat M of the rolling path 33, and then roll and transfer to the rectifying path 34. The rectifying path 34 contacts the first and second inclined portions 43b and 44b. To do. Then, a large amount of game balls B are diverted and rectified by the first and second inclined portions 43b and 44b, and are introduced into the inside from the game ball introduction port 56a of the ball passage 56. At this time, since the first and second rectifying walls 43 and 44 have self-lubricating properties, the game ball B slides on the outer surfaces of the first and second rectifying walls 43 and 44. The stress generated when the game ball B comes into contact with the first and second rectifying walls 43 and 44 is received by the lid plate 42 from the base ends of the first and second rectifying walls 43 and 44 and is free. It is received by the end positioning member 38.

  When the game ball B flows down in multiple stages, the upper game ball B goes up the first and second inclined portions 43b and 44b. Then, as shown in FIG. 8, most of the game balls B are bridges on both sides adjacent to the first and second inclined portions 43b and 44b (first and second rectifying walls 43 and 44) by the guide surfaces G. It is guided so as to incline toward the bridge 37 on the left side of the road 37. That is, most of the game balls B are guided so as to incline toward the bridge 37 adjacent to the left wall surfaces 43B, 44B of the first and second rectifying walls 43, 44. As a result, the game ball B riding on the first and second inclined portions 43b and 44b has the left wall surfaces 43B and 44B out of the ball passages 56 located on both sides of the first and second inclined portions 43b and 44b. It falls toward the ball passage 56 facing the ball passage 56. That is, most of the game balls B riding on the first and second inclined portions 43b and 44b are guided by the guide surface G so as to fall in the same direction.

  Furthermore, the game ball B that has climbed up the first and second inclined portions 43b and 44b contacts the first and second ball breaking portions 43a and 44a. At this time, as shown in FIG.6 (c), the adjacent 1st ball breaking part 43a and the 2nd ball breaking part 44a have shifted position back and forth along the said flow-down direction. For this reason, when the game ball B contacts the both ball breaking parts 43a and 44a at the same time, the position where both the game balls B fall can be displaced forward and backward along the flow-down direction.

  The game ball B that has contacted the first and second ball breakers 43a and 44a is located on the left of the ball passages 56 adjacent to the first and second rectifying walls 43 and 44 by the guide surface A. Guided to tilt towards In other words, most of the game balls B are guided such that the left wall surfaces 43B and 44B face the ball passage 56 and the left bridge 37 faces the ball passage 56 forming the bottom surface, and the ball passage 56 is left as it is. Fall towards As a result, the game ball B that climbs the first and second rectifying walls 43 and 44 falls toward the ball passage 56 where the left wall surfaces 43B and 44B face the ball passage 56 by the guide surface G and the guide surface A, respectively. To be guided. That is, most of the game balls B that have contacted the first and second ball breakers 43a and 44a are guided by the guide surface A so as to fall in the same direction.

  Among the game balls B, there are game balls B that are not guided by the guide surface G so that the left wall surfaces 43B and 44B fall into the ball passage 56 facing the ball passage 56 in the present embodiment. . In this case, as shown in FIG. 6C, the first inclined portion 43b and the second inclined portion 44b adjacent to each other have different inclination angles θ1 and θ2, and the first and second rectifying walls 43 and 44 are arranged side by side. In the installation direction, there is a portion where a height difference is formed. This height difference is such that the base end side of the first and second rectifying walls 43, 44 is larger than the distal end side of the horizontal portion 44 c of the second rectifying wall 44. Due to the difference in height between the first inclined portion 43b and the second inclined portion 44b, the fall height of the game ball B from the first inclined portion 43b and the fall height of the game ball B from the second inclined portion 44b. To be different. Therefore, even if the game ball B falls from the first and second inclined portions 43b and 44b on both sides of one ball passage 56, the height at which both game balls B fall toward the ball passage 56 is high. Are less likely to be the same.

  Further, among the game balls B, there is a game ball B which is not guided by the guide surface A so that the left wall surfaces 43B and 44B fall into the ball passage 56 facing the ball passage 56 in the present embodiment. . In this case, the adjacent first and second spherical breakers 43a and 44a are displaced forward and backward along the flow-down direction. For this reason, even if the game ball B falls from the first and second ball breakers 43a and 44a on both sides of one ball passage 56, the position where both the game balls B fall is set in the flow direction. The position can be shifted back and forth along.

  As shown in FIG. 9, the game ball B introduced into the ball passage 56 is guided downstream in the flow-down direction by the guide wall 53 while maintaining the aligned state. Within each ball passage 56, the game ball B rolls on the bridge 37 while sliding on the right wall surfaces 43 A and 44 A, the left wall surfaces 43 B and 44 B on both sides of the bridge 37, and the wall surfaces of the guide wall 53. For this reason, the fine dust adhering to the game ball B is peeled off from the game ball B by sliding contact with each wall surface. The fine dust passes through the gap T and is discharged from the gap K to the outside of the foreign matter discharge path 20. Thereafter, the game ball B rolls on the mat M of the rectifying path 34 and is then collected in the ball collection tank 19.

  In addition, a large amount of game balls B are constantly in contact with and sliding on the first rectifying wall 43, the second rectifying wall 44, and the guide wall 53. Therefore, the first rectifying wall 43, the second rectifying wall 44, and the guide wall 53 are formed so that the game ball B can slide on the outer surface, and the generated stress can be received by the lid members 41, 51. Even if formed, the first rectifying wall 43, the second rectifying wall 44, and the guide wall 53 need to be replaced due to their service life being exceeded. Here, the first and second rectifying walls 43 and 44 are integrally formed with the second lid member 41, and the guide wall 53 is integrally molded with the third lid member 51. The second lid member 41 and the third lid member 51 are fixed to the side wall 32 with screws 60 and assembled to the discharge path main body 30.

  Further, the first rectifying wall 43, the second rectifying wall 43, and the guide wall 53 are not fixed to the main body bottom portion 36 of the discharge passage main body 30 by screws or the like, and are also assembled to the side wall 32. It is not done. Therefore, the screw 60 is removed from the screw hole 32a, and the second lid member 41 and the third lid member 51 are simply assembled upward. It can be detached from the main body 30. Moreover, the first and second rectifying walls 43 and 44 are all integrally formed with the second lid member 41, and the guide walls 53 are all integrally formed with the third lid member 51. For this reason, all of the first and second rectifying walls 43, 44 and the guide wall 53 are removed from the discharge path main body 30 by only one operation of disassembling the second lid member 41 and the third cover member 51 from the discharge path main body 30. Can be removed from the group.

  Then, another second lid member 41 and another third lid member 51 are newly assembled to the discharge path main body 30, and each lid member 41, 51 is screwed to the side wall 32 with a screw 60. New first and second rectifying walls 43 and 44 and a new guide wall 53 can be provided in the discharge passage main body 30. That is, the first and second rectifying walls 43 and 44 and the guide wall 53 are attached to and detached from the discharge path main body 30 by attaching and detaching the second lid member 41 and the third lid member 51 to the discharge path main body 30. And the foreign matter discharge path 20 can be assembled.

  Further, the cover member C can be divided into three lid members 40, 41, 51, and can be divided into first and second rectifying walls 43, 44 and a guide wall 53. Accordingly, by disassembling only the second lid member 41 from the discharge path main body 30, only the first and second rectifying walls 43 and 44 can be detached from the discharge path main body 30. On the other hand, it is naturally possible to detach only the guide wall 53 from the discharge path main body 30 by assembling the third lid member 51 from the discharge path main body 30. Then, another second lid member 41 or a third lid member 51 is newly assembled to the discharge passage main body 30 and is screwed to the side wall 32 with a screw 60. The 2nd rectification walls 43 and 44 or the guide wall 53 can be provided.

  In addition, when the coin that falls to the back side of the pachinko gaming machine P and enters the foreign matter discharge path 20 from the discharge rod 15 rides on the first and second inclined portions 43b and 44b while the state thereof is substantially horizontal, After the coins are locked to the first and second ball breaking portions 43a and 44a, they fall into the inclined ball passage 56 due to the height difference between the first and second inclined portions 43b and 44b. Then, the coins are discharged out of the foreign matter discharge path 20 from the gap K through the gap Y and the gap T formed between the game ball B and the first rectifying wall 43 or the second rectifying wall 44. On the other hand, when the aspect of the coin is almost upright, the coin is left as it is through the gap Y and the gap T formed between the game ball B and the first rectifying wall 43 or the second rectifying wall 44. To the outside of the foreign matter discharge path 20.

According to the foreign matter discharge path 20 of the above embodiment, the following effects can be obtained.
(1) A guide surface G inclined downward in the same direction toward the thickness direction of the first and second rectifying walls 43 and 44 is formed on the upper edges of the first and second inclined portions 43b and 44b. Therefore, the game ball B riding on the first and second inclined portions 43b and 44b is guided by the guide surface G so as to roll downward in the same direction. That is, most of the game balls B riding on the first and second inclined portions 43b and 44b are one (left) of the bridges 37 adjacent to the first and second inclined portions 43b and 44b. 37 falls into the ball passage 56 forming the bottom surface. Therefore, the game balls B are prevented from falling from both the first rectifying wall 43 (partition wall) and the second rectifying wall 44 (partition wall) forming the ball passage 56 in each ball passage 56. The As a result, it is possible to reduce the chance of contact between the game balls B that have fallen into the ball passage 56 and the number of contact between the game ball B that flows down on the bridge 37 and the game ball B that has dropped. It is possible to prevent the transportability of the 56 game balls B from being lowered.

  (2) The guide surface G has more than half the thickness of the first and second rectifying walls (partition walls) 43 and 44. Therefore, it is possible to easily exhibit the function of the guide surface G that causes the game ball B riding on the first and second inclined portions 43b and 44b to roll down in the same direction.

  (3) On the downstream side in the flow direction of the first and second inclined portions 43b, 44b, first and second spherical breakers 43a, 44a are connected, and the first and second spherical breakers 43a, 44a are connected to each other. The guide surface A is formed continuously with the guide surface G. And the guide surface A is formed so that it may incline in the same direction toward the thickness direction of the 1st and 2nd rectifying walls 43 and 44 similarly to the guide surface G. For this reason, the game ball B that has contacted the first and second ball breakers 43a and 44a is guided by the guide surface A so as to roll in the same direction. That is, most of the game balls B that have contacted the first and second ball breakers 43a, 44a are one (left) of the ball passages 56 adjacent to the first and second ball breakers 43a, 44a. Roll toward 56. Therefore, the game balls B are prevented from falling from both the first rectifying wall 43 (partition wall) and the second rectifying wall 44 (partition wall) forming the ball passage 56 in each ball passage 56. The As a result, it is possible to reduce the chance of contact between the game balls B that have fallen into the ball passage 56 and the number of contact between the game ball B that flows down on the bridge 37 and the game ball B that has dropped. It is possible to prevent the transportability of the 56 game balls B from being lowered.

  (4) The guide surface A is connected to the guide surface G. For this reason, the game ball B that has not been partitioned in the direction in which the guide surface G is inclined downward can be guided again by the guide surface A. Therefore, by the cooperation of the guide surface A and the guide surface G, the game ball B is prevented from falling from the adjacent first and second rectifying walls (partition walls) 43 and 44 toward the ball passage 56 therebetween. Can do.

  (5) In the state where the plurality of first and second rectifying walls (partition walls) 43 and 44 are arranged side by side, the adjacent first sphere breaking portion 43a and the second sphere breaking portion 44a are arranged in the flow-down direction of the game ball B. Along the position, they are displaced. For this reason, the fall position of both game balls B which contacted the 1st ball breaking part 43a and the 2nd ball breaking part 44a can be misaligned back and forth. Therefore, even if the game balls B fall into one ball passage 56 from the first and second ball breakers 43a, 44a on both sides of the ball passage 56, the game balls B are concentrated and fall at the same position in the flow-down direction. Can be prevented. In addition, the game balls B that have fallen into the ball passage 56 can be inserted one by one into the game balls B that flow down on the bridge 37, which contributes to the prevention of deterioration in the transportability of the game balls B in the ball passage 56. can do.

  (6) In a state where a plurality of first and second rectifying walls (partition walls) 43 and 44 are arranged side by side, the adjacent first inclined portion 43b and second inclined portion 44b have different inclination angles θ1 and θ2. Thus, a height difference is formed between the first inclined portion 43b and the second inclined portion 44b. For this reason, in the discharge path main body 30, the 1st inclination part 43b in which the game ball B rises easily and the 2nd inclination part 44b in which the game ball B does not rise easily exist. That is, unlike the case where the inclination angles θ1 and θ2 of the first and second inclined portions 43b and 44b are all the same, the position at which the game ball B of the first and second inclined portions 43b and 44b falls toward the ball passage 56 ( It becomes difficult for all the heights to be the same. Therefore, even if the game balls B fall into one ball passage 56 from the first and second inclined portions 43b and 44b on both sides of the ball passage 56 at the same time, the game balls B collide when they fall. Can be avoided, and can be dropped with a time lag in the row of game balls B flowing down on the bridge 37. As a result, the game balls B that have fallen into the ball passage 56 can be entered one by one into the game balls B that flow down on the bridge 37, which contributes to prevention of a decrease in the transportability of the game balls B in the ball passage 56. can do.

  (7) Two kinds of inclination angles are set, that is, the inclination angle θ1 of the first inclination portion 43b and the inclination angle θ2 of the second inclination portion 44b. Therefore, by arranging the first rectifying wall 43 and the second rectifying wall 44 so that the first inclined portion 43b and the second inclined portion 44b are alternately arranged, the adjacent first inclined portion 43b and second inclined portion 44b. The inclination angle can be varied. Therefore, even if three or more types of rectifying walls having different inclination angles of the inclined portions are not formed, the inclination angles of the adjacent inclined portions can be made different, and the manufacture and arrangement of the rectifying walls can be facilitated.

  (8) On the lid plate 42 of the second lid member 41, first and second rectifying walls 43 and 44 having a guide surface G and a guide surface A are integrally formed. For this reason, the 1st and 2nd rectification walls 43 and 44 provided with the guide surface G and the guide surface A can be provided in the discharge path main body 30 only by assembling the second lid member 41 to the discharge path main body 30. The foreign matter discharge path 20 can be easily formed.

In addition, you may change the said embodiment as follows.
In the embodiment, three or more types of rectifying walls may be provided, and three or more types of inclined portions having different inclination angles may be provided. At this time, it is preferable to arrange the rectifying walls so that the inclination angles of the adjacent inclined portions are different.

In the embodiment, the concave portion 38b in the positioning member 38 may be deleted and the free ends of the first and second inclined portions 43b and 44b may not be positioned.
-In embodiment, you may form the recessed part which can insert / extract the free end of 1st and 2nd inclination part 43b, 44b in the mat M other than the positioning member 38 of the bottom formation member 39. FIG.

In the embodiment, at least one of the rectifying walls 43 and 44 and the guide wall 53 may be integrally formed with the bottom forming member 39 (main body bottom portion 36).
In the embodiment, the first and second rectifying walls 43 and 44 are integrally formed on the second lid member 41, and the guide wall 53 is integrally molded on the third lid member 51. However, the following changes may be made. Good. That is, the second lid member 41 is configured to assemble separate rectifying walls 43 and 44 to the lid plate 42, and the third lid member 51 is configured to assemble a separate guide wall 53 to the lid plate 52. As an alternative, the separate first and second rectifying walls 43 and 44 and the guide wall 53 may be detachable from the discharge path body 30 simultaneously with the attachment and detachment of the cover plates 42 and 52 to the discharge path body 30.

  In the embodiment, the second lid member 41 and the third lid member 51 are integrated into a single lid member, and the first and second rectifying walls 43 and 44 and the guide wall 53 are integrated into the first lid member. A partition wall composed of the first and second rectifying walls 43 and 44 and the guide wall 53 may be formed.

In the embodiment, the first lid member 40, the second lid member 41, and the third lid member 51 may be integrated to form the cover member C as one member.
In the embodiment, the first rectifying walls 43 or the second rectifying walls 44 may be arranged side by side so that the inclination angles are the same.

In the embodiment, the first ball breaker 43a and the second ball breaker 44a may not be displaced forward and backward along the flow direction.
-In embodiment, you may make it the 1st ball breaking part 43a be located in the flow direction rear side rather than the 2nd ball breaking part 44a.

  In the embodiment, the first spherical breaker 43a is not connected to the first inclined part 43b, but the horizontal part is connected to the first inclined part 43b, and then the first spherical breaker 43a is connected to the horizontal part. In addition, the guide surface G and the guide surface A may not be provided continuously.

-In embodiment, it is not necessary to form the guide surface A in the 1st and 2nd ball breaking parts 43a and 44a.
In the embodiment, the guide surface G is formed so that one end thereof coincides with the bisector Q, and the guide surface G has half the thickness of the first and second inclined portions 43b and 44b. It may be formed. Further, the guide surface A is formed so that one end thereof coincides with the bisector Q, and the guide surface A is formed so as to have a half of the thickness at the first and second ball breaking portions 43a and 44a. May be.

  In the embodiment, the guide surface G is inclined downward toward the other side (right side in FIG. 8) of the bridges 37 adjacent to the first and second inclined parts 43b and 44b, that is, You may form so that it may incline and descend from the left wall surface 43B, 44B side to the right wall surface 43A, 44A side. In other words, the direction in which all the guide surfaces G are inclined downward may be reversed from the embodiment. In this case, the direction of inclination while the guide surface A is widened is also opposite to that of the embodiment.

  In the embodiment, the first lid member 40, the second lid member 41, and the third lid member 51 are transparent to allow the inside of the discharge path main body 30 to be seen through in the assembled state to the discharge path main body 30. Alternatively, it may be formed of a semitransparent synthetic resin material, and the entire cover member C may be formed to be transparent or translucent. At this time, the first to third lid members 40, 41, and 51 are preferably formed of a synthetic resin material having self-lubricating properties such as nylon, polycarbonate, and polyacetal. If comprised in this way, the inside of the discharge path main body 30 can be seen through through the cover member C in the state in which the cover member C is still assembled to the discharge path main body 30. Therefore, without removing the cover member C from the discharge passage main body 30, it is possible to visually recognize and grasp the dirt on the bridge 37, the deformation and wear of the first and second rectifying walls 43 and 44, and the like.

  In the embodiment, six rows are formed as the plurality of ball passages 56 in the discharge passage main body 30, but the number of the ball passages 56 is not limited to six rows, the number of bridges 37, the first and second rectifying walls 43. 44 and the number of guide walls 53 may be changed to change the number of ball passages 56 to, for example, four rows, five rows, eight rows, nine rows, ten rows, and the like.

In the embodiment, the main body bottom 36 is configured by the rolling path 33 and the rectification path 34, but the main body bottom 36 may be configured by only the rectification path 34.
Next, the technical idea that can be grasped from the above embodiment and other examples will be described below.

  (A) A plurality of bridges are provided in an island facility where a gaming machine is installed, and a plurality of bridges are formed inside a discharge passage main body including a bottom portion arranged in parallel with a gap and a side wall standing on the bottom portion. A partition wall is provided, and a plurality of spherical passages in which the bridge is located between adjacent partition walls and a gap is formed between the partition wall and the bridge are arranged in parallel, and flow down in the discharge channel body. A lid member that covers the top of the discharge path main body of the foreign substance discharge path configured to discharge the foreign matter that has entered into the spherical passage from the gap to the outside of the discharge path main body, A partition wall is integrally formed, and a plurality of inclined portions that are inclined upward from the bottom side along the flow-down direction of the game ball are formed on the game ball introduction port side of the ball passage in the plurality of partition walls, A lid member in which a guide surface that is inclined downward in the same direction is formed on an upper portion of the inclined portion.

( B ) The foreign matter discharge path according to claim 4 , wherein the plurality of partition walls are integrally formed with the lid member.
( C ) The partition wall includes a rectifying wall that includes the inclined portion and aligns the game balls in the flow-down direction, and a game ball that is positioned downstream of the rectification wall in the flow-down direction and is aligned by the flow control walls. It is comprised from the guide wall guided to the said flow direction downstream in the aligned state, The said baffle wall and the guide wall are arranged in parallel by the lower surface of another cover member, respectively, or the technical thought (b ). Foreign matter discharge path.

(D) the inclined portion is formed such that the inclination angle in the adjacent partition walls different inclination angles of the inclined portion, two have been set according to claim 1 to claim 4, the technical idea (b) And the foreign matter discharge passage according to any one of the technical ideas (c) .

( E ) The foreign matter discharge path according to claim 2 , wherein the ball breaking portion is disposed so as to be displaced forward and backward along the flow-down direction in adjacent partition walls.

The partially cutaway front view which shows the whole island facility and a part in island facility. The perspective view which shows the foreign material discharge path which deleted the 1st cover member and partially cut off the 3rd cover member. FIG. 3 is a sectional view taken along line 3-3 in FIG. 2. The top view which shows a bottom formation member. The perspective view which shows a 2nd cover member. (A) is a bottom view of the second lid member, (b) is a front view of the second lid member, and (c) is a side view of the second lid member. 7A is a sectional view taken along line 7a-7a in FIG. 6C, and FIG. 7B is a sectional view taken along line 7b-7b in FIG. 6B. FIG. 8 is a schematic cross-sectional view taken along line 8-8 in FIG. 2. FIG. 9 is a schematic cross-sectional view taken along line 9-9 in FIG. 2.

Explanation of symbols

  A ... Guide surface, B ... Game ball, G ... Guide surface, K ... Gap, P ... Pachinko game machine (game machine), T ... Gap, θ1, θ2 ... Inclination angle, 10 ... Island equipment, 20 ... Foreign material discharge path , 30 ... discharge channel main body, 32 ... side wall, 36 ... main body bottom (bottom), 37 ... bridge, 43 ... first rectifying wall (partition wall), 43a ... first ball breaking part, 43b ... first inclined part, 44 ... 2nd rectifying wall (partition wall), 44a ... 2nd ball breaking part, 44b ... 2nd inclination part, 53 ... Guide wall (partition wall), 56 ... Ball passage, 56a ... Game ball introduction port.

Claims (2)

A plurality of partition walls are provided inside the discharge channel main body, which is provided in an island facility where a gaming machine is installed, and which includes a bottom portion in which a plurality of bridges are arranged in parallel with a gap and a side wall erected on the bottom portion. Providing a plurality of spherical passages in which the bridge is located between adjacent partition walls and a gap is formed between the partition walls and the bridge, and flows down in the discharge passage main body to flow down the spherical passage. A foreign matter discharge path configured to discharge the foreign matter that has entered inside the discharge path main body from the gap,
In each partition wall, an inclined portion that is inclined upward from the bottom side along the flow direction of the game ball is formed on the game ball introduction port side of the ball passage, and the thickness direction of the partition wall is formed on the upper edge of each inclined portion Forming a guide surface that slopes downward in the same direction toward the same direction, and the entire edge that rises from the bottom side along the flow-down direction of the game ball from the tip of the game ball introduction port side of the ball passage in the partition wall is The ball breaker that continuously inclines to the guide surface and rises perpendicularly to the bottom is connected to the downstream side of the game ball in the flow-down direction. A guide surface that is inclined in the same direction toward the thickness direction is formed continuously with the guide surface, and the guide surface and the guide surface have the same inclination angle, and the upper edge of the inclined portion is non-guided in the thickness direction. Face side is inclined Foreign matter discharge passage formed in Rukoto no planar end surface. A lid member that covers the upper portion of the discharge path body; and the plurality of partition walls are arranged side by side on the lower surface of the lid member, and the plurality of partition walls are attached to and removed from the discharge path body. By attaching the lid member to the discharge path main body, the bridge is positioned between adjacent partition walls so that a plurality of spherical passages are formed in the discharge path main body. foreign matter discharge passage according to claim 1 which is a.

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