JP2010115520A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a game machine capable of preventing ball clogging in a branch chamber. <P>SOLUTION: The game machine includes a ball delivery device 90 and the branch chamber 70 provided with an inflow port 71 into which balls delivered from the ball delivery device 90 flow on the upper part. The branch chamber 70 is provided with a delivery path 72 for an upper tray communicated with the upper tray 6 and a delivery path 76 for a lower tray communicated with the lower tray 7 respectively. A drop port 73 serving as the entrance part of the delivery path 72 for the upper tray is provided facing right below the inflow port 71 at the upper part of the branch chamber 70. The delivery path 76 for the lower tray is provided at such a position that a ball rebounded by hitting balls accumulated at the drop port 73 of the delivery path 72 for the upper tray can flow in. The interval of the inflow port 71 at the upper part of the branch chamber 70 and the drop port 73 is set to such an interval dimension that the ball can flow in from the inflow port 71 even when the balls are jammed at the drop port 73. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

The present invention relates to a gaming machine such as a pachinko machine.

In a gaming machine, such as a pachinko machine, a ball delivery device and a branch chamber into which a ball delivered from the ball delivery device flows are arranged in the ball payout path. The branch chamber is provided with a ball passage for the upper plate that leads to the upper plate,
A passage opening of a ball passage for a lower plate that is located on one side of the upstream portion of the ball passage and communicates with the lower plate is provided. Then, the sphere delivered from the sphere delivery device and flowing into the branch chamber first flows into the upper plate ball passage and is paid out to the upper plate. The plate ball is full
Then, the sphere passage for the upper dish in the branch chamber is gradually filled with balls from the downstream side toward the upstream side. When a large number of spheres accumulate and fill the upper plate ball passage and become full, the balls flowing into the branch chamber are accumulated in the upper plate ball passage.
It bounces off the balls that have been piled up, flows into the ball path for the lower dish, and is paid out to the lower dish.

By the way, in the said conventional thing, the ball | bowl of the upper dish ball channel | path of a branch chamber may mutually mesh, or a ball | gum may mesh | engage with a channel | path wall and many spheres may accumulate excessively. Then, the flow of the ball is stopped and the ball becomes clogged.
There was a subject.

  In view of the above-described conventional problems, an object of the present invention is to provide a gaming machine that can prevent a clogged ball in a branch chamber.

In order to achieve the above object, the gaming machine according to the first aspect of the present invention is summarized as follows. Therefore, the sphere delivered from the sphere delivery device is dropped from the inlet at the upper part of the branch chamber to the entrance of the delivery path for the upper plate facing directly below it.
And is guided to the same plate delivery path to be paid out to the upper plate. When the upper plate ball is full and the ball stays at the entrance of the delivery path for the upper plate, the ball that has dropped from the inlet at the top of the branch chamber is excessively placed on the ball that stayed at the entrance.
Without depositing, it hits the ball that stayed at the entrance and bounces off, flows reliably into the lower plate delivery path, and is delivered to the lower plate. For this reason, the flow of a ball | bowl is stopped in a branch chamber, and the malfunction that a ball | bowl clogging generate | occur | produces is prevented.

Further, the gaming machine according to the second invention has a configuration as described in claim 2, and the entrance of the delivery path for the upper plate has a depth opening dimension and a width opening dimension, Dimensions with at least one opening dimension corresponding to the diameter dimension of the sphere
Is set to Therefore, it is further reduced that the sphere that has fallen from the inlet at the upper part of the branch chamber accumulates on the sphere that has remained at the inlet, and this is highly effective in preventing the occurrence of clogging.

  A gaming machine according to a third aspect of the present invention has the gist of the configuration as set forth in claim 3, and the lower tray delivery path is located at the left, right, front, Of each of the rear outer parts, the plurality of outer parts have side guide paths for guiding the spheres. Therefore, in the state where the ball stays at the entrance of the delivery path for the upper plate, the ball dropped from the inlet at the upper part of the branch chamber bounces off the ball staying at the entrance and leads to a plurality of side guides outside the entrance. It flows reliably on the road. For this reason, the accumulation of spheres at the entrance is further reduced, and the effect of preventing the occurrence of clogging is great.

  As described above, according to the present invention, even when the balls remain in the entrance of the delivery path for the upper plate, the balls that have fallen from the inflow at the upper part of the branch chamber are excessively accumulated at the entrance. Therefore, it is possible to flow into the lower plate delivery path and pay it out to the lower plate, so that the occurrence of clogging of the balls can be prevented.

It is a rear view which shows a pachinko machine as a gaming machine according to an embodiment of the present invention with a part broken away. It is a rear view which similarly shows the whole pachinko machine. It is a longitudinal cross-sectional view similarly based on the III-III line of FIG. It is a longitudinal cross-sectional view similarly based on the IV-IV line of FIG. It is a longitudinal cross-sectional view similarly based on the VV line of FIG. It is a longitudinal cross-sectional view which expands and similarly shows the relationship between the unit case upper part of a ball paying unit in the unit mounting part of a mechanism board, and a locking member. Similarly, it is a longitudinal sectional view showing an enlarged relationship between the lower engagement portion of the unit mounting portion and the lower engagement piece at the lower portion of the unit case. It is a cross-sectional view similarly based on the VIII-VIII line of FIG. It is a cross-sectional view based on the IX-IX line of FIG. It is a transverse cross section similarly based on the XX line of FIG. It is a longitudinal cross-sectional view which similarly shows the unit case of a ball delivery unit. It is explanatory drawing which partially fractures | ruptures and shows the state in which the locking member was similarly arrange | positioned with respect to a unit case in the attachment position. Similarly, the locking member is a partially broken view illustrating a state where the arrangement is switched to the detaching position. It is explanatory drawing which shows the state by which the ball stop member was similarly arrange | positioned in the ball stop position by the pressing member. It is a rear view which expands and shows the state where the rotary body was similarly assembled | attached to the rotary body storage chamber of the ball delivery unit. It is sectional drawing which similarly shows the assembly | attachment state of a rotary body and a payout motor. It is explanatory drawing which similarly shows the setting of the space | interval dimension between the indoor side opening end of the inflow port of a branch chamber, and the upper end opening part of the entrance of the delivery path for upper plates.

  Embodiments of the present invention will be described with reference to the drawings. 2 showing the pachinko machine from the back, FIG. 1 showing a partially broken view, FIG. 3 showing the section based on the III-III line in FIG. 1, FIG. 5 showing the section based on the VV line in FIG. 8, the pachinko machine 1 as a gaming machine is mounted on the front side of the outer frame 2 with a rectangular frame-shaped front frame 3 that can be opened and closed by a hinge function. .

  A glass frame having a glass door 4 that can be opened and closed is attached to the frame opening of the front frame 3, and a front plate 5 is attached so as to be openable and closable adjacent to the lower part of the glass frame. On the front surface of the front plate 5, an upper plate 6 capable of storing a sphere B is mounted. Further, a lower pan 7 capable of storing the sphere B is attached to the front lower portion of the front frame 3, and a handle device (not shown) for launching a sphere is attached to one side of the front lower portion of the front frame 3. .

  On the rear surface of the front frame 3, the base frame 10 is assembled in a fixed state at the peripheral edge of the frame opening. A game board 11 is detachably fitted in the frame of the base frame 10 and the periphery of the rear surface of the game board 11 is pressed by a mechanism plate 20 (also called a back set plate, a back mechanism plate, etc.). It is fixed. A ball guide rod (not shown) is assembled on the rear surface of the game board 11, and a back cover body 13 is assembled so as to be openable and closable so as to cover the ball guide rod. A main control board box 15 in which a main control board 16 is housed is mounted on the rear surface of the back cover body 13.

  The mechanism plate 20 that holds the periphery of the rear surface of the game board 11 is formed in a frame shape surrounding the back cover body 13, and is attached to one side of the base frame 10 on one side thereof so as to be openable and closable. The mechanism plate 20 is held in a closed state so as to be detachable from the base frame 10 by a stopper 12. When the mechanism board 20 is opened, the game board 11 is attached to and detached from the base frame 10, and the mechanism board 20 is closed so that the game board 11 is pressed against the base frame 10 and fixed. It has become. In the game area on the front surface of the game board 11, an accessory device, a symbol display device, and the like having a general winning port, a specific winning port, a gate port, and the like are arranged.

  A sphere tank 21 in which the sphere B is stored and a tank rail 22 connected to a supply port provided at a lower portion near one end of the sphere tank 21 are mounted on the upper rear surface of the mechanism plate 20. Yes. The tank rail 22 is formed in an inclined shape so that the spheres B flow from one side to the other side (from the left side to the right side in FIG. 1) while being aligned in two front and rear rows. It is a ball delivery unit. The sphere tank 21 and the tank rail 22 constitute a sphere supply unit of the present invention. On one side of the rear surface of the mechanism plate 20 (right side in FIG. 1), a unit mounting portion is provided adjacent to the ball delivery portion of the tank rail 22, and the unit mounting portion includes one unit constituting a ball dispensing device. A unit-shaped ball dispensing unit 51 is detachably mounted.

  As shown in FIGS. 5 and 7, the mechanism plate 20 has a lower engagement portion 28 that removably engages the lower portion of the ball dispensing unit 51 at the lower portion of the unit mounting portion. Projected in a letter shape. As shown in FIGS. 5 and 6, a support portion 29 is provided on the upper portion of the unit mounting portion, and a locking member 33 is assembled to the support portion 29.

  As shown in FIGS. 6 and 12, the locking member 33 is supported by the screw 31 and the long hole 32 so as to be slidable in the left-right direction, and its sliding stroke is limited. The one end position of the slide of the locking member 33 is a locking position where the ball dispensing unit 51 is locked in the mounted state. Further, as shown in FIG. 13, the other end position of the slide of the locking member 33 is a detachable position where the ball paying unit 51 can be detached. That is, as shown in FIGS. 6 and 12, the locking member 33 is formed with a flat plate-like locking portion 34 that is long in the lateral direction for locking the ball dispensing unit 51 in the mounted state. A plurality of (a pair of left and right) notch portions 35 for removing the ball payout unit 51 are formed in a notch shape.

  As shown in FIGS. 12 to 14, a ball stopper member 40 is mounted on the rear surface of the mechanism plate 20 so as to be positioned between the ball delivery portion of the tank rail 22 and the ball dispensing unit 51. The ball stopper member 40 includes a main body portion 40a having a spring storage portion, a ball stopper piece 41 extending downward from one side of the main body portion 40a, and an engagement recess 42 provided on the upper portion of the main body portion 40a. And an upper plate portion 44 forming an upper wall portion of the engaging recess 42 are integrally provided. The ball stopper member 40 is guided by a guide portion provided on the mechanism plate 20 and is assembled so as to be movable up and down.

  That is, as shown in FIG. 13, the ball stopper member 40 has a ball stopper position at which the ball stopper piece 41 enters the ball delivery portion of the tank rail 22 so that the ball of the ball delivery portion cannot be dropped. As shown in FIG. 12, the arrangement is switched to a retreat position where the balls of the ball delivery unit are retracted from the ball delivery unit of the tank rail 22 and can be supplied to the ball dispensing unit 51. Further, a return spring 45 that elastically holds the ball stopper member 40 in the retracted position between the spring storage portion of the main body portion 40a of the ball stopper member 40 and the spring receiving portion protruding from the rear surface of the mechanism plate 20. Is intervened.

  Also, on the rear surface of the mechanism plate 20, a pressing member 46 that is positioned above the upper plate portion 44 of the ball stopper member 40 and that switches the ball stopper member 40 between a ball stopper position and a retracted position is assembled. ing. The pressing member 46 can be rotated about a shaft 48 at the center thereof, and is formed in a substantially circular shape having a pressing release portion 47 formed of a cut surface on a part of the outer peripheral surface. Then, as shown in FIG. 12, when the pressing release portion 47 of the pressing member 46 is rotated so as to face downward and disposed at the non-pressed position, the ball retaining member 40 is moved by the elastic force of the return spring 45. The upper plate portion 44 is held at a retracted position where the upper plate portion 44 abuts against the press release portion 47. Further, as shown in FIG. 14, when the pressing member 46 is rotated by a predetermined angle about the shaft 48, the ball stopper member 40 is switched to the ball stopper position against the elastic force of the return spring 45. It has come to be.

  As shown in FIGS. 12 to 14, when the locking member 33 is switched between the locking member 33 and the ball locking member 40 from the locking position toward the detaching position, the locking member 33. Interlocking means for switching the ball stopper member 40 to the ball stopper position is provided in conjunction with the switching operation. In this embodiment, when the locking member 33 slides toward the attachment / detachment position, the locking member 33 slides on the lower surface of one end portion of the locking member 33 while contacting the lower surface of the engagement recess 42 of the ball stopper member 40. Thus, a downwardly inclined interlocking portion 36 is formed to push down the ball stop piece 41 against the elastic force of the return spring 45.

  In this embodiment, interlocking means is constituted by the interlocking portion 36 of the ball stopper member 40. In this embodiment, an upwardly inclined interlocking portion 43 corresponding to the interlocking portion 36 of the locking member 33 is also formed on the lower surface of the engaging recess 42 of the ball stopper piece 41. Further, an opening window 20a is formed in the unit mounting portion of the mechanism plate 20 between the portion where the lower engaging portion 28 is provided and the portion where the locking member 33 is assembled (FIGS. 6 and 7). reference).

  As shown in FIGS. 1 and 5, a ball dispensing unit 51 that is detachably mounted on a unit mounting portion of the mechanism plate 20 includes a unit case 52, a rotating body 90 assembled to the unit case 52, and a dispensing motor 81. , First and second passage switching members 100 and 110, various detectors and the like. As shown in FIGS. 5 to 7, the unit case 52 is configured by separably connecting three parts of a base body 53, an intermediate partition body 54, and a cover body 56 that are respectively molded by synthetic resin injection molding. Has been. Further, in this embodiment, a plurality (a pair of left and right) upper engagement pieces 58 and lower engagement pieces 59 project from the upper and lower ends of the intermediate partition 54. Then, the lower engagement piece 59 is inserted from obliquely above the lower engagement portion 28 of the unit mounting portion, and the unit case 52 is erected toward the unit mounting portion with this portion as a fulcrum, so that the upper engagement piece 58 is detached. Is inserted into the removal hole of the locking member. Thereafter, the ball dispensing unit 51 is locked in the mounted state with respect to the unit mounting portion by sliding the locking member to the locked position.

  As shown in FIG. 7, two rows of front and rear spherical passages are formed in the unit case 52 with the intermediate partition 54 as a boundary. Further, as shown in FIG. 11, in the unit case 52, there are an upper ball passage 60, a rotating body storage chamber 61, a prize ball passage 63, and a ball rental passage 64 that constitute a ball passage from the upper part toward the lower part. The branch passage 70 having the dispensing passage 65, the upper dish delivery path 72, and the lower dish delivery path 76 is communicated in this order, and in the intermediate partition 54, each of the passages is divided into two front and rear rows. Yes. Further, an upper bulb passage 67 is formed in communication with the upstream portion of the payout passage 65.

  In this embodiment, the passage wall 60 a of the upper spherical passage 60, the chamber wall 61 a of the rotating body storage chamber 61, and the passage wall 63 a of the prize ball passage 63 are provided on the front and rear surfaces of the flat intermediate plate 54. A passage wall 64a of the ball rental passage 64, a passage wall 65a of the payout passage 65, a chamber wall 70a of the branch chamber 70, and a passage wall 67a of the upper ball passage 67 are formed. That is, since the intermediate partition 54 is configured to function as a passage structure, the passage walls 60a, 63a, 64a, 65a, 67a and the chamber walls 61a, 70a are formed in the base body 53 and the cover body 56. Therefore, the base body 53 and the cover body 56 can be easily formed.

  The passage walls 60a, 63a, 64a, 65a, 67a and the chamber walls 61a, 70a are provided in consideration of the shape, structure, formability, etc. of the three parts of the base body 53, the intermediate partition body 54, and the cover body 56. The base body 53, the intermediate partition body 54, and the cover body 56 are divided into three parts that are easy to mold, and the passage walls 60a, 63a, 64a, 65a, 67a and the like are assembled by assembling the three parts. It is also possible to constitute the chamber walls 61a and 70a.

  The upper sphere passage 60 of the unit case 52 is bent substantially in an S shape, and the inlet of the unit case 52 faces the sphere delivery portion of the tank rail 22. Thereby, the sphere B flowing down from the sphere delivery part of the tank rail 22 flows into the upper sphere passage 60. As shown in FIG. 12, the unit case 52 is provided with a ball-cut detector 80 located in the vicinity of the inlet of the upper spherical passage 60. When the supply of the sphere B from the sphere delivery unit of the tank rail 22 is interrupted, the sphere-cut detector 80 outputs the sphere-cut signal to the main control board 16 or the frame control board 121, and based on this The ball breakage notification lamp installed at a predetermined position of the pachinko machine 1 is turned on.

  As shown in FIGS. 15 and 16, in the rotating body storage chamber 61 communicating with the outlet of the upper spherical passage 60, a substantially circular through hole 54 a is formed in a portion of the intermediate partition body 54 surrounded by the chamber wall 61 a. The number of balls corresponding to the number of balls sent out from a lending machine (not shown) and the function of paying out the number of balls corresponding to the number of winning balls when entering the various winning holes of the game board 11 are formed. A rotating body 90 having a function of paying out a sphere is disposed so as to be rotatable about a substantially horizontal axis 90a in the front-rear direction. The rear end portion of the shaft 90 a of the rotating body 90 is rotatably supported by a bearing portion 56 a provided on the inner surface of the cover body 56 of the unit case 52. Further, the front end portion of the shaft 90 a of the rotating body 90 is connected to the output shaft 82 of the payout motor 81 so as to transmit torque. The payout motor 81 is assembled to the front surface of the base body 53 in the gap between the base body 53 of the unit case 52 and the game board 11. The payout motor 81 is rotationally controlled based on a prize ball payout signal sent from the main control board 16 or the frame control board 121, and sent from a ball rental machine (not shown) installed on one side of the pachinko machine 1. The rotation is controlled based on the rented ball payout signal.

  As shown in FIGS. 15 and 16, the rotating body 90 includes an intermediate plate 91, front and rear sprocket portions 94 and 96, and a plate to be detected 92 integrally around the shaft 90 a. An intermediate plate 91 provided at a substantially central portion in the front-rear direction of the rotating body 90 is fitted into the through hole 54 a so as to be rotatable on substantially the same plane as the intermediate partition 54. The front surface of the intermediate plate 91 is provided with a front sprocket portion 94 in which a plurality (for example, four) of ball receiving portions 95 are recessed on the outer periphery with a predetermined interval (for example, an interval of 90 degrees in the case of four). It has been. In addition, a plurality of (for example, four) ball receiving portions 97 are provided on the rear surface of the rotating body 90 so as to be phased by a half pitch (for example, 45 degrees in the case of four) with respect to the ball receiving portion 95 of the front sprocket portion 94. Is provided in a recessed manner with a predetermined interval, and a sprocket portion 96 is provided. In this embodiment, a rear sprocket portion 96 is integrally formed on the rear side of the intermediate plate 91, and a front sprocket portion 94 is integrally formed on the rear side of the detection plate 92.

  As shown in FIGS. 15 and 16, the detection plate 92 is formed in a disc shape, and the number of ball receiving portions 95 of both the front and rear sprocket portions 94 and 96 is formed on the outer periphery of the detection plate 92. The number of detected portions 93 is the same as the number obtained by adding each of the shapes of the U-shaped groove and the V-shaped groove. At a predetermined position of the intermediate partition 54 of the unit case 52, a payout number detector 98 including an optical sensor that optically detects each detected portion 93 of the detected plate 92 is disposed. The detection signal of each detected portion 93 of the detected plate 92 by the payout number detector 98 (in other words, the signal of the payout number of the sphere B) is sent to the main control board 16 and the frame control board 121. .

  That is, when the rotating body 90 is rotated in a predetermined direction by the payout motor 81 based on a signal corresponding to a winning ball or a rental ball, the ball B sent to the upper entrance of the rotating body storage chamber 61 is turned into the rotating body 90. Then, it flows into the ball receiving portions 95 and 97 of both the front and rear sprocket portions 94 and 96 in order, and is discharged from the storage chamber outlet at the bottom of the rotating body storage chamber 61. Then, when the detected portion 93 of the detected plate 92 is detected by the payout number detector 98 corresponding to the payout number of the ball B, the payout motor 81 is stopped and the rotation of the rotating body 90 is stopped. It is like that.

  As shown in FIG. 11, a prize ball passage 63 and a ball rental passage 64 are arranged in parallel at the outlet of the storage body 61 of the rotating body storage chamber 61 so that they can alternatively communicate with each other by the first passage switching member 100. ing. That is, the first passage switching member 100 is selectively switched to both the first and second switching positions by a switching drive device such as a solenoid (not shown) with the shaft 101 as the center. . Then, as shown by the solid line in FIG. 11, when the first passage switching member 100 is switched to the first position, the ball B is paid out from the storage chamber outlet to the prize ball passage 63. Further, as shown by a two-dot chain line in FIG. 11, when the first passage switching member 100 is switched to the second position, the ball B is paid out from the storage chamber outlet to the ball rental passage 64. Yes.

  In addition, a prize ball detector 105 for detecting a ball paid out to the passage is arranged at a predetermined position of the prize ball passage 63, and a predetermined position of the ball rental passage 64 is paid to the passage. A lending detector 106 for detecting the ball that has been put out is provided. The detection signal of the ball B by the winning ball detector 105 is sent to the main control board 16 and the frame control board 121, respectively. The detection signal of the ball B by the ball rental detector 106 is sent to the ball rental machine and the frame control board 121. To be sent to each. When the number of detected balls B or the number of balls B corresponding to the number of balls lent is detected by the award ball detector 105 or the ball rental detector 106 is insufficient (for example, the ball tank 21 When the supply failure of the sphere B occurs in the tank rail 22 or the like, a shortage of discharge of the sphere B occurs), and a signal corresponding to the shortage is sent to the discharge motor 81, whereby the rotating body 90 corresponds to the shortage number. The required number of spheres B are accurately paid out without a shortage.

  The winning ball passage 63 and the rental ball passage 64 meet at the downstream portion thereof. A branching portion is provided on the downstream side of the joining portion of the prize ball passage 63 and the ball rental passage 64, and a payout passage 65 and an upper ball removal passage 67 branch on the downstream side of the branching portion. Is formed. Further, at the branch portion, the second passage switching member 110 is selectively switched to both the first and second switching positions by a switching driving device such as a solenoid (not shown) with the shaft 111 as the center. It is like that. Then, as shown by the solid line in FIG. 11, when the second passage switching member 110 is switched to the first position, the ball B at the branching portion flows into the dispensing passage 65. Further, as shown by a two-dot chain line in FIG. 11, when the second passage switching member 110 is switched to the second position, the sphere B at the branching portion flows into the upper spherical passage 67. In the payout passage 65, a part of the passage wall 65a is removed, and a bell 111 that emits a hitting sound when the ball B flowing through the payout passage 65 hits is provided in the removed portion.

  As shown in FIG. 11, a branch chamber 70 is formed on the downstream side of the dispensing passage 65. In the upper part of the branch chamber 70, an inflow port 71 into which the sphere B delivered from the payout passage 65 flows is provided in a substantially vertical shape and enters the branch chamber 70. Further, in the branch chamber 70, there is provided an upper plate delivery path 72 that has an inlet 73 that faces directly below the inlet 71 of the branch chamber 70 and communicates with the upper plate 6 through the upper plate communication path 25. It has been. Furthermore, in the branch chamber 70, the ball B staying at the entrance 73 of the upper plate delivery path 72 (for example, when the ball B of the upper plate 6 and the upper plate communication path 25 is full) A lower dish delivery path 76 is provided through which the ball B bounced off by hitting the ball B) staying at the entrance 73 of the path 72 can flow in and guides the ball to the lower dish 7 through the lower dish communication path 26.

  That is, in this embodiment, as shown in FIGS. 4 and 11, the upper dish delivery path 72 is located at the middle partition 54 in the middle of the width direction in the branch chamber 70 and at a predetermined height position. A substantially U-shaped entrance wall 73a, a communication hole 74 provided in the intermediate partition 54 so as to communicate with the passage space of the entrance wall 73a before and behind the entrance wall 73a, and the base body 53 are provided. And a delivery port 75 that is made up of. The upper dish delivery path 72 uses the upper end opening of the U-shaped inlet wall 73a as the inlet 73, and the outlet 75 penetrating the base body 53 communicates with the upper dish communication path 25. ing. Moreover, as shown in FIG. 11, the space | interval dimension H between the indoor side opening end of the inflow port 71 of the branch chamber 70, and the upper end opening part of the entrance 73 of the delivery path 72 for upper plates is the same upper end opening part. Even when the sphere B stays and accumulates, a spacing dimension that allows the sphere B to flow into the branch chamber 70 from the inlet 71, for example, a spacing dimension that is approximately 1.5 to 2 times or more the diameter dimension of the sphere B. It is set to become.

  In addition, in order to prevent many spheres B from accumulating at the entrance 73 of the delivery path 72 for the upper plate, at least one of the depth opening dimension and the width opening dimension of the entrance 73 is the sphere B. It is desirable to set the dimension corresponding to the diameter dimension. In this embodiment, the width opening dimension of the upper end opening portion of the entrance 73 of the upper dish delivery path 72 is a dimension corresponding to the diameter dimension of the sphere B (a dimension slightly larger than the diameter dimension of the sphere B). The depth opening of the entrance 73 is about twice as large as the diameter of the sphere B, and its substantially central portion is divided forward and backward by the intermediate partition 54. The sphere B does not accumulate at the upper end opening of the inlet 73.

  Moreover, the said space | interval dimension H between the indoor side opening end of the inflow port 71 of the branch chamber 70 and the upper end opening part of the inlet 73 of the delivery path 72 for upper plates is the (A)-(C) of FIG. ). That is, the distance A between the opening on the indoor side of the inlet 71 of the branch chamber 70 and the sphere B staying at the uppermost portion of the entrance 73 is equal to or larger than the diameter of the sphere B (about 1.5 times in FIG. 17). It is necessary to set to be. Therefore, for example, as shown in FIG. 17A, when the depth opening dimension and the width opening dimension W1 of the entrance 73 are set to be approximately the same as the diameter dimension of the sphere B, the flow of the branch chamber 70 is reduced. An interval dimension H1 between the indoor side opening end of the inlet 71 and the upper end opening part of the entrance 73 of the upper dish delivery path 72 is appropriately larger than the distance A (in FIG. 17, only the radial dimension of the sphere B). By setting a larger value, it becomes possible to prevent clogging of the balls. Further, the depth opening dimension of the entrance 73 is substantially the same as the diameter of the sphere B, and the width opening dimension W2 of the entrance 73 is substantially the same as the diameter of the sphere B, as shown in FIG. When set to about twice, the distance A between the opening on the indoor side of the inlet 71 of the branch chamber 70 and the sphere B that can be deposited on the uppermost stage of the inlet 73 is equal to or greater than the diameter of the sphere B. Further, the distance dimension H2 between the indoor side opening end of the inlet 71 of the branch chamber 70 and the upper end opening part of the inlet 73 of the delivery path 72 for the upper plate is set to be a diameter dimension of the sphere B rather than the distance dimension H1. This can be dealt with by setting it to be large. Similarly, the depth opening dimension of the entrance 73 is substantially the same as the diameter dimension of the sphere B, and the width opening dimension W3 of the entrance 73 is the diameter dimension of the sphere B as shown in FIG. When the distance A is set to about three times the distance A, the distance A between the opening end on the indoor side of the inlet 71 of the branch chamber 70 and the sphere B that can be deposited on the uppermost stage of the inlet 73 is larger than the diameter dimension of the sphere B. In order to achieve this, the distance dimension H3 between the indoor side opening end of the inlet 71 of the branch chamber 70 and the upper end opening part of the inlet 73 of the delivery path 72 for the upper dish is set to a diameter of the sphere B larger than the distance dimension H2. This can be dealt with by setting the size as large as possible. Thus, the indoor opening end of the inlet 71 of the branch chamber 70 and the upper end of the inlet 73 of the upper plate delivery path 72 corresponding to the width opening dimension and / or the depth opening dimension of the inlet 73. The distance dimension H between the openings is set appropriately.

  As shown in FIGS. 7 and 11, the lower tray delivery path 76 includes a side guide path 76 a that guides a sphere on both sides of the entrance wall 73 a that forms the entrance 73 of the upper dish delivery path 72, and a U-shape. , A bottom guide path 76b provided between the inlet wall 73a and the bottom surface of the branch chamber 70, a through hole 77 penetrating the intermediate partition 54 in the lower part of the branch chamber 70, and the through hole 77 And a delivery port 78 penetrating the base body 53 at a position corresponding to. In the lower plate delivery path 76, a delivery port 78 penetrating the base body 53 communicates with the lower plate communication path 26. The ball dispensing unit 51 is configured with the above components and the ball path configuration, and is detachably mounted on the unit mounting portion of the mechanism plate 20. In this embodiment, as shown in FIGS. 2 and 5, the rear surface of the cover body 56 of the unit case 52 of the ball dispensing unit 51 is a sub-control board that is electrically connected to the main control board 16. The first sub board box 120 in which the frame control board 121 is housed is detachably mounted.

  As shown in FIGS. 1 and 4, a lower extension portion is integrally provided at the lower portion of the game board fitting portion of the base frame 10. In the lower extension portion of the base frame 10, a passage that forms a part of the upper plate communication passage 25 that communicates the delivery port 75 of the delivery plate 72 for the upper plate with the upper plate 6 at a portion on the right side as viewed in FIG. 1. The wall 25a is integrally formed. The entrance portion of the upper plate communication path 25 faces the delivery port 75 of the delivery plate 72 for the upper plate through the opening window of the unit mounting portion of the mechanism plate 20. Further, a passage wall 26 a constituting a lower plate communication passage 26 having an upper portion adjacent to the right side of the upper plate communication passage 25 in FIG. 1 and a lower portion communicating with the lower plate 7 is formed at the lower extension portion of the base frame 10. They are integrally formed (see FIG. 10).

  As shown in FIGS. 1, 8, 9, and 10, a lower ball extraction passage 27 that communicates with the upper ball extraction passage 67 of the ball dispensing unit 51 is formed in a portion closer to one side of the base frame 10. The passage wall 27a is integrally formed. The upper part of the lower ball removal passage 27 faces the exit of the upper ball removal passage 67 of the ball dispensing unit 51. That is, in this embodiment, as shown in FIGS. 1, 8, 9, and 10, in a portion closer to one side of the base frame 10 along the outer side on one side of the game board 11, from the front surface of the base frame 10. A passage wall 27a is integrally projected toward the rear surface of the front frame 3. The main part of the lower bulb passage 27 (substantially the entire length of the lower bulb passage 27) is surrounded by the front surface of the base frame 10, the passage wall 27a, and the rear surface of the front frame 3. Further, as shown in FIG. 8, the upper inlet portion of the lower bulb passage 27 communicates with the lower outlet portion of the upper bulb passage 67 through a communication portion 20 c formed in the mechanism plate 20. Further, the lower bulb passage 27 extends substantially vertically to the vicinity of the lower portion of the lower extension portion of the base frame 10. Further, the lower end portion of the lower ball extraction passage 27 is extended substantially in an L shape adjacent to the outer side and the lower side of the lower dish communication passage 26. Then, the ball is discharged out of the machine by using the extended end of the lower ball extraction passage 27 as an outlet.

  Further, in this embodiment, as shown in FIGS. 1, 3, and 4, the lower surface of the mechanism plate 20 is substantially covered on the rear surface side of the lower extension portion of the base frame 10 so as to cover the portion. The second sub-board box 130 in which the power supply board 131 is housed is mounted on the projecting portion 20 b of the flat mechanism plate 20. Further, on the rear surface of the second sub-board box 130, there is a third sub-board box 140 in which a lamp control board 141 and a sound control board 142 as sub-control boards are adjacent to each other on the left and right and are accommodated on the same plane. Mounted in a stack.

  The pachinko machine 1 according to this embodiment is configured as described above. Therefore, prior to a pachinko game or during a game, when a ball lending switch disposed at a predetermined position on the front side of the pachinko machine 1 is operated, the signal is sent to the frame control board 121, based on this. Then, a switching drive device such as a solenoid is actuated by a signal generated from the frame control board 121, and the first passage switching member 100 is switched to the second position.

  At this time, a signal based on the operation of the ball lending switch is sent to a ball lending machine (not shown) installed on one side of the pachinko machine 1, and the number of signals corresponding to the number of balls lending emitted from the lending machine is framed. It is sent to the control board 121. Based on this, the payout motor 81 is rotationally controlled by a payout signal issued from the frame control board 121. Then, the payout motor 81 causes the rotating body 90 to rotate in a predetermined direction by a rotation number or a rotation angle corresponding to the number of rented balls. As a result, the balls B received by the ball receiving portions 95 and 97 of the front and rear sprocket portions 94 and 96 of the rotating body 90 are paid out to the front and rear payout passages 65 through the front and rear ball rental passages 64. Then, the balls B of the front and rear discharge passages 65 flow from the front and rear inlets 71 of the branch chamber 70 into the inlets 73 of the front and rear upper dish delivery paths 72 positioned immediately below the inlets 71, respectively. From the delivery port 75 to the upper plate communication path 25, paid out to the upper plate 6, and stored in the upper plate 6.

  Further, in the pachinko game, when the ball B launched into the game area of the game board 11 flows into the winning opening and is detected by the detector, the signal is sent to the main control board 16. Then, the arrangement of the first passage switching member 100 is switched to the first position via the frame control board 121. At this time, a number of signals corresponding to the number of prize balls issued from the main control board 16 are sent to the frame control board 121, and the payout motor 81 is rotationally controlled by a payout signal issued from the frame control board 121 based on this signal. The Then, the payout motor 81 rotates the rotating body 90 in a predetermined direction by a rotation angle corresponding to the number of prize balls. As a result, the balls B received by the ball receiving portions 95 and 97 of the front and rear sprocket portions 94 and 96 of the rotating body 90 are paid out to the front and rear payout passages 65 through the front and rear prize ball passages 63. Then, the balls B of the front and rear discharge passages 65 flow from the front and rear inlets 71 of the branch chamber 70 into the inlet 73 of the front and rear upper dish delivery passages 72 located immediately below the inlets 71. It flows from the delivery port 75 to the upper plate communication path 25 and is paid out to the upper plate 6.

  As described above, after the ball B paid out to the front and rear discharge passages 65 passes from the front and rear inlets 71 of the branch chamber 70 through the inlet 73 of the front and rear upper plate delivery path 72, the upper plate communication path After 25, it is paid out to the upper plate 6 and stored. The sphere B of the upper plate 6 may become full, and the sphere B may remain at the entrance 73 of the upper and lower upper plate delivery path 72. In this state, when the ball B paid out to the front and rear discharge passages 65 flows into the front and rear inlets 71 of the branch chamber 70, the ball B stays at the inlet 73 of the front and rear upper dish delivery path 72. Bounces off the ball and flows to the side guide path 76a of the front and rear lower plate delivery path 76. The sphere B that has flowed to the side guide path 76a located on the left side as viewed in FIG. 11 flows while being guided by the bottom guide path 76b. Then, the balls B of the front and rear lower dish delivery paths 76 flow into the lower dish communication passage 26 through the delivery port 78 penetrating the base body 53 and are delivered to the lower dish 7 (see FIGS. 5 and 7).

  That is, in this embodiment, as shown in FIG. 11, the distance dimension H between the indoor side opening end of the inlet 71 of the branch chamber 70 and the upper end opening of the inlet 73 of the delivery path 72 for the upper plate is Even when the sphere B remains in the upper end opening, the interval dimension in which the sphere B can flow into the branch chamber 70 from the inlet 71, for example, approximately 1.5 to 2 times the diameter of the sphere B. It is set so as to have the above-mentioned distance dimension. Therefore, in a state where the ball B stays at the entrance 73 of the front and rear upper dish delivery path 72, when the ball B paid out to the front and rear delivery passages 65 flows into the front and rear inlets 71 of the branch chamber 70, The balls B bounce off the balls B staying at the entrance 73 without excessive accumulation on the balls B staying at the entrance 73 of the front and rear upper dish delivery paths 72, and send the front and rear lower dishes. It flows reliably to the side guide path 76a of the path 76. For this reason, the trouble that the flow of the sphere B is stopped in the branch chamber 70 and the sphere is blocked is prevented.

  Further, at least one of the depth opening dimension and the width opening dimension of the inlet 73 is the diameter dimension of the sphere B so that many balls B do not accumulate at the inlet 73 of the upper dish delivery path 72. The dimension corresponding to is set. In this embodiment, the width opening dimension of the upper end opening portion of the entrance 73 of the upper dish delivery path 72 is a dimension corresponding to the diameter dimension of the sphere B (a dimension slightly larger than the diameter dimension of the sphere B). The depth opening of the entrance 73 is about twice as large as the diameter of the sphere B, and its substantially central portion is divided forward and backward by the intermediate partition 54. The sphere B does not accumulate at the upper end opening of the inlet 73. Therefore, it is possible to more reliably prevent the problem that the flow of the sphere B is stopped in the branch chamber 70 and the sphere is clogged. In addition, the distance H between the indoor opening end of the inlet 71 of the branch chamber 70 and the upper end opening of the inlet 73 of the upper dish delivery path 72 is kept small (for example, approximately 2 of the diameter of the sphere B). It is possible to reduce the height dimension of the branch chamber 70, and consequently the height dimension of the ball dispensing unit 51, so that the size can be reduced.

Further, when the balls in the upper ball passage 60 of the ball tank 21, the tank rail 22, and the ball dispensing unit 51 are discharged out of the machine, the ball removal switch arranged at a predetermined position of the pachinko machine 1 is turned on. Then, the ball removal signal is sent from the main control board 16 to the frame control board 121, and the second passage switching member 110 is arranged at the second position by the ball removal signal emitted from the frame control board 121 based on this signal. In addition, the payout motor 81 is rotationally controlled.
As a result, the balls B of the ball tank 21, the tank rail 22, and the upper ball passage 60 of the ball dispensing unit 51 sequentially flow into the ball receiving portions 95 and 97 of the sprocket portions 94 and 96 before and after the rotating body 90. Then, the ball B is paid out to the prize ball passage 63 or the payout passage 65 and flows into the upper ball removal passage 67. Subsequently, the sphere B flows from the upper sphere extraction passage 67 to the lower sphere extraction passage 27 of the base frame 10 and is discharged out of the machine from the outlet of the lower sphere extraction passage 27. In addition, at the time of ball removal, the 1st channel | path switching member 100 may be arrange | positioned in the 1st position, and may be arrange | positioned in the 2nd position.

  In addition, in the said embodiment, although the case where the side part guidance path 76a of the delivery path 76 for lower dishes was provided in the right and left both sides of the entrance 73 of the delivery path 72 for upper dishes, it limited to this. is not. For example, you may provide the side part guidance path which guide | induces a ball | bowl to the both sides before and behind the entrance 73 of the delivery path 72 for upper plates, respectively. Further, among the outer portions on the left, right, front, and rear of the entrance 73 of the delivery path 72 for the upper plate, there are provided side guide paths for guiding the spheres at two or more outer portions. Also good. Moreover, in the said embodiment, although the ball | bowl dispensing apparatus 50 was comprised by the ball | bowl dispensing unit 51 made into one unit, and the case where it was mounted | worn with respect to the unit mounting part of the mechanism board 20 was illustrated, it limited to this. Not what you want. Further, in the above-described embodiment, the ball delivery device is exemplified by the case where the payout motor 81 is used as a drive source and the rotating body 90 including the front and rear sprocket portions 94 and 96 is mainly used. Any structure may be used as long as it has a function. In addition, the balls may be sent out in two or more rows by the ball sending device, or may be sent in one row.

1 Pachinko machine (game machine)
10 base frame 20 mechanism plate 51 ball dispensing unit (ball dispensing device)
70 Branching chamber 72 Upper dish delivery path 73 Inlet 75 Delivery outlet 76 Lower dish delivery path 76a Side guidance path 76b Bottom guidance path 78 Delivery outlet 90 Rotating body (ball delivery device)

Claims (3)

A sphere delivery device, and a branch chamber having an inflow port into which a sphere delivered from the sphere delivery device flows,
Each of the branch chambers is provided with an upper dish delivery path leading to the upper dish and a lower dish delivery path leading to the lower dish,
The entrance that forms the entrance of the delivery path for the upper plate is provided directly below the inlet at the top of the branch chamber,
The lower dish delivery path is provided at a position where a ball bounced off by hitting a ball staying at the entrance of the upper dish delivery path can flow.
Further, the space between the inlet at the upper part of the branch chamber and the inlet is set to a dimension that allows the ball to flow from the inlet even when the ball remains in the inlet. Machine. The gaming machine according to claim 1,
The entrance of the delivery path for the upper dish is a gaming machine in which at least one of the depth opening dimension and the width opening dimension is set to a dimension corresponding to the diameter dimension of the sphere. A gaming machine according to claim 1 or 2,
The lower tray delivery path is a gaming machine having side guide paths that guide the balls at a plurality of outer portions among the left, right, front, and rear outer portions of the entrance of the upper tray delivery path. .

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