JP2009233213A - Ball dispensing device of game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ball dispensing device of a game machine capable of preventing an overload from being applied to a pair of ball-dispensing cams and allowing the pair of ball-dispensing cams to alternately and stably put out game balls to a ball-dispensing path. <P>SOLUTION: The ball dispensing device 1 has two ball flow paths 3, the ball-dispensing cams 61 formed with ball-holding portions 611, and one ball-dispensing path 4. The two ball-dispensing cam 61 are provided in the axial direction of a rotary shaft 6, and are alternately formed with the ball-holding portions 611 in the circumferential direction. The two ball flow paths 3 have a downstream side provided with induction wall portions 31 for inducing game balls to the center side in a direction in which the two ball flow paths 3 are positioned side by side. Between the two ball flow paths 3 and the ball-dispensing path 4, a guide path 5 is formed which feeds the game balls along a feed direction of the ball-dispensing cam 61. The ball-dispensing path 4 has an upstream side provided with convergent wall portions 41 for collecting the game balls dispensed by the ball-dispensing cams 61 into one flow. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a ball payout device for paying out a predetermined number of game balls according to prize balls or the like in a gaming machine.

  In a gaming machine such as a pachinko gaming machine, a ball payout device is used to pay out a predetermined number of game balls according to a payout command for prize balls or the like to a ball tray. For example, in the pachinko ball payout device of Patent Document 1, a rotating body (ball payout cam) for paying out a game ball is disposed in the downstream portion of the two supply passages for flowing down the game ball, A single discharge passage is formed on the downstream side of the position where the rotating body is disposed. When the game balls are transferred by the rotating bodies, the discharge passages are converged from the two flowing down states to the one flowing down state.

  However, when converging in the flow-down state at the same time as the transfer of the game ball, the rotating body has a load when the game ball is transferred and when the game ball is converged to the center side in the direction in which the two payout paths are aligned. A load is applied simultaneously. For this reason, an excessive load due to frictional resistance or the like may be applied to the rotating body.

JP 2000-135356 A

  The present invention has been made in view of such conventional problems, and prevents an excessive load from being applied to a pair of ball payout cams, and a pair of ball payout cams alternately and stably to a ball payout path. It is an object of the present invention to provide a gaming machine ball payout device capable of paying out money.

The present invention comprises two ball flow passages formed adjacent to each other to allow game balls to flow down,
A ball payout cam formed with a ball holding portion for holding a game ball;
And a single ball payout passage for allowing the game balls paid out by the ball payout cam to flow down,
Two of the ball payout cams are provided in the axial direction of the rotation shaft that is rotationally driven by the drive source corresponding to the two ball flow down passages, and the ball holding portions in the two ball payout cams are , Alternately formed in the circumferential direction,
In the downstream part of the two ball flow passages, a guide wall for guiding the game ball to the center side in the direction in which the two ball flow passages are arranged is provided.
Between the two ball flow down passages and the ball payout passage, there is a guide passage for sending the game balls held in the ball holding portion of the ball payout cam along the transfer direction of the ball payout cam. Formed,
A ball of a gaming machine characterized in that a converging wall portion for converging the game ball paid out by the ball paying cam into a single flowing-down state is provided in an upstream portion of the ball payout passage. It is in the dispensing device (claim 1).

The ball dispensing device for a gaming machine according to the present invention is such that a guide passage is formed between two ball flow-down passages and one ball discharge passage, and two ball flow-down passages are formed at the guide passage formation portion. A ball payout cam is arranged corresponding to the above. In addition, a guide wall portion is provided in the downstream portion of the two sphere flow down passages, and a converging wall portion is provided in the upstream portion of the ball payout passage.
The ball payout device of the present invention is configured to converge the flowing-down state of the game ball in two stages at the upstream position and the downstream position with respect to the ball payout cam, and the guide passage in which the ball payout cam is arranged In this case, the game balls are not converged in the flow-down state.

  When the game balls are paid out by the ball payout device, the game balls flowing down the two ball flow down passages are the ball holding portions in one ball payout cam of the game balls flowing down through the one ball flow down passage. The game ball flowing down in the other ball flow-down passage is prevented from flowing down by the other ball discharge cam. At this time, the game balls held in the ball holding portion of the ball payout cam are converged in the first stage, and the center side in the direction in which the two ball flow-down passages are aligned by the guide wall portion in the ball flow-down passage (two balls). The downflow passages are moved toward the center in the direction adjacent to each other.

  When the two ball payout cams provided on the rotation shaft are driven to rotate by the drive source, the game balls held in the ball holding portion in one of the ball payout cams are transferred along the guide path, A game ball that flows down the other ball flow-down passage is held by a ball holding portion in the other ball payout cam. Thereafter, the game balls transferred along the guide passage and discharged and discharged from the ball holding portion are further brought closer to the central side in the adjacent direction by the converging wall portion in the ball payout passage as the second stage of convergence. . Thereafter, the rotation driving is continuously performed, so that the game ball held in the ball holding portion of the other ball payout cam is transferred along the guide path.

Thus, in the present invention, the game balls flowing down the two ball flow down passages can be alternately paid out to the ball payout passage by the pair of ball payout cams. , The game ball can be converged in two stages. Further, when the game ball is transferred by the ball payout cam, it is possible to apply a force to the game ball only in the transfer direction so that no force is applied in a direction different from the transfer direction, ie, the convergence direction.
Thereby, a part of the convergence is performed at the guide wall portion of the upstream portion with respect to the guide passage without converging the game balls at a time from two to one at the convergent wall portion of the downstream portion with respect to the guide passage. Can do. Therefore, the converging structure after the game ball is paid out from the ball payout cam can be made smoother. In addition, in the process of transferring the game ball by the ball payout cam, it is possible to prevent an excessive load from being applied to the ball payout cam due to frictional resistance or force applied in two different directions. The game ball can be paid out stably and alternately to the ball payout passage.

  Therefore, according to the ball payout device of the gaming machine of the present invention, an excessive load is prevented from being applied to the pair of ball payout cams, and the game balls are stably and alternately supplied to the ball payout passage by the pair of ball payout cams. Can be paid out.

A preferred embodiment of the present invention described above will be described.
In the present invention, the guide passage is formed by a guide upper surface on which a game ball is placed and rolled, and two notch grooves formed downward from the guide upper surface for arranging the ball payout cams, respectively. (Claim 2).
In this case, a guide passage for guiding the transfer of the game ball can be easily formed.
Further, when the game ball is held by the ball holding portion, it is placed on the guide upper surface and is not placed on the rotating shaft. Therefore, among the two ball flow down passages, at least the ball flow down passage on the side where the ball holding portion faces, the ball pressure of the game ball continuously supplied from the upstream side is directly applied to the rotating shaft. Can not be. Thereby, it is possible to prevent an excessive load from being applied to the ball dispensing cam, and the ball dispensing cam can be stably rotated.

  In addition, the two ball flow down passages, the guide passage, and the ball payout passage are formed in a case portion, the ball payout cam, the drive source, a rotating shaft provided with the ball payout cam, and the drive source. A drive gear provided on the output shaft, a driven gear provided on the rotating shaft, and an intermediate gear for transmitting the rotation of the drive gear to the driven gear are accommodated in the case portion, and the driven gear is The case portion is arranged in a gear housing portion formed in a side region of the guide wall portion, and the ball payout passage is converged into a single flow-down state by the convergent wall portion, It is formed in a state of being biased to one side of the case portion, and the drive source is disposed in a space formed on the other side by the ball payout passage formed to be biased to the one side. (Claim 3).

In this case, the driven gear provided on the rotating shaft can be easily arranged using the space as the gear housing portion formed in the case portion. Here, the lateral region of the guide wall portion refers to a space region provided in the vicinity of the portion where the guide wall portion is formed in the case portion, in other words, by forming the guide wall portion. It refers to the space area formed in the periphery.
Further, the ball payout passage is formed in a state of being biased to one side portion of the case portion after being converged into a single flow-down state by the converging wall portion. And the drive source is arrange | positioned in the space formed in the other side part side by the ball | bowl paying_out path formed biased to one side part. Thereby, drive sources, such as a motor, can be arrange | positioned using the space formed adjacent to the ball payout path | pass in the case part.

  In this case, the driving source is not directly connected to the rotating shaft, and the rotational force transmitted from the driving source to the rotating shaft is transmitted via the driving gear, the intermediate gear, and the driven gear. The drive source is arranged in the ball dispensing device using the space as described above. Therefore, a drive source can be arrange | positioned without projecting so much from the width dimension of the direction where two ball | bowl flow-down passages adjoin.

Further, since the guide wall portion is formed in the case portion, the space region (the gear housing portion) can be formed in the peripheral portion. By using this space area, the driven gear provided on the rotating shaft can be arranged, and there is no need to separately provide an area for arranging the driven gear outside the case portion.
Further, an intermediate gear for transmitting the rotational force of the drive source to the driven gear using the space area and the space area generated by converging the two ball flow down paths into the one ball payout path is provided. Can be arranged. Therefore, it is not necessary to separately provide a region for arranging the intermediate gear outside the case portion.

  Therefore, in the case portion of the ball dispensing device, a width necessary for forming the two ball flow-down passages is secured, and the rotating shaft as well as the driving source is not protruded so much from the range of the necessary width. A driving gear, a driven gear, and an intermediate gear can be arranged. Therefore, each component can be arranged in a limited space, and the ball dispensing device can be miniaturized.

Embodiments of a ball payout device for a gaming machine according to the present invention will be described below with reference to the drawings.
As shown in FIG. 1 and FIG. 2, the ball dispensing device 1 of the gaming machine includes two ball flow-down passages 3 formed adjacent to each other to flow the game ball X, and a ball for holding the game ball X. A ball payout cam 61 in which holding portions 611 are formed at equal intervals, and a single ball payout passage 4 through which the game ball X paid out by the ball payout cam 61 flows down are provided. As shown in FIGS. 2 and 3, two ball dispensing cams 61 are provided in the axial direction of the rotary shaft 6 that is rotationally driven by the drive source 62 corresponding to the two ball flow down passages 3. The ball holding portions 611 in the two ball payout cams 61 are alternately formed in the circumferential direction.

  As shown in FIG. 3 and FIG. 5, the downstream side portion of the two ball flow-down passages 3 has a central side in the direction in which the two ball flow-down passages 3 are arranged (adjacent directions in which the two ball flow-down passages 3 are adjacent to each other. A guide wall portion 31 for guiding the game ball X to the center B) is provided. As shown in FIG. 1, the game ball X held by the ball holding portion 611 of the ball payout cam 61 is placed between the two ball flow down passages 3 and the ball payout passage 4 along the transfer direction of the ball payout cam 61. The guide passage 5 for feeding out is formed. An upstream portion of the ball payout passage 4 is provided with a converging wall portion 41 for converging the game balls X paid out by the ball payout cam 61 into a single flow-down state.

Hereinafter, the ball payout device 1 of the gaming machine of this example will be described in detail with reference to FIGS.
The gaming machine ball dispensing device 1 of this example is used in a pachinko gaming machine to dispense a predetermined number of gaming balls X to a ball tray in accordance with a prize ball or the like.
As shown in FIGS. 1 and 2, the ball dispensing device 1 of the gaming machine includes a rotating shaft 6 provided with a ball dispensing cam 61 formed with a ball holding portion 611 for holding the game ball X, and the rotating shaft 6. A drive source 62 for rotationally driving, a drive gear 71 provided on the output shaft of the drive source 62, a driven gear 73 provided on the rotary shaft 6, and a rotation for transmitting the rotation of the drive gear 71 to the driven gear 73. The intermediate gear 72 includes a rotating shaft 6, a drive source 62, a drive gear 71, a driven gear 73, and a case portion 11 that accommodates the intermediate gear 72. The two sphere flow down passages 3 and the one sphere payout passage 4 are formed in the case portion 11. In FIG. 1, a part of the case portion 11 (the back side portion in the figure) is indicated by a two-dot chain line.

As shown in FIG. 5, the driven gear 73 is arranged in the gear housing portion 32 formed in the side region 311 of the guide wall portion 31 in the case portion 11. As shown in FIGS. 1, 2, and 4, the ball payout passage 4 is converged to one flow-down state by the converging wall portion 41, and then biased to one side portion 111 in the adjacent direction B in the case portion 11. It is formed in a state. The drive source 62 of this example is a stepping motor, and this motor 62 is arranged in a space 113 formed on the other side 112 side by a ball payout passage 4 formed so as to be biased toward one side 111. .
In addition, after the ball payout passage 4 is converged in a single flow-down state by the converging wall portion 41, the ball payout passage 4 is also biased to one side portion in the direction D perpendicular to the adjacent direction B in the case portion 11. Is formed.

  In FIG. 6, the back surface part of the main body frame 2 of the gaming machine in which the ball dispensing device 1 of this example is disposed is shown. As shown in the figure, the main body frame 2 has a frame shape with an upper frame portion (upper side portion) 21, a pair of side frame portions (side side portions) 22, and a lower frame portion (lower side portion) 23. An opening area 201 that opens the back side of the game board attached to the main body frame 2 is formed inside the frame shape. The main body frame 2 is formed with a ball passage 24 for storing and flowing down the game ball X for paying out by the ball paying device 1. The ball path 24 is connected to the first ball path 241 disposed from one side of the left and right direction W to the other side of the upper frame portion 21 and the other side of the first ball path 241, and is connected to one side. The frame portion 22 includes a second spherical passage 242 disposed from the upper end portion to the lower end portion in the vertical direction H. The second ball passage 242 is formed in a single-row state in the left-right direction W in one side frame portion 22 and in a double-row state in the front-rear direction D.

  The ball payout device 1 is arranged in the main body frame 2 with the adjacent direction B adjacent to the two ball flow-down passages 3 facing the left-right direction W in the gaming machine. In addition, between the lower end portion of the second ball passage 242 and the entrance portion of the ball dispensing device 1 (the entrance portion 35 of the ball flow down passage 3), the flowing state of the game ball X is changed to two in the front-rear direction D. There is provided a torsion passage 243 for changing from the lined down state to the lined down state in the left-right direction W.

The case portion 11 of the ball dispensing device 1 of this example is formed to have a width necessary for forming the two ball flow-down passages 3. That is, as shown in FIGS. 2 to 4, the case portion 11 of this example is formed so that the width in the left-right direction W (adjacent direction B) is about 30 mm and the width in the front-rear direction D is about 60 mm. is there. And the ball dispensing apparatus 1 which formed the external shape with the case part 11 has a substantially rectangular parallelepiped shape.
Further, the ball dispensing device 1 of the present example can enlarge the dimension in the left-right direction W of the opening region 201 in the main body frame 2 by reducing the width in the left-right direction W (adjacent direction B). Thereby, the opening area | region 201 by the side of the back surface of the game board in the main body frame 2 can be expanded. Therefore, it is possible to improve the degree of freedom of arrangement of game parts to be arranged in the game area, and it is possible to arrange a large liquid crystal display unit or the like in the game area. In addition, by reducing the width in the front-rear direction D, it is possible to avoid interference with a structure such as a pillar on the island facility (game hall) side where the gaming machine is installed.

  As shown in FIGS. 1 and 2, the two ball flow-down passages 3 meander and form so as to disperse the ball pressure of the game ball X flowing down the ball flow-down passage 3. That is, by forming the ball flow lower passage 3 meandering, a part of the ball pressure of the game ball X in the downward direction (gravity direction) can be dispersed in the ball pressure in the horizontal direction. Further, the ball flow down passage 3 of this example is formed by meandering in the horizontal direction at intervals of about one game ball X. Thereby, the ball pressure of the game ball X applied to the ball payout cam 61 is reduced. In addition, a central partition wall 33 is provided between the two ball flow passages 3.

  As shown in FIGS. 1 and 5, the ball payout cam 61 of this example is integrally formed on the rotating shaft 6 side by side in the axial direction of the rotating shaft 6. In the case portion 11, the game ball X held by the ball holding portion 611 of the ball payout cam 61 is placed between the two ball flow down passages 3 and the ball payout passage 4 along the transfer direction of the ball payout cam 61. A guide passage 5 for feeding out is formed. The guide passage 5 is formed by a guide upper surface 51 on which the game ball X is placed and rolled, and two notch grooves 52 formed below the guide upper surface 51 in order to place the ball payout cam 61, respectively. It is. Each notch groove 52 is provided with a ball payout cam 61, and the game ball X held by the ball holding portion 611 of the ball payout cam 61 receives the rotational force of the ball payout cam 61 and receives a guide passage. 5 is configured to roll along a notch groove 52 that forms the shape 5.

  The ball payout cam 61 of the present example is formed with concave ball holding portions 611 for holding the game ball X at equal intervals in the circumferential direction, and in a portion where the ball holding portion 611 is not formed, A convex outer peripheral portion 612 is formed. In addition, the ball holding portion 611 and the outer peripheral portion 612 of this example are formed at three locations at 120 ° intervals in the circumferential direction, and six games are achieved by one rotation of the rotating shaft 6 (ball payout cam 61). The ball X is configured to be paid out.

Further, in the two ball payout cams 61 adjacent to each other, the outer peripheral portion 612 of the other ball payout cam 61 faces the position facing the ball holding portion 611 of the one ball payout cam 61.
The ball payout cam 61 has an outer peripheral portion 612 protruding from the guide upper surface 51 of the guide passage 5 and a bottom portion of the ball holding portion 611 positioned below the guide upper surface 51 of the guide passage 5. It is rotatably arranged with respect to a passage forming member 53) which will be described later.

  With this configuration, when the game ball X is held by the ball holding portion 611, it is placed on the guide upper surface 51 and is not placed on the rotating shaft 6. As a result, of the two ball flow down passages 3, at least the ball flow down passage 3 on the side facing the ball holding portion 611 faces the rotating shaft 6 of the game ball X continuously supplied from the upstream side. It is possible to prevent the ball pressure from being applied directly. Thereby, it is possible to prevent an excessive load from being applied to the ball dispensing cam 61, and the ball dispensing cam 61 can be stably rotated.

As shown in FIG. 5, the guide wall portion 31 of this example is a downstream portion of the two ball flow down passages 3 in the case portion 11, and on both sides in the adjacent direction B (both surfaces of the case portion 11). The case portion 11 is formed so as to protrude toward the center side. The guide wall portion 31 has a curved upper surface for guiding the game ball X to the center side in the adjacent direction B.
As shown in FIG. 1, in the case portion 11 of this example, a passage forming member 53 for forming the guide passage 5 is provided, and the passage forming member 53 is formed in the center by forming two notch grooves 52. It has a central vertical wall portion 531 located on the side, and side vertical wall portions 532 formed on both sides of the central vertical wall portion 531.

  The central vertical wall portion 531 is formed with a mixed flow preventing projection 533 that protrudes upward and prevents the game ball X from flowing from one guide passage 5 to the other guide passage 5. The mixed flow preventing projection 533 is formed at a position below the spherical flow lower passage 3 in the guide passage 5. The mixed ball preventing projection 533 and the lower end portion of the central partition wall 33 cause the gaming ball X to enter the other guiding upper surface 51 from one guiding upper surface 51 due to the downward flow, for example. Preventing the game ball X from flowing from one guide upper surface 51 to the other guide upper surface 51 by abutting against the mixed flow preventing projection 533 and the lower end of the central partition wall 33 and blocking the entry. Can do. In addition, it is possible to prevent one game ball X from coming into contact with the outer peripheral portion 612 of the other ball payout cam 61. As a result, it is possible to prevent the ball payout cam 61 from being unintentionally applied with a ball pressure and causing a problem in the payout of the game ball X.

  As shown in FIGS. 1 and 4, the converging wall portion 41 of this example is formed in an upstream portion of the ball payout passage 4. The convergent wall portion 41 is formed by reducing the distance between the wall surfaces on both sides in the adjacent direction B downward. The inclination angle of the wall surfaces on both sides in this example is approximately 15 to 30 ° with respect to the vertical direction (vertical direction), and is the same on the wall surfaces on both sides.

As shown in FIG. 2, the intermediate gear 72 of this example is larger than the diameters of the drive gear 71 and the driven gear 73, the intermediate gear 72 meshes obliquely below the driven gear 73, and the drive gear 71 is connected to the intermediate gear 72. 72 is engaged obliquely below. A part 721 of the intermediate gear 72 of this example is exposed from the case portion 11, and when maintenance such as ball clogging becomes necessary, the intermediate gear 72 is rotated by manual operation so that the ball dispensing cam 61 is rotated. It can be rotated.
As shown in FIG. 3, the drive gear 71 of this example is directly provided on the output shaft of the motor 62 as the drive source 62, and the drive gear 71, the intermediate gear 72, and the driven gear 73 are arranged in the adjacent direction B in the case portion 11. It is arrange | positioned in the vicinity of the side part of one side.

  The ratio of the diameters of the gears 71, 72, 73 is drive gear 71: intermediate gear 72: driven gear 73 = 1: 3: 1. Further, when a plurality of intermediate gears 72 are provided, rattling due to meshing such as backlash tends to occur, and the rotation control of the rotating shaft 6 may be unstable. On the other hand, only one intermediate gear 72 of this example is provided between the drive gear 71 and the driven gear 73, and the rotation control of the rotary shaft 6 can be stabilized.

As shown in the figure, the motor 62 of this example has an axial width that is smaller than the width in the adjacent direction B of the case portion 11 (the width required to form the two ball flow-down passages 3). And in the state arrange | positioned in the case part 11, most are settled in the width | variety in the adjacent direction B of the case part 11. FIG.
As shown in FIGS. 2 and 3, the case portion 11 is rotatably provided with a rotation detection gear 74 that rotates in mesh with the drive gear 71 and detects the rotation position of the motor 62. is there. The rotation detection gear 74 is formed with slits or holes at a plurality of locations in the circumferential direction. A light emitting portion and a light receiving portion are provided on both sides of the rotation detection gear 74 around the rotation detection gear 74. A rotational position detection sensor 82 such as a photo interrupter is provided.

  In the ball dispensing apparatus 1 of this example, the rotation detection gear 74 and the rotation position detection sensor 82 are used by utilizing the region in the case portion 11 by using the rotation detection gear 74 that meshes with the drive gear 71. Can be arranged. Thereby, it is possible to suppress the rotation detecting gear 74 and the rotation position detecting sensor 82 from protruding outward from the case portion 11, and to reduce the size of the ball dispensing device 1. Further, since the rotation of the output shaft of the drive source 62 is detected using the rotation detection gear 74, the rotational position of the drive source 62 can be detected appropriately, and problems such as step-out of the drive source 62 can be promptly detected. Can be detected.

  Further, since the ratio between the drive gear 71 and the driven gear 73 is 1: 1, the amount of rotation of the drive gear 71 and the driven gear 73 can be made the same. Thus, by detecting the rotational position of the drive gear 71 (drive source 62), the rotational position (rotation amount) of the driven gear 73 (rotary shaft 6) can be indirectly detected correctly. In this example, the ratio of the diameters of the rotation detection gear 74 and the drive gear 71 is also 1: 1. Thereby, it is comprised so that the rotation amount of each gear 71, 73, 74 may become the same.

A ball detection sensor 81 for detecting the game ball X flowing down the ball payout passage 4 is provided at a position below the rotation shaft 6 provided with the two ball payout cams 61 and the driven gear 73. The ball detection sensor 81 has a detection port 811 for allowing the game ball X to pass therethrough, and is configured to transmit the number of game balls X passing through the detection port 811 to the control device of the game machine. is there.
As shown in FIG. 5, the arrangement center interval B <b> 1 of the ball payout cam 61 of this example is smaller than the arrangement center interval B <b> 2 of the two ball flow-down passages 3. That is, the arrangement center interval B1 of the ball payout cam 61 of this example is smaller than the size of one game ball (about 11 mm) (about 8 mm in this example), and the two ball payout cams 61 are These are arranged at symmetrical positions around the center position (the central partition wall 33) in the adjacent direction B.

As described above, the ball payout device 1 of the gaming machine of this example is formed with the guide passage 5 between the two ball flow-down passages 3 and the one ball payout passage 4, and the formation portion of the guide passage 5 is formed. The ball payout cam 61 is arranged corresponding to the two ball flow-down passages 3. In addition, a guide wall portion 31 is provided in the downstream portion of the two ball flow passages 3, and a converging wall portion 41 is provided in the upstream portion of the ball payout passage 4.
The ball payout device 1 of the present example is configured to converge the flowing-down state of the game ball X in two stages at the upstream position and the downstream position with respect to the ball payout cam 61. In the arranged guide passage 5, the game ball X does not converge in the flow-down state.

  When the game payout device 1 pays out the game ball X, the game ball X flowing down the two ball flow down passages 3 is one game ball X flowing down through the ball flow down passage 3 on the other side. While being held by the ball holding portion 611 in the payout cam 61, the game ball X flowing down the other ball flow down passage 3 is prevented from flowing down by the outer peripheral portion 612 in the other ball payout cam 61. At this time, the game ball X held by the ball holding portion 611 of the ball payout cam 61 is converged at the first stage by the guide wall portion 31 in the ball flow down passage 3 in the adjacent direction B (two ball flow down passages 3 are (Directions adjacent to each other).

  When the two ball payout cams 61 provided on the rotating shaft 6 are rotationally driven by the motor 62, the game ball X held by the ball holding portion 611 in the one ball payout cam 61 is moved along the guide passage 5. The ball holding portion 611 is transferred in the rotating direction, and the game ball X flowing down the other ball flow down passage 3 flows down to the guide passage 5 and is held by the ball holding portion 611 in the other ball payout cam 61. . At this time, after being transferred along the guide passage 5, the game balls X released and discharged from the ball holding portion 611 are converged in the second stage by the converging wall portion 41 in the ball dispensing passage 4 as a second stage of convergence. It is brought closer to the center side of. Thereafter, the rotation driving is continuously performed, so that the game ball X held by the ball holding portion 611 of the other ball payout cam 61 is transferred along the guide passage 5 and discharged in the same manner.

  Thus, in this example, the game balls X flowing down the two ball flow passages 3 can be alternately paid out to the ball payout passage 4 by the pair of ball payout cams 61, and the upstream position relative to the ball payout cam 61 And the downstream position, the game ball X can be converged in two stages. Thereby, an excessive load due to frictional resistance or the like when converging the flow-down state of the game ball X is dispersed. At the same time, when the game ball X is transferred by the ball payout cam 61, force is applied to the game ball X only in the transfer direction, and no force in the direction different from the transfer direction, ie, the convergence direction, is applied. The pair of ball payout cams 61 can alternately and stably pay out the game balls X to the ball payout passage 4.

  Therefore, according to the ball dispensing device 1 of the gaming machine of the present example, an excessive load is prevented from being applied to the pair of ball dispensing cams 61, and the ball dispensing passages 61 are alternately and stably stabilized by the pair of ball dispensing cams 61. Then, the game ball X can be paid out.

  In addition, with respect to the converging wall portion 41 that is the second-stage converging mechanism, a part of the converging process has already been completed by the guide wall portion 31 that is the first-stage converging mechanism. The convergence length can be shortened and made compact, and the convergence mechanism can be made smooth by reducing the convergence angle.

  Further, as described above, the ball dispensing device 1 of this example includes the case portion 11 that houses the rotating shaft 6, the motor 62, the drive gear 71, the driven gear 73, and the intermediate gear 72. The driven gear 73 is disposed in the gear housing portion 32 formed in the side region 311 of the guide wall portion 31 in the case portion 11. Thereby, the driven gear 73 provided on the rotating shaft 6 can be easily arranged by using the space as the gear housing portion 32 formed in the case portion 11. Here, the side region 311 of the guide wall portion 31 refers to a space region provided in the vicinity of the portion where the guide wall portion 31 is formed in the case portion 11, in other words, the guide wall portion 31. This refers to a space region formed in the peripheral part of the formation.

  Further, the ball payout passage 4 is formed in a state of being biased to one side portion 111 in the adjacent direction B in the case portion 11 after being converged into a single flow-down state by the converging wall portion 41. The motor 62 is arranged in a space 113 formed on the side of the other side 112 by the ball payout passage 4 formed to be biased toward the one side 111 in the adjacent direction B. Thereby, the motor 62 can be arranged using the space formed adjacent to the ball payout passage 4 in the case portion 11.

  Further, in the ball dispensing device 1 of this example, the drive source 62 is not directly connected to the rotary shaft 6, and the transmission of the rotational force by the drive source 62 to the rotary shaft 6 is transmitted to the drive gear 71 and the intermediate gear. 72 and a driven gear 73. And the drive source 62 is arrange | positioned in the ball dispensing apparatus 1 using the said space 113 as mentioned above. Therefore, the drive source 62 can be arranged so as not to protrude so much from the width dimension in the adjacent direction B of the two sphere lowering passages 3.

Further, in the ball dispensing device 1 of the present example, by forming the guide wall portion 31 in the case portion 11, a space region (gear housing portion 32) can be formed in the peripheral portion thereof. Then, the driven gear 73 provided on the rotating shaft 6 can be arranged using this space region, and it is not necessary to provide a region for arranging the driven gear 73 outside the case portion 11 separately.
Further, the rotational force of the drive source 62 is transmitted to the driven gear 73 by using the space region and the space region generated by converging the two ball flow-down passages 3 in the one ball discharge passage 4. Intermediate gear 72 can be arranged. Therefore, it is not necessary to separately provide a region for arranging the intermediate gear 72 outside the case portion 11.

  Therefore, in the case portion 11 of the ball dispensing device 1 of the present example, a width necessary for forming the two ball flow down passages 3 is secured, and the motor does not protrude so much from the range of the necessary width. In addition to 62, the rotation shaft 6, the drive gear 71, the driven gear 73, and the intermediate gear 72 can be arranged. Therefore, each component can be arranged in a limited space, and the ball dispensing device 1 can be reduced in size.

  Therefore, according to the ball payout device 1 of the gaming machine of this example, the ball payout device 1 does not protrude so much from the range of the width dimension in the adjacent direction B of the ball flow down passage 3 configured adjacent to the two strips. Therefore, the ball dispensing device 1 can be reduced in size.

  In addition, a ball removal mechanism can be appropriately provided in the ball flow down passage 3. In this case, in FIG. 2, the right side portion of the ball flow down passage 3 can be used as a ball removal passage. In the figure, the part where the ball removal mechanism is provided is indicated by symbol a, and the flow-down direction of the game ball X when the ball removal passage is formed is indicated by an arrow F. Moreover, in this case, the wall portion of the ball removal passage is formed by the wall portion on the side of the main body frame 2 by forming the ball removal passage in a U-shaped cross section and assembling the ball dispensing device 1 to the main body frame 2. be able to.

Further, the portion of the outer periphery 612 of the ball payout cam 61 where the game ball X comes into contact can be made into a smooth shape (R shape) to improve the durability of the ball payout cam 61 (the amount of wear can be reduced). ). In the ball dispensing device 1, a plurality of intermediate gears 72 may be provided instead of one.
Further, without using the gears 71, 72, and 73, the rotating shaft 6 having the two ball paying cams 61 can be provided directly on the output shaft of the drive source (motor) 62.
The above-described ball payout device 1 is not limited to a pachinko gaming machine, and can be applied to other gaming machines such as an arrangement ball gaming machine and a slot machine using a gaming ball as a gaming medium.

The perspective explanatory view showing the ball dispensing device in the example. Side explanatory drawing which shows the ball dispensing apparatus in an Example. It is a figure which shows the ball delivery apparatus in an Example, and is AA arrow sectional view explanatory drawing of FIG. It is a figure which shows the ball paying-out apparatus in an Example, and is the BB arrow directional cross-sectional explanatory drawing of FIG. Cross-sectional explanatory drawing which expands and shows the periphery of the ball payout cam in an Example. Explanatory drawing which shows the back surface part of the main body frame in the game machine in an Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Sphere delivery apparatus 11 Case part 2 Body frame 3 Sphere flow down path 31 Guide wall part 32 Gear accommodating part 4 Sphere delivery path 41 Converging wall part 5 Guide path 52 Notch groove 53 Path | route formation member 6 Rotating shaft 61 Sphere delivery cam 611 Sphere holding Part 612 Outer part 62 Drive source (motor)
71 Drive gear 72 Intermediate gear 73 Driven gear 74 Rotation detection gear 81 Ball detection sensor 82 Rotation position detection sensor X Game ball B Adjacent direction W Left and right direction D Front and rear direction

Claims (3)

Two ball flow passages formed adjacent to each other to allow the game balls to flow down;
A ball payout cam formed with a ball holding portion for holding a game ball;
A single ball payout passage for flowing down the game balls paid out by the ball payout cam;
Two of the ball payout cams are provided in the axial direction of the rotation shaft that is rotationally driven by the drive source corresponding to the two ball flow down passages, and the ball holding portions in the two ball payout cams are , Alternately formed in the circumferential direction,
In the downstream part of the two ball flow passages, a guide wall for guiding the game ball to the center side in the direction in which the two ball flow passages are arranged is provided.
Between the two ball flow down passages and the ball payout passage, there is a guide passage for sending the game balls held in the ball holding portion of the ball payout cam along the transfer direction of the ball payout cam. Formed,
A ball of a gaming machine characterized in that a converging wall portion for converging the game ball paid out by the ball paying cam into a single flowing-down state is provided in an upstream portion of the ball payout passage. Dispensing device.   2. The guide passage according to claim 1, wherein the guide passage is formed by a guide upper surface on which a game ball is placed and rolled, and two notch grooves formed downward from the guide upper surface for arranging the ball payout cams. A ball dispensing device for a gaming machine, characterized by In Claim 1 or 2, the above-mentioned two ball flow down passages, the above-mentioned guide passage, and the above-mentioned ball discharge passage are formed in a case part,
The ball payout cam, the drive source, a rotary shaft provided with the ball payout cam, a drive gear provided on the output shaft of the drive source, a driven gear provided on the rotary shaft, and rotation of the drive gear on the driven gear The intermediate gear for transmitting to is housed in the case part,
The driven gear is arranged in a gear accommodating portion formed in a side region of the guide wall portion in the case portion,
The ball payout passage is formed in a state of being biased to one side portion of the case portion after being converged into a single flow-down state by the converging wall portion, and the drive source is configured to be the one side portion A ball payout device for a gaming machine, characterized in that the ball payout device is arranged in a space formed on the other side portion by the ball payout passage formed so as to be biased toward the side.

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