JP2018201966A - Game machine - Google Patents

Abstract

To provide a game machine capable of rotating a rotor smoothly.SOLUTION: In a game machine 10, a gear 88 fixed to a rotating shaft 88S is engaged with an internal gear 89G provided in a block 85. When the rotating shaft 88S is driven to rotate and the gear 88 is rotated in one piece with the rotating shaft 88S, the block 85 is rotated. The game machine 10 includes a support member 121 that is in slide contact with the internal gear 89G and supports the block 85.SELECTED DRAWING: Figure 11

Description

  The present invention relates to a gaming machine.

  In the gaming machine disclosed in Patent Document 1, rotational force is transmitted from a plurality of gears meshed with an internal gear to a rotating body including the internal gear.

JP2015-204920A (paragraphs [0602] to [0604], FIGS. 89 and 90)

  In the gaming machine of Patent Document 1, unevenness occurs in the rotation of the plurality of gears, and it is difficult to smoothly rotate the rotating body.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a gaming machine that can smoothly rotate a rotating body.

  A first means is a gaming machine having a driving gear that is rotationally driven, and a rotating body that has an internal gear that meshes with the driving gear, and has a support member that supports the rotating body. It is.

  According to the said invention, it becomes possible to rotate a rotary body smoothly.

Front view of a gaming machine according to an embodiment of the present invention Front view of game board Front view of the game board in a state where the first movable part and the second movable part are arranged at the standby position Front view of mechanism frame with movable accessory unit attached Perspective view of movable accessory unit (A) Front view of the movable accessory unit when the movable base is disposed at the first rotational position, (B) Front view of the movable accessory unit when the movable base is disposed at the second rotational position. Schematic configuration diagram of linear motion drive mechanism Perspective view of movable stage (A) Cross-sectional view of a block arranged so that the first light-transmitting wall faces the front side, (B) Cross-sectional view of a block arranged so that the second light-transmitting wall faces the front side Block diagram showing electrical configuration of gaming machine Exploded perspective view of blocks constituting the rotating body The disassembled perspective view of the block arrange | positioned next to the block shown in FIG. Perspective view of second retaining ring, gear and intermediate sleeve Cross section of gear, idle gear and support member Sectional drawing which shows another example of a supporting member

  As shown in FIG. 1, the gaming machine 10 of the present embodiment is a pachinko gaming machine having a front frame 10 </ b> Z on the front surface and a game shown in FIG. 2 through a glass window 10 </ b> W formed in the front frame 10 </ b> Z. A game area R1 formed on the front surface of the board 11 is visible.

  An upper plate 26 and a lower plate 27 are provided in two upper and lower stages below the glass window 10W in the front frame 10Z, and a firing handle 28 is provided on the right side of the lower plate 27. Then, when the launch handle 28 is rotated, the game ball accommodated in the upper plate 26 is blown out toward the game area R1 (FIG. 2).

  As shown in FIG. 2, the entire game area R <b> 1 has a substantially circular shape and is surrounded by the guide rail 12. A display opening 11H is formed through the center of the game area R1 in the game board 11, and the display screen 13G of the display device 13 faces forward through the display opening 11H. Note that various effects relating to the game are displayed on the display screen 13G of the display device 13.

  A display decoration frame 23 is attached to the opening edge of the display opening 11H. Specifically, the display decoration frame 23 is fitted into the display opening 11H from the front side of the game board 11 and protrudes from the front surface of the game board 11, and a game ball flowing down the game area R1 enters the inside of the display decoration frame 23. It regulates that.

  An opening inside the display decoration frame 23 is formed in a horizontally long and substantially rectangular shape, and a stage 24 on which a game ball can roll is formed on the lower side of the display decoration frame 23. Further, a warp path 24 </ b> R for receiving a game ball flowing down the game area R <b> 1 and guiding it to the stage 24 is formed on the side of the display decoration frame 23.

  On the lower side of the display decoration frame 23, first and second start winning ports 14A and 14B are provided side by side. A start gate 18 is provided on the right side of the display decoration frame 23. A large winning opening 15 is provided on the lower right side of the display decoration frame 23, that is, on the right side of the first and second starting winning openings 14A and 14B. In addition to the start winning ports 14A and 14B and the big winning port 15, the game area R1 includes a plurality of general winning ports 20.

  The general winning opening 20 has a size that allows one game ball to enter one by one and opens upward or sideward. When a game ball enters (wins) the general winning opening 20, the game ball is taken into the rear side of the game board 11, and, for example, 15 prize balls are paid out to the upper plate 26 for each entered ball.

  The start gate 18 has a portal structure through which game balls can pass. When the game ball passes through the start gate 18, a normal symbol success / failure determination is performed. The result of the normal symbol success / failure determination is displayed on the normal symbol display unit 18H.

  The first start winning opening 14A is formed in a pocket structure, and opens upward in such a size that game balls can enter one by one. The second start winning opening 14B has a size that allows one game ball to enter one by one and opens forward. Normally, the front is closed by the open / close door 14T, so that a game ball can be entered ( (Winning) is regulated. The opening / closing door 14T rotates about the lower end portion and is tilted forward by a predetermined time when the above-described normal symbol determination result is successful. Then, the game ball received by the open / close door 14T can enter the second start winning opening 14B.

  When a game ball enters the winning prize opening 14A, 14B (wins), a predetermined number of prize balls are paid out to the upper plate 26 and a special symbol determination is made. The result of the special symbol success / failure determination is displayed on the special symbol display unit 14H and also on the display screen 13G of the display device 13. If the result of the special symbol success / failure determination is a win, a big hit game is executed. Note that, on the display screen 13G, for example, a symbol composed of numbers, characters, and the like is changed and stopped, and the result of the special symbol success / failure determination is displayed by the combination of the stopped symbols.

  The special winning opening 15 has a horizontally long rectangular shape, and is closed by the movable door 15T in a normal gaming state. When the above jackpot game is executed, the movable door 15T is brought down to the front side over a predetermined period. Then, the grand prize opening 15 is opened forward, and a large number of game balls can be awarded to the big prize opening 15 with the movable door 15T as a guide. When a game ball wins the big winning opening 15, a predetermined number of winning balls are paid out to the upper plate 26.

  All the game balls that have not won any of the above-described winning ports 14A, 14B, 15, 20 are all taken into the out port 16 provided at the lower end of the gaming area R1. The game balls taken into the out port 16 are collected by a ball collection device (not shown).

  A mechanism frame 17 shown in FIG. 4 is provided on the back side of the game board 11. Various parts including the movable accessory unit 40 are fixed to the mechanism frame 17. The opening 17A inside the mechanism frame 17 is overlapped with the display opening 11H (see FIG. 2) of the game board 11 so that the display screen 13G of the display device 13 is visible.

  As shown in FIGS. 4 and 5, the movable accessory unit 40 includes a fixed base 41 and a movable base 51. The fixed base 41 is formed in a frame shape having a substantially circular opening 41 </ b> A on the inner side, and is fixed to the mechanism frame 17 by being overlapped from the front side. The movable base 51 has a substantially circular shape, is fitted inside the opening 41 </ b> A of the fixed base 41, and is configured to be rotatable with respect to the fixed base 41. In the present embodiment, the fixed base 41 and the movable base 51 are formed to be colorless and transparent so that the display screen 13G can be viewed through the fixed base 41 and the movable base 51.

  Specifically, external teeth 51 </ b> G are formed on a part of the outer peripheral surface of the movable base 51. As shown in FIG. 6A, the external gear 51G of the movable base 51 is engaged with a drive gear 42 that is rotatably supported by the fixed base 41. The drive gear 42 is driven by a base drive source 43 (see FIG. 5) provided in the fixed base 41.

  The movable base 51 is normally arranged at the first rotation position shown in FIG. 6A, and is driven between the first rotation position and the second rotation position shown in FIG. Move between. The second rotational position is shifted by about 90 degrees in the clockwise direction with respect to the first rotational position when viewed from the front. Here, a rectangular window 51A is formed at the center of the movable base 51. When the movable base 51 is arranged at the first rotation position or the second rotation position, the window 51A is displayed on the display screen. It overlaps with the central part of 13G (see FIG. 2).

  As shown in FIG. 5, the movable base 51 includes a first movable part 61 and a second movable part 62, and a first movable part 61 and a second movable part 62, which are opposed to each other with the window 51A interposed therebetween. A linear motion drive mechanism 70 is mounted so as to approach and separate in the opposite direction. Note that the first movable portion 61 and the second movable portion 62 are normally disposed at a standby position that is farthest in the facing direction (see FIG. 3), and are disposed at the closest combined position by the linear motion drive mechanism 70. (See FIG. 2).

  Each of the first movable part 61 and the second movable part 62 includes inner movable bodies 61A and 62A disposed on the inner side in the facing direction, and outer movable bodies 61B and 62B disposed on the outer side in the facing direction. It has been. When the movable base 51 is disposed at the first rotation position, the first movable portion 61 and the second movable portion 62 face each other in the vertical direction, and the first movable portion 61 is located above the second movable portion 62. Arranged (FIG. 6A). Further, when the movable base 51 is disposed at the second rotational position, the first movable portion 61 and the second movable portion 62 face each other in the left-right direction, and the first movable portion 61 is on the right side with respect to the second movable portion 62. Arranged (FIG. 6B). Hereinafter, the inner movable body 61A and the outer movable body 61B of the first movable section 61 are appropriately referred to as a first inner movable body 61A and a first outer movable body 61B, and the inner movable body 62A and the outer movable body of the second movable section 62 are referred to as appropriate. 62B will be appropriately referred to as a second inner movable body 62A and a second outer movable body 62B.

  As shown in FIG. 7, the movable bodies 61 </ b> A and 61 </ b> B of the first movable section 61 and the movable bodies 62 </ b> A and 62 </ b> B of the second movable section 62 are opposed to the first movable section 61 and the second movable section 62. The first plate part 64 and the second plate part 65 that extend in the direction from the first plate part 64 to the second plate part 65, and the movable effect part 63 provided between the first plate part 64 and the second plate part 65 are provided. The first plate part 64 and the second plate part 65 are arranged so as to sandwich the window part 51 </ b> A of the movable base 51 in the extending direction of the movable effect part 63. FIG. 7 shows only the first outer movable body 61B and the second outer movable body 62B.

  In the first movable part 61, the first plate part 64 is arranged on one side in the extending direction of the movable effect part 63, and the second plate part 65 is arranged on the other side. On the other hand, in the second movable portion 62, the second plate portion 65 is disposed on one side in the extending direction of the movable effect portion 63, and the first plate portion 64 is disposed on the other side. Between the 1st movable part 61 and the 2nd movable part 62, it arrange | positions so that the 1st plate part 64 and the 2nd plate part 65 may face | abut, and the 1st movable part 61 and the 2nd movable part 62 were the closest Sometimes, the first plate part 64 of the first movable part 61 and the second plate part 65 of the second movable part 62 are arranged in the extending direction of the movable effect part 63, and the second plate part 65 of the first movable part 61 is arranged. The first plate part 64 of the second movable part 62 is arranged in the extending direction of the movable effect part 63.

  In the first movable portion 61, the first plate portion 64 of the first inner movable body 61A and the first plate portion 64 of the first outer movable body 61B are overlapped, and the second plate of the first inner movable body 61A. The portion 65 and the second plate portion 65 of the first outer movable body 61B are overlapped (see FIG. 5). Similarly, in the second movable portion 62, the first plate portion 64 of the second inner movable body 62A and the first plate portion 64 of the second outer movable body 62B are overlapped and the second plate of the second inner movable body 62A is overlapped. The plate portion 65 and the second plate portion 65 of the second outer movable body 62B are overlapped.

  As shown in FIG. 7, elongated holes 64N and 65N extending in the extending direction are formed in the first plate portion 64 and the second plate portion 65. A support shaft portion 66 fixed to the movable base 51 is inserted through the long holes 64N and 65N, so that the first plate portion 64 and the second plate portion 65 can move linearly in their extending directions. It has become. Further, racks 64R and 64R are formed on both sides of the first plate portion 64, and a rack 65R is formed on a portion of the second plate portion 65 opposite to the first plate portion 64.

  As shown in FIGS. 4, 5, and 7, the linear motion drive mechanisms 70 are provided in pairs so as to sandwich the window portion 51 </ b> A of the movable base 51 in the extending direction of the movable effect portion 63. Each linear drive mechanism 70 includes an inner movable body drive source 71A for driving the first inner movable body 61A and the second inner movable body 62A, a first outer movable body 61B, and a second outer movable body 62B. The outer movable body drive source 71B for driving, and the drive gears 72 and 72 rotated by the respective drive sources 71A and 71B (in FIG. 7, the drive gear 72 rotated by the outer movable body drive source 71B). Only is shown).

  As shown in FIG. 7, the drive gear 72 meshes with a rack 64 </ b> R disposed on the opposite side of the second plate portion 65 among the racks 64 </ b> R and 64 </ b> R of the first plate portion 64. Specifically, the drive gear 72 of one of the pair of linear motion drive mechanisms 70, 70 (the direct motion drive mechanism 70 on the right side in FIG. 7) is movable by the first movable portion 61. The drive gear 72 of the other direct acting drive mechanism 70 (the left direct acting drive mechanism 70 in FIG. 7) meshes with the rack 64 </ b> R of the first plate portion 64 in the bodies 61 </ b> A and 61 </ b> B. The movable bodies 62A and 62B mesh with the rack 64R of the first plate portion 64.

  Further, one linear motion drive mechanism 70 is sandwiched between the first plate portion 64 of the first movable portion 61 and the second plate portion 65 of the second movable portion 62, and the rack of the first plate portion 64. A relay gear 73 that meshes with both 64R and the rack 65R of the second plate portion 65 is provided. The other linear motion drive mechanism 70 is sandwiched between the second plate portion 65 of the first movable portion 61 and the first plate portion 64 of the second movable portion 62, and the rack 64R of the first plate portion 64 A relay gear 73 that meshes with both the racks 65R of the second plate portion 65 is provided.

  When the drive gear 72 is rotationally driven by the outer movable body drive source 71B in the pair of linear drive mechanisms 70, 70, as shown by the arrows in FIG. 7, the first plate portion of the first outer movable body 61B. 64 and the first plate portion 64 of the second outer movable body 62B move in the opposite direction along the long hole 64N. Note that the rotation direction of the drive gear 72 is the same in the pair of linear drive mechanisms 70, 70.

  When the first plate portion 64 of the first outer movable body 61B moves along the elongated hole 64N, the relay gear 73 rotates with the movement, and the second plate portion 65 of the second outer movable body 62B moves to the first. It moves in the direction opposite to the plate part 64. Here, since the movement direction of the second plate portion 65 of the second outer movable body 62B is the same as the movement direction of the first plate portion 64 of the movable body 62B, the second outer movable body 62B has 2 It is driven by the two outer movable body drive sources 71B, 71B.

  When the first plate portion 64 of the second outer movable body 62B moves along the long hole 64N, the relay gear 73 rotates with the movement, and the second plate portion 65 of the first outer movable body 61B It moves in the direction opposite to the first plate portion 64. Here, since the moving direction of the second plate portion 65 of the first outer movable body 61B is the same as the moving direction of the first plate portion 64 of the movable body 61B, the first outer movable body 61B has 2 Driven in the opposite direction to the second outer movable body 62B by the two outer movable body drive sources 71B, 71B.

  The driving of the first inner movable body 61A and the second inner movable body 62A is the same as the driving of the first outer movable body 61B and the second outer movable body 62B. Then, the linear drive mechanism 70 drives the first inner movable body 61A and the second inner movable body 62A in the opposite directions in the same manner as the driving of the first outer movable body 61B and the second outer movable body 62B.

  As shown in FIGS. 5 and 8, the movable effector 63 includes a prismatic rotator 81, a pair of supports 82 and 82 that support the rotator 81 in the axial direction, and the back side of the rotator 81. And a communication member 83 that communicates with the pair of supports 82, 82. One support body 82 is provided with a rotation drive source 81K that rotates the rotation body 81 around a central axis 81J (see FIG. 8) of the rotation body 81. The rotating body 81 is configured by arranging a plurality of blocks 85, and the connecting member 83 is provided with a partition plate 84 that partitions between the blocks 85 and between the block 85 and the support 82.

  As shown in FIGS. 9A and 9B, each block 85 of the rotating body 81 has a structure in which a light emitting substrate 87 is provided inside a rectangular tube body 86. Both ends of the rectangular cylinder 86 are closed by end walls 89 having a circular opening 89A, and an internal gear 89G is formed on the inner peripheral surface of the circular opening 89A. The end wall 89 is rotatably supported by the partition plate 84. A gear 88 that meshes with the internal gear 89G is provided inside the rectangular tube 86. The gear 88 is fixed to a rotating shaft 88S that penetrates the rotating body 81. The rotary shaft 88S is supported by the partition plate 84 and is rotationally driven by a rotational drive source 81K.

  A plurality of light emitting elements 87 </ b> A are mounted on the light emitting substrate 87. In addition, a first light transmission wall 86A and a second light transmission wall 86B are provided on the peripheral wall of the rectangular tube body 86. Then, when the first light transmitting wall 86A or the second light transmitting wall 86B is disposed to face the light emitting element 87A, the light from the light emitting element 87A is recognized by the player. Here, the first light transmitting wall 86A and the second light transmitting wall 86B are disposed to face each other, and usually, the first light transmitting wall 86A is disposed to face the light emitting element 87A (FIG. 9A). . When the rotating body 81 rotates and the second light transmitting wall 86B is disposed opposite the light emitting element 87A, the light of the light emitting element 87A can be recognized by the player through the second light transmitting wall 86B (FIG. 9 ( B)).

  FIG. 10 shows an electrical configuration of the gaming machine 10. In the figure, reference numeral 150 denotes a main control circuit 150, which includes a microcomputer having a CPU 150A, a RAM 150B, a ROM 150C and a plurality of counters, an input / output circuit connecting the microcomputer and the sub-control circuit 152, and a prize winning device. Etc. are connected to an input / output circuit connecting a relay circuit and a payout control circuit, etc., to perform main control related to the game. The CPU 150A includes a determination unit, a control unit, a calculation unit, various counters, various registers, various flags, etc., and performs calculation control, and also generates random numbers related to special symbol determination and normal symbol determination and generates control signals. It is configured to be able to output (transmit) to the sub-control circuit 152 and the like. The RAM 150B includes a storage area for various random values generated by the CPU 150A, a storage area and a flag for temporarily storing various data, and a work area for the CPU 50A. In ROM 150C, control data, special symbol and symbol variation data relating to variation display of normal symbols, and the like, special symbol success / failure determination and normal symbol success / failure determination values, and the like are written.

  Similarly to the main control circuit 150, the sub control circuit 152 includes a microcomputer including a CPU 152A, a RAM 152B, a ROM 152C, and a plurality of counters, an input / output circuit connecting the microcomputer and the main control circuit 150, a display control circuit 154, An input / output circuit for connecting the lamp control circuit 155, the movable accessory unit 40, and the like is provided. The CPU 152A includes a control unit, a calculation unit, various counters, various registers, various flags, etc., and performs calculation control, and outputs (transmits) control signals to the display control circuit 154, the lamp control circuit 155, the movable accessory unit 40, and the like. ) Is configured to be possible. The RAM 152B has a storage area for various data and a work area for the CPU 152A. The ROM 152C stores various production data and the like.

  The sub-control circuit 152 controls the movable base 51, the first movable body drive source 71 </ b> A, the outer movable body drive source 71 </ b> B, and the rotational drive source 81 </ b> K of the movable accessory unit 40, The movable bodies 61A, 61B, 62A, and 62B of the movable section 61 and the second movable section 62 and the rotating bodies 81 in the movable bodies 61A, 61B, 62A, and 62B are driven and controlled.

  The display control circuit 154 is provided in the display device 13 and includes a CPU 154A, a RAM 154B, and a ROM 154C. The CPU 154A acquires image data from the ROM 154C based on the control signal from the sub control circuit 152, and displays an image on the display screen 13G based on the image data.

  The lamp control circuit 155 performs on / off control of the light emitting element 87A (see FIG. 9A) mounted on the light emitting substrate 87 of the decorative lamp or the movable accessory unit 40 based on the control signal from the sub control circuit 152.

<Details of block drive mechanism>
Below, the detail of the drive mechanism of the rotary body 81 in each movable body 61A, 61B, 62A, 62B of the 1st movable part 61 and the 2nd movable part 62 is demonstrated. As described above, the rotating body 81 includes a plurality of blocks 85, and the gears 88 meshing with the internal gears 89G formed on the end wall 89 of each block 85 are rotationally driven, whereby each block 85 is rotated. Rotates (FIGS. 5 and 9 (A)). As shown in FIG. 11, two rotary shafts 88 </ b> S and one support shaft 120 are inserted inside each block 85. The three shafts 88S, 88S, 120 are supported by the above-described partition plate 84 (see FIG. 8) and are arranged at equal intervals around the central axis 81J of the rotating body 81 (see FIG. 14). Specifically, the partition plate 84 is formed with a pair of rotation shaft insertion holes 84A and 84A and a support shaft insertion hole 84B. The rotation shaft 88S is inserted into the rotation shaft insertion hole 84A, and the support shaft is inserted. The support shaft 120 is inserted through the insertion hole 84B. The partition plate 84 is provided with a substrate insertion hole 84K through which the light emitting substrate 87 is inserted, and one light emitting substrate 87 is arranged inside the plurality of blocks 85.

  As shown in FIG. 11, the gear 88 is fixed to one of the two rotating shafts 88 </ b> S and 88 </ b> S via a retaining ring 90. Here, the gear 88 is an internal gear 89G, 89G formed on a pair of end walls 89, 89 (only one end wall 89 is shown in FIG. 11) of each block 85. Each block 85 is provided with a pair so as to mesh with each other. Each gear 88 is sandwiched between the retaining ring 90 and the partition plate 84 (only one partition plate 84 is shown in FIG. 11) in the axial direction of the rotary shaft 88S.

  The retaining ring 90 is formed in a C shape in which a part of the annular ring in the circumferential direction is cut out, and extends in a direction crossing the rotating shaft 88S at a position shifted by 180 degrees in the circumferential direction on the outer peripheral surface of the rotating shaft 88S. A pair of mounting grooves 90M, 90M (only one mounting groove 90M is shown in FIG. 11) is engaged with engaging end portions 90K, 90K constituting both ends of the C-shaped shaft, thereby rotating the shaft. It is fixed to 88S. Then, when the engaging end 90K of the retaining ring 90 comes into contact with the bottom of the mounting groove 90M, the retaining ring 90 rotates integrally with the rotary shaft 88S.

  The two retaining rings 90 disposed in each block 85 include a first retaining ring 91 and a second retaining ring 92. Both the first retaining ring 91 and the second retaining ring 92 are provided on the opposite side of the C-shaped opening from the engagement projection 90T projecting toward the gear 88 (the engagement projection 90T of the second retaining ring 92 is illustrated in FIG. 13). Here, the gear 88 has external teeth 88H formed only on the outer peripheral portion of one axial portion (the lower portion of the gear 88 in the example of FIG. 13), and the other axial portion is An engaging recess 88A that is open to the other side in the axial direction and the outer side in the radial direction is formed in the base portion 88B to be formed. Then, the engaging projection 90T of the retaining ring 90 engages with the engaging recess 88A of the gear 88, so that the gear 88 rotates integrally with the retaining ring 90 (the first retaining ring 91 and the second retaining ring 92). Is possible.

  As shown in FIG. 13, the second retaining ring 92 has a stepped portion 93 at an intermediate position in the axial direction, and a large diameter portion 94 closer to the gear 88 with respect to the stepped portion 93 and a stepped portion 93. On the other hand, a small-diameter portion 95 far from the gear 88 is formed. The engagement protrusion 90T described above is provided in the large diameter portion 94. On the other hand, the first retaining ring 91 does not have the stepped portion 93 and has substantially the same diameter as the large-diameter portion 94 of the second retaining ring 92 over the entire axial direction (FIG. 11).

  As shown in FIG. 11, an intermediate sleeve 100 sandwiched between the first retaining ring 91 and the second retaining ring 92 is inserted through the rotating shaft 88 </ b> S to which the gear 88 is attached. The intermediate sleeve 100 has a structure in which one end of a cylinder is expanded in diameter, and includes a cylindrical sleeve main body 101 and a cap portion 102 having a larger diameter than the sleeve main body 100. The sleeve body 101 has substantially the same diameter as the small diameter portion 95 of the second retaining ring 92, and the cap portion 102 has substantially the same diameter as the large diameter portion 94 of the second retaining ring 92. Then, the cap portion 102 of the intermediate sleeve 100 is put on the small diameter portion 95 of the second retaining ring 92, so that the opening of the second retaining ring 92 is suppressed. The intermediate sleeve 100 is formed to have substantially the same length as the distance between the first retaining ring 91 and the second retaining ring 92, and is sandwiched between the first retaining ring 91 and the second retaining ring 92, thereby rotating the shaft. The movement in the axial direction of 88S is restricted. Thereby, the movement of the cap part 102 in the axial direction of the rotating shaft 88S is also restricted, and the cap part 102 is prevented from coming off from the small diameter part 95 of the second retaining ring 92.

  As shown in FIG. 11, the idle gear 110 is rotatably attached to the other rotary shaft 88S of the two rotary shafts 88S, 88S. Specifically, a pair of idling gears 110 and 110 are inserted into the other rotating shaft 88S, and each idling gear 110 is abutted against the partition plate 84 and has an internal gear 89G on the end wall 89. Mesh with. The pair of idle gears 110 and 110 are positioned by a cylindrical spacer 111 inserted through the other rotary shaft 88S. The idle gear 110 has the same structure as the gear 88, and has external teeth 110H only on one side in the axial direction.

  As shown in FIG. 11, a support member 121 is inserted through the support shaft 120. The support member 121 has a structure in which an overhang portion 123 projects laterally from both ends of the sleeve 122 through which the support shaft 120 is inserted. The length of the sleeve 122 is substantially the same as the interval between the two adjacent partition plates 84. The overhang portion 123 is provided with an engagement protrusion 123T that engages with an engagement hole 84C formed in the partition plate 84, and the engagement protrusion 123T engages with the engagement hole 84C. The overhang portion 123 is fixed to the partition plate 84. In detail, the support member 121 can be divided into a pair of divided bodies 121 </ b> A and 121 </ b> A in the axial direction of the support shaft 120. The overhang portion 123 is provided in each of the one divided body 121A and 121A, and each divided body 121A engages with the partition plate 84.

  As shown in FIG. 14, the overhang portion 123 can be slidably contacted with the internal gear 89 </ b> G of the block 85 from the inside. Specifically, the projecting portion 123 is formed with a circular arc surface 123M that is inscribed at the tips of the plurality of internal teeth of the internal gear 89G.

  FIG. 12 shows the internal structure of the block 85 adjacent to the block 85 shown in FIG. Here, one of the two rotary shafts 88S, 88S is referred to as a first rotary shaft 88SA, and the other rotary shaft 88S is referred to as a second rotary shaft 88SB. The arrangement of the gear 88 and the structure of the first shaft 88SA and the second shaft 88SB are different. Specifically, in the block 85 shown in FIG. 11, the gear 88 is fixed to the first rotating shaft 88SA, and the idle gear 110 is rotatably attached to the second rotating shaft 88SB. On the other hand, in the block 85 shown in FIG. 12, the gear 88 is fixed to the second rotating shaft 88SB, and the idle gear 110 is inserted through the first rotating shaft 88SA. In the present embodiment, the first rotation shaft 88SA and the second rotation shaft 88SB rotate in reverse to each other. Therefore, in the present embodiment, the two adjacent blocks 85 rotate in the reverse direction. As shown in FIG. 14, in each block 85, the internal gear 89G of the block 85 rotates by receiving the power from the gear 88, and the idling gear 110 receives the power from the internal gear 89G. Rotate. The rotation direction of the idle gear 110 is the same as the rotation direction of the gear 88 (the rotation direction of the rotation shaft 88S to which the gear 88 is fixed), and the rotation direction of the rotation shaft 88S to which the idle gear 110 is attached. It is reversed.

  Thus, in the gaming machine 10 of the present embodiment, since there is one gear 88 that transmits power to the internal gear 89G, as in the case where there are a plurality of gears 88 that transmit power to the internal gear 89G. A variation in rotation does not occur between the plurality of gears 88, and the block 85 can be smoothly rotated. In the present embodiment, the block 85 is supported by the overhanging portion 123 that is in sliding contact with the internal gear 89G from the inside, so that the rotation of the block 85 is stabilized. In addition, since the arcuate surface 123M that is inscribed at the tips of the plurality of internal teeth in the internal gear 89G is formed in the overhanging portion 123, the overhanging portion 123 is prevented from obstructing the rotation of the block 85. .

  In this embodiment, since the support member 121 is fixed to the support shaft 120 that penetrates the inside of the block 85, the support member 121 (the overhang portion 123) can be stably supported, and the support member 121 can be supported. Interference between the support shaft 120 and the block 85 is avoided.

  In the present embodiment, the block 85 is supported by the three members of the gear 88, the support member 121, and the idling gear 110, so that the support of the block 85 can be stabilized. Further, the internal gear 89G is formed on the pair of end walls 89, 89 of the block 85, and the block 85 is driven at two locations by the pair of gears 88, 88, so that the block 85 can be stably operated. It can be rotated. In addition, since the block 85 is supported at two locations by the pair of overhang portions 123, 123, the block 85 can be supported more stably.

  Further, in the gaming machine 10 of the present embodiment, when the cap portion 102 of the intermediate sleeve 100 covers the second retaining ring 92, the opening of the second retaining ring 92 is suppressed, and the second retaining ring 92 is detached from the rotating shaft 88S. It is suppressed. Moreover, since the cap portion 102 is fixed in the axial direction of the rotary shaft 88S by the sleeve main body 101 and the first retaining ring 91, the cap portion 102 is suppressed from being detached from the second retaining ring 92, and the cap portion 102. Assembling becomes easy. Furthermore, since the sleeve body 101 is sandwiched between the first retaining ring 91 and the cap portion 102, the cap portion 102 can be positioned with a simple configuration. In the present embodiment, the second retaining ring 92 is provided with a stepped portion 93 that reduces the diameter of one side in the axial direction, and the cap portion 102 is put on the small diameter portion 95 of the second retaining ring 92. Therefore, the cap portion 102 can be easily positioned with respect to the second retaining ring 92.

  In addition, as another form of this embodiment, the structure which the two adjacent blocks 85 rotate in the same direction may be sufficient. At that time, the rotation speeds of two adjacent blocks 85 may be the same or different.

  As another form of this embodiment, the two retaining rings 90 arranged in one block 85 may both be the second retaining rings 92. In this case, the intermediate sleeve 100 may be configured to include the cap portions 102 at both ends.

  Moreover, as another form of this embodiment, it is good also as a structure which is not provided with the idle gear 110. FIG.

  As another form of the present embodiment, as shown in FIG. 15, the protruding portion 123 of the support member 121 may be circular.

  Moreover, as another form of this embodiment, the structure by which the some support member 121 is arrange | positioned in one block 85 may be sufficient.

[Other Embodiments]
The present invention is not limited to the above-described embodiment. For example, the embodiments described below are also included in the technical scope of the present invention, and various modifications are possible within the scope of the invention other than the following. It can be changed and implemented.

  (1) In the above embodiment, an example in which the present invention is applied to a pachinko gaming machine has been shown, but it may be applied to a slot machine or an arrangement ball.

  (2) In the above embodiment, the movable base 51 is configured to rotate with respect to the fixed base 41, but may be configured to move linearly with respect to the fixed base 41. In this case, the moving direction of the first movable part 61 and the second movable part 62 is preferably different from the moving direction of the movable base 51.

  (3) In the above embodiment, the first movable portion 61 and the second movable portion 62 may be directly supported by the fixed base 41 without including the movable base 51.

  (4) In the above embodiment, the movable bodies 61A, 61B, 62A, 62B of the first movable portion 61 and the second movable portion 62 are configured to move linearly along the display screen 13G, but the display screen 13G The structure which rotates along may be sufficient.

  (4) In the said embodiment, the 1st movable part 61 is good also as a structure provided with only 1 movable body, and good also as a structure provided with 3 or more. Moreover, the 2nd movable part 62 is good also as a structure provided with only one movable body, and good also as a structure provided with 3 or more.

  (5) In the above embodiment, the movable base 51 is not provided with the linear drive mechanism 70, and the movable bodies 61A, 61B, 62A, 62B of the first movable portion 61 and the second movable portion 62 are along the display screen 13G. It is good also as a structure which does not move.

  (6) In the above-described embodiment, the block 85 may include a cylindrical body having a circular cross section or a polygonal cross section instead of the rectangular cylinder 86.

[Appendix]
Hereinafter, the characteristics of the invention group extracted from each of the above-described embodiments will be described while showing effects and the like as necessary. In the following, for ease of understanding, the corresponding configuration in the above embodiment is appropriately shown in parentheses, but is not limited to the specific configuration shown in parentheses.

<Feature A group>
The following feature group A relates to a gaming machine. In the gaming machine of “Patent Document A” (Japanese Patent Laid-Open No. 2015-204920), a rotational force is applied to a rotating body including the internal gear from a plurality of gears that mesh with the internal gear. As for the background art “Transmitted (paragraphs [0602] to [0604] of FIG. 89, 90)”, in the gaming machine of Patent Document A, unevenness occurs in the rotation of a plurality of gears, and the rotating body is It was difficult to rotate smoothly. ”

(Feature A1)
A drive gear (gear 88) that is rotationally driven;
A gaming machine (game machine 10) having a rotating body (block 85) provided with an internal gear (internal gear 89G) meshing with the drive gear,
A gaming machine having a support member (support member 121) for supporting the rotating body.

  According to the configuration shown in this feature, since the rotating body is supported by the support member, the rotation of the rotating body can be stabilized. As a result, it is possible to reduce the number of drive gears that transmit power to the internal gear and to rotate the rotating body smoothly.

(Feature A2)
In the gaming machine according to feature A1,
The said support member is a gaming machine which has a sliding contact part (overhang | projection part 123) which slidably contacts the said internal gear from the inner side and supports the said rotary body.

  In the configuration shown in this feature, the rotating body can be supported from the inside by the support member, and thus the rotating body can be smoothly rotated.

(Feature A3)
In the gaming machine described in feature A2,
The said sliding contact part is a game machine which has the circular arc surface (circular arc surface 123M) inscribed in the front-end | tip of several internal teeth in the said internal gear.

  According to the configuration shown in this feature, the rotating body can be rotated more smoothly.

(Feature A4)
In the gaming machine according to feature A2 or A3,
A support shaft penetrating the inside of the internal gear (support shaft 120);
The game machine in which the support member is fixed to the support shaft.

  According to the configuration shown in this feature, stable support of the support member (sliding contact portion) is achieved, and interference between the member that supports the support member (support shaft) and the rotating body is avoided.

(Feature A5)
In the gaming machine according to any one of features A2 to A4,
A pair of rotating shafts (first rotating shaft 88SA and second rotating shaft 88SB) that are driven to rotate through the inside of the internal gear;
The drive gear is attached to one of the pair of rotating shafts (in the example of FIG. 11, the first rotating shaft 88SA) so as to be integrally rotatable with the one rotating shaft,
The other rotating shaft (second rotating shaft 88SB in the example of FIG. 11) of the pair of rotating shafts has an idling gear (idling gear 110) that meshes with the internal gear with respect to the other rotating shaft. A game machine that can be freely rotated.

  According to the configuration shown in this feature, the rotating body can be supported by the three members of the drive gear, the support member, and the idling gear, so that the support of the rotating body can be stabilized.

(Feature A6)
In the gaming machine according to Feature A5,
A plurality of the rotating bodies are arranged in the axial direction of the rotating shaft;
One rotating shaft (first rotating shaft 88SA in FIGS. 11 and 12) of the pair of rotating shafts has one rotating body (block 85 shown in FIG. 11) of two adjacent rotating bodies. The drive gear that meshes with the internal gear is attached, and the idle gear that meshes with the internal gear of the other rotating body (block 85 shown in FIG. 12) is attached,
The other rotating shaft (second rotating shaft 88SB in FIGS. 11 and 12) of the pair of rotating shafts is attached with the idling gear that meshes with the internal gear of the one rotating body and the other rotating shaft. The drive gear meshing with the internal gear of the rotating body is attached,
A gaming machine in which the one rotary shaft and the other rotary shaft rotate in reverse.

  According to the configuration shown in this feature, two rotating bodies adjacent in the axial direction of the rotating shaft can be rotated in directions opposite to each other.

(Feature A7)
In the gaming machine according to any one of features A2 to A6,
The rotating body has a cylindrical wall (square cylindrical body 86) and a pair of annular end walls (end wall 89) projecting inward from both ends of the cylindrical wall,
The internal gear is formed on each of the pair of annular end walls,
A gaming machine in which the drive gear and the sliding contact portion are provided in pairs corresponding to the pair of annular end walls.

  According to the configuration shown in this feature, the rotating body can be driven at two locations by a pair of driving gears, and thus the rotating body can be stably rotated. Moreover, since the rotating body can be supported at two locations by the pair of sliding contact portions, the rotating body can be stably supported.

(Feature A8)
A rotating shaft (rotating shaft 88S) that is driven to rotate;
A drive gear (gear 88) that rotates integrally with the rotary shaft;
A gaming machine (game machine 10) having a rotating body (block 85) provided with an internal gear (internal gear 89G) meshing with the drive gear,
A gaming machine having a support member (support member 121) for supporting the rotating body.

  According to the configuration shown in this feature, since the rotating body is supported by the support member, the rotation of the rotating body can be stabilized. As a result, it is possible to reduce the number of drive gears that transmit power to the internal gear and to rotate the rotating body smoothly.

  Note that the configuration shown in the feature A8 may be combined with the configuration shown in the feature A2 to A7.

DESCRIPTION OF SYMBOLS 10 Game machine 81 Rotating body 85 Block 86 Rectangular cylinder 88 Gear 88S Rotating shaft 89 End wall 89G Internal gear 110 Idling gear 120 Support shaft 121 Support member 123 Overhang part

Claims (7)

A drive gear driven to rotate;
A gaming machine having a rotating body with an internal gear meshing with the drive gear,
A gaming machine having a support member for supporting the rotating body. In the gaming machine according to claim 1,
The gaming machine according to claim 1, wherein the support member has a sliding contact portion that is in sliding contact with the internal gear from the inside and supports the rotating body. The gaming machine according to claim 2,
The said sliding contact part is a game machine which has the circular arc surface inscribed in the front-end | tip of several internal teeth in the said internal gear. In the gaming machine according to claim 2 or 3,
A support shaft penetrating the inside of the internal gear,
The game machine in which the support member is fixed to the support shaft. In the gaming machine according to any one of claims 2 to 4,
Having a pair of rotating shafts that are driven to rotate through the inside of the internal gear;
The drive gear is attached to one of the pair of rotating shafts so as to be integrally rotatable with the one rotating shaft,
A gaming machine in which an idling gear meshing with the internal gear is attached to the other rotating shaft of the pair of rotating shafts so as to be freely rotatable with respect to the other rotating shaft. The gaming machine according to claim 5,
A plurality of the rotating bodies are arranged in the axial direction of the rotating shaft;
The drive gear that meshes with the internal gear of one of the two adjacent rotating bodies is attached to one rotating shaft of the pair of rotating shafts, and the other rotating body The idling gear meshing with the internal gear is attached,
The idling gear meshing with the internal gear of the one rotating body is attached to the other rotating shaft of the pair of rotating shafts, and meshing with the internal gear of the other rotating body A drive gear is installed,
A gaming machine in which the one rotary shaft and the other rotary shaft rotate in reverse. In the gaming machine according to any one of claims 2 to 6,
The rotating body includes a cylindrical wall and a pair of annular end walls projecting inward from both ends of the cylindrical wall;
The internal gear is formed on each of the pair of annular end walls,
A gaming machine in which the drive gear and the sliding contact portion are provided in pairs corresponding to the pair of annular end walls.

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