JP2017023502A - Performance device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a performance device which achieves diversification of movement of an operation member.SOLUTION: A performance device comprises: a gear member 275; and a small gear 277. The gear member 275 can rotate around an axial line C. The gear member 275 comprises a first extension part 275D, a second extension part 275E, and a protrusion part 275F. The first extension part 275D and the second extension part 275E face each other with a gap 276 along the rotation direction of the gear member 275. The protrusion part 275F protrudes from the second extension part 275E to the first extension part 275D. The small gear 277 is disposed in the gap 276 and can rotate around an axial line D. When the gear member 275 rotates in a first direction (arrow A1 direction), the protrusion part 275F is engaged to a tooth part 277A of the small gear 277, and the small gear 277 becomes unrotatable around the axial line D. When the gear member 275 rotates in a second direction (arrow A2 direction), the protrusion part 275F is separated from the small gear 277, and the small gear 277 becomes rotatable around the axial line D.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a rendering device.

  Conventionally, an effect device provided in a gaming machine is known. The rendering device includes a power transmission mechanism. For example, the power transmission mechanism of the rendering device disclosed in Patent Document 1 includes an electric motor, a gear train, a rack mechanism, and a start door. The gear train includes a plurality of gears that are examples of the rotating member. The power of the electric motor is transmitted to a starting door which is an example of an operation member via a gear train and a rack mechanism. When the electric motor rotates in one direction, the starting door moves linearly in a predetermined direction, while when the electric motor rotates in another direction opposite to one direction, the starting door moves linearly in a direction opposite to the predetermined direction.

JP 2008-220694 A

  However, in the effect device, the start door moves linearly even when the electric motor rotates in one direction or the other direction, so that the start door moves monotonously.

  An object of the present invention is to provide an effect device that diversifies the movement of an operation member.

  An effect device according to a first aspect of the present invention is an effect device provided in a gaming machine, wherein a first direction centered on a first axis extending in a predetermined direction, and a second direction opposite to the first direction, A first extending portion that extends in a direction intersecting with the first direction, and is spaced from the first extending portion on the second direction side. And a first rotating member having a second extending portion extending across the second direction, and being biased by the first extending portion or the second extending portion, the first rotating member is A member that moves in a rotating direction, and an operation member that can rotate around a second axis parallel to the first axis along with the movement, and the first rotating member rotates in the first direction, While the operation member is in a state in which rotation about the second axis is restricted, the first rotation member is When rotating in the serial second direction, said operation member, characterized by comprising a switching means for rotatable state about the second axis.

  According to the above configuration, when the first rotating member rotates in the first direction, the operating member moves in the first direction without rotating around the second axis. On the other hand, when the first rotating member rotates in the second direction, the operating member moves in the second direction while rotating around the second axis. Therefore, the operation member moves differently depending on the direction in which the first rotation member rotates. Therefore, a rendering device that diversifies the movement of the operating member is realized.

  In the rendering device, the switching means is provided in a first engagement portion provided in the operation member and in the second extension portion, and when the first rotation member rotates in the first direction, You may provide the 2nd engaging part engaged with a 1st engaging part. In this case, when the second engaging portion is engaged with the first engaging portion, the switching unit can bring the operating member into a state in which the rotation is restricted. Therefore, the rendering device can simplify the mechanism that restricts the rotation of the operating member.

  In the production device, the switching unit has an uneven portion that is in contact with the operation member from one side in a direction orthogonal to the first axis and is formed in an uneven shape along the first direction. You may provide the 2nd rotation member which can be rotated centering on one axis, and the provision means to provide the force which faces the said 2nd direction side with respect to a said 2nd rotation member. In this case, when the first rotating member rotates in the first direction, the operating member moves in the first direction in a state in which the rotation is restricted and is in contact with the uneven portion. As a result, the second rotating member rotates in the first direction. On the other hand, when the first rotating member rotates in the second direction, the operating member moves in the second direction while contacting the concavo-convex portion. In this case, the rotation of the second rotating member in the second direction is restricted by the force applied from the applying unit. Thereby, the operating member moves in the second direction while rotating around the second axis, and the second rotating member does not rotate. Therefore, the rendering device can switch between a state in which the rotation of the second rotation member is allowed and a state in which the rotation of the second rotation member is restricted according to the rotation direction of the first rotation member.

  In the rendering device, the switching means is provided in a first engagement portion provided in the operation member and in the second extension portion, and when the first rotation member rotates in the first direction, A second engagement portion that engages with the first engagement portion, and a concavo-convex portion that contacts the operation member from one side in a direction orthogonal to the first axis and is formed in a concavo-convex shape along the first direction And a second rotating member rotatable about the first axis, and an applying means for applying a force directed to the second direction side to the second rotating member. Is a first gear member, the first engagement portion is a first tooth portion extending in a rotation direction around the second axis, and the second rotation member is a second gear member, The uneven portion may be a second tooth portion that extends parallel to the first direction and meshes with the first tooth portion. In this case, when the first rotating member rotates in the second direction, the operating member can reduce a load applied to the second rotating member. Therefore, the rendering device can stably rotate the first rotating member in the second direction.

  In the effect device, the second engaging portion protrudes from the second extending portion toward the operating member, and when the first rotating member rotates in the first direction, the second engaging portion bites into the first tooth portion. It may be a protrusion that can be inserted. In this case, the operation member is in a state in which the rotation is restricted only by the protrusion portion biting into the first tooth portion. Therefore, the rendering device can simplify the mechanism that restricts the rotation of the operating member.

  In the effect device, the first extending portion and the second extending portion may be opposed to each other with the operation member interposed therebetween. In this case, since the operating member is disposed between the first extending portion and the second extending portion, the rendering device can improve assemblability.

1 is a front view of a pachinko machine 1. FIG. 2 is a front view of the game board 2. FIG. It is a perspective view of the rendering device 30 with the decorative body 55 in the lower end position. FIG. 6 is a perspective view from the rear side of a decorative body 55. 4 is an enlarged perspective view from the rear side of the decorative body 55. FIG. It is a rear view of the gear member 275 and the two small gears 277. 5 is a perspective view of a cam gear 280. FIG. 3 is a perspective view of a swing support mechanism 200 and a rotation support mechanism 300. FIG. FIG. 11 is a rear view of the gear member 275 that urges the small gear 277 by the first extending portion 275D. It is a perspective view of the rendering device 30 with the decorative body 55 in the upper end position. FIG. 20 is another perspective view of the effect device 30 with the decorative body 55 in the upper end position. It is a rear view of the gear member 275 in which the second extending portion 275E biases the small gear 277. FIG. 10 is an explanatory diagram showing a flow in which a sliding portion 250 slides with respect to a cam surface 285. It is explanatory drawing which shows the flow which the rotation member 51 rotates and the rocking | fluctuation member 52 rocks | fluctuates. It is a rear view of gear member 375 etc. which are the 1st modification. It is a rear view of gear member 475 etc. which are the 2nd modification.

<1. Configuration of pachinko machine 1>
A pachinko machine 1 according to an embodiment of the present invention will be described with reference to the drawings. In the following description, the front side, back side, upper side, lower side, left side, and right side of FIG. 1 are respectively the front side (front side), rear side (rear side), upper side, lower side, and left side of the pachinko machine 1. And on the right.

  A schematic configuration of the pachinko machine 1 will be described with reference to FIGS. 1 and 2. The pachinko machine 1 is provided with a game board 2. The game board 2 has a substantially square plate shape when viewed from the front, and the front surface is protected by a front frame 13 holding a transparent glass plate. An upper plate 5 is provided at the lower part of the game board 2. The upper plate 5 supplies a game ball (not shown) to a launcher (not shown) and receives a prize ball. An operation button 9 that is operated by a player is provided at the upper center of the upper plate 5. A lower plate 6 for receiving a prize ball is provided immediately below the upper plate 5. On the right side of the lower plate 6, a launch handle 7 for adjusting the launch of the game ball is provided. Speakers 48 are respectively provided on the left and right corners of the upper portion of the front frame 13.

  A substantially circular game area 4 surrounded by guide rails 3 is formed on the front surface of the game board 2. The game ball launched by the launcher flows down in the game area 4. A frame-shaped decorative frame 14 is disposed substantially at the center of the game area 4. A first start port 15 is provided at the center lower side of the decorative frame 14. A second start port 16 having an opening / closing member is provided immediately below the first start port 15. The second starting port 16 can win a game ball only when the opening and closing member is opened. Below the second start port 16, an out port 17 is provided for collecting game balls that have flowed down to the central lower end of the game area 4.

  On the rear side of the game board 2, an image display device 28 having a display surface 27 constituted by an LCD (Liquid Crystal Display) or the like is provided. The display surface 27 is provided inside the decorative frame 14 in a front view and can display an image forward. On the display surface 27, a plurality of demonstration symbols for informing the player of the result of the hit determination based on the special symbol (big hit determination) is displayed. The plurality of demo symbols start to change when the game ball wins one of the first start port 15 and the second start port 16, and after the change, are determined and displayed in combination according to the result of the jackpot determination.

  A decorative body 55 is provided behind the decorative frame 14. The decoration body 55 is supported by the effect device 30 (see FIG. 3) attached to the rear side of the game board 2 so as to be movable up and down. The effect device 30 moves the decorative body 55 up and down in conjunction with the image display device 28, the speaker 48, and the like. Thereby, the production | presentation apparatus 30 performs various productions, such as a notification production. In FIG. 2, the decorative body 55 at the lower end position of the movable range is illustrated by a solid line, and the decorative body 55 at the upper end position of the movable range is illustrated by a virtual line.

  On the rear side of the game board 2, a main board (not shown), a sub board (not shown), and the like are provided. The main board controls the main control of the pachinko machine 1. The main board is provided with a CPU that executes various arithmetic processes, a RAM that temporarily stores data, and a ROM that stores a control program and the like. The sub board is electrically connected to the main board. As with the main board, the sub board is provided with a CPU, a RAM, and a ROM. The sub board operates the effect device 30 and the like according to a command transmitted from the main board, and executes comprehensive control related to the effect.

<2. Configuration of rendering device 30>
The outline of the configuration of the rendering device 30 will be described with reference to FIGS. As shown in FIG. 3, the rendering device 30 of this example is a device that operates a decorative body 55 shaped like so-called “18 prohibited”. The decorative body 55 includes a support body 59 that is a substantially circular plate-like member in a rear view, a rotating member 51 provided so as to cover the support body 59 from the front side, and a rocking member disposed substantially in front of the rotating member 51. A moving member 52. Although detailed description will be given later, the support body 59 supports the rotating member 51 and the swinging member 52. A central hole (not shown) that is formed in a circular shape and faces substantially in the front-rear direction is provided at the center of the support body 59. Hereinafter, the axis of the central hole of the support 59 is referred to as “axis A”.

  The rotating member 51 is a substantially circular plate-like member when viewed from the front. A central hole (not shown) formed in a circular shape around the axis A is formed in the central portion of the rotating member 51. The central hole of the rotating member 51 faces the central hole of the decorative body 55 from the front. A rectangular recess 51 </ b> B that extends linearly across the central hole is formed on the front surface 51 </ b> A of the rotating member 51. Although detailed description will be given later, the rotating member 51 is rotatable about the axis A. The swing member 52 is a flat plate-like member, and is a member that is aligned with the rotating member 51 in the substantially front-rear direction. The front surface 52A of the swing member 52 is formed in a substantially flat shape.

  The effect device 30 of the present example causes the swing member 52 to swing around an axis E (described later) extending in the left-right direction while moving the decorative body 55 up and down, and further causes the rotation member 51 to move along the axis. Rotate around A. Further, when the rotation device 51 rotates the rotation member 51 clockwise in front view, the effect device 30 regulates the swing of the swing member 52 while rotating the rotation member 51 counterclockwise in front view. Rotates the rotating member 51 counterclockwise in front view. The axis A is displaced as the decorative body 55 moves up and down.

  The rendering device 30 of this example includes a vertical drive mechanism 40 (see FIG. 3), a swing support mechanism 200 (see FIG. 5), and a rotation support mechanism 300 (see FIG. 8). The vertical drive mechanism 40 is a mechanism that moves the decorative body 55 up and down. The swing support mechanism 200 is a mechanism that supports the swing member 52 of the decorative body 55 so as to be swingable around an axis E (described later) extending in the left-right direction. The rotation support mechanism 300 is a mechanism that supports the rotation member 51 of the decorative body 55 so as to be rotatable about the axis A. Hereinafter, the configurations of the three mechanisms included in the rendering device 30 will be described in detail.

<2-1. Vertical drive mechanism 40>
As shown in FIG. 3, the vertical drive mechanism 40 includes a support member 60, a support shaft 72, an arm member 70, a motor 62, a rotation member 81, a fixed member 90, a moving member 110, and a fastening portion 150.

  The support member 60 is a substantially rectangular plate-like member in front view that is long in the left-right direction, and is fixed on the rear side of the lower portion of the decorative frame 14 (see FIG. 2). The support shaft 72 extends forward from the left end portion of the support member 60. The support shaft 72 rotatably supports the arm member 70. The arm member 70 extends rightward from the support shaft 72 along a direction orthogonal to the front-rear direction. The motor 62 is provided in the lower left part of the support member 60. The motor 62 rotates the arm member 70 around the support shaft 72 by being driven to rotate.

  An opening 76 is provided at the right end 75 of the arm member 70 that is the end in the direction away from the support shaft 72. The opening 76 is a long hole that is long in the longitudinal direction of the arm member 70, and penetrates the right end portion 75 in the front-rear direction.

  The rotating member 81 is attached to the opening 76. The rotating member 81 is a substantially circular member when viewed from the front. The rotating member 81 can move relative to the right end 75 in the longitudinal direction of the opening 76 and can rotate around an axis (not shown) extending in the front-rear direction. A meshing portion 81 </ b> A that is a tooth portion extending in the circumferential direction is formed on the outer peripheral surface of the rotating member 81.

  The fixing member 90 is fixed to a portion of the front surface of the support member 60 that is behind the right end portion 75 of the arm member 70. The fixing member 90 includes a tooth portion 92. The tooth portion 92 is erected forward from the support member 60 and extends linearly in the vertical direction. The tooth portion 92 meshes with the meshing portion 81A of the rotating member 81 from the left side. Therefore, when the arm member 70 rotates about the support shaft 72, the rotating member 81 can rotate while moving upward along the tooth portion 92. When the arm member 70 is in a first rotation position that is a rotation position extending downward and right from the support shaft 72 (see FIG. 3), the rotation member 81 is at the lower end position of the movable range.

  The moving member 110 is a plate-like body that is provided on the right side of the rotating member 81 and has a substantially rectangular shape when viewed from the front. The moving member 110 is attached to the right part of the front surface of the support member 60 via the slide rail 105. Thus, the moving member 110 is supported by the support member 60 so as to be movable up and down.

  A tooth portion 112 is formed at the left end portion of the moving member 110. The tooth portion 112 extends linearly in the vertical direction and meshes with the meshing portion 81A of the rotating member 81 from the right side. Since the tooth portion 112 meshes with the meshing portion 81 </ b> A, the moving member 110 can move up and down as the rotating member 81 rotates and moves up and down. When the rotating member 81 is at the lower end position, the moving member 110 is at the lower end position.

  The fastening portion 150 is provided at the upper end portion of the moving member 110. As shown in FIG. 4, the fastening portion 150 includes a first plate member 122, a shaft member 128, and a second plate member 134. The first plate-like member 122 is fastened to the upper end portion of the moving member 110 via a screw member (not shown). The shaft member 128 extends in the left-right direction and is fixed to the first plate-like member 122. The second plate member 134 is provided in front of the first plate member 122 and is supported by the shaft member 128. The second plate member 134 is fastened to the lower portion of the support body 59 via a screw member (not shown). Therefore, the fastening portion 150 fixes the decorative body 55 to the moving member 110, and the decorative body 55 can move up and down integrally with the moving member 110. Hereinafter, the lower end positions of the movable ranges of the moving member 110 and the decorative body 55 are simply referred to as “lower end positions” (see FIG. 3), and the upper end positions of the movable ranges of the moving member 110 and the decorative body 55 are simply referred to as “upper end positions”. This is referred to as “position” (see FIGS. 10 and 11). When the decorative body 55 is in the lower end position, the upper end portion of the decorative body 55 overlaps the lower end portion of the display surface 27 in front view (see FIG. 2). When the decorative body 55 is in the upper end position, substantially the entire decorative body 55 overlaps the lower portion of the display surface 27 in front view (see FIG. 2).

  The outline of the operation in which the vertical drive mechanism 40 having the above configuration moves the decorative body 55 up and down is as follows. When the motor 62 is driven to rotate, the arm member 70 located at the first rotation position rotates counterclockwise (in the direction of arrow P in FIG. 3) around the support shaft 72 in a front view. As the arm member 70 rotates, the inner wall surface of the opening 76 urges the rotating member 81 upward and moves relative to the rotating member 81 in the longitudinal direction of the arm member 70. Thereby, the rotating member 81 linearly moves upward while rotating counterclockwise (in the direction of arrow Q in FIG. 3) in a front view around an axis (not shown) extending in the front-rear direction.

  When the rotating member 81 rotates and moves linearly, the moving member 110 and the decorative body 55 linearly move upward from the lower end position. The linear movement amount of each of the moving member 110 and the decorative body 55 is a total value of the linear movement amount of the rotating member 81 and the rotational movement amount of the rotating member 81. Accordingly, the amount of linear movement of each of the moving member 110 and the decorative body 55 increases.

<2-2. Swing Support Mechanism 200>
As shown in FIG. 4, the swing support mechanism 200 is provided on the upper portion of the rear surface of the support body 59. The swing support mechanism 200 includes a power transmission unit 270 and a support unit 240. The power transmission unit 270 transmits the driving force of the decorative body motor 202 provided at the upper left part of the rear surface of the support body 59 to the swing member 52 (see FIG. 3). A motor gear 202A is fixed to a drive shaft (not shown) of the decorative body motor 202. The support portion 240 supports the swing member 52 so as to be swingable about an axis E (described later) extending in the left-right direction.

<2-2-1. Power Transmission Unit 270>
The configuration of the power transmission unit 270 will be described with reference to FIGS. 5 shows a perspective view of the power transmission unit 270 in which a cam gear 280 described later is removed from the support shaft 59A. As shown in FIG. 5, the power transmission unit 270 includes a connection gear 271, an intermediate gear 273, a gear member 275, two small gears 277, and a cam gear 280.

  The connection gear 271 is a gear that is connected to the motor gear 202 </ b> A of the decorative body motor 202. The intermediate gear 273 is a gear connected to the connection gear 271 and is rotatable about the axis A. A tooth portion 273A extending in the rotation direction is formed on the outer peripheral surface of the intermediate gear 273. The tooth portion 273A meshes with the connecting gear 271. A circular hole 273B (see FIG. 8) is formed in the center of the intermediate gear 273. The circular hole 273B has a circular shape centered on the axis A and faces substantially in the front-rear direction. The circular hole 273B faces the above-described central hole (not shown) of the support body 59 from behind. Hereinafter, the clockwise direction in the rear view around the axis A is referred to as a first rotation direction, and the opposite direction to the first rotation direction is referred to as a second rotation direction. The first rotation direction is the direction in which the arrow M1 in FIG. 7 faces. The second rotation direction is a direction in which an arrow M2 in FIG. 7 faces.

  The gear member 275 is rotatably supported by a support shaft 59A that protrudes rearward from a portion of the support body 59 that is obliquely above and to the left of the intermediate gear 273. The gear member 275 is rotatable about an axis C that is the axis of the support shaft 59A. The axis C extends substantially in the front-rear direction. Hereinafter, the counterclockwise direction in the rear view around the axis C is referred to as “first direction”, the opposite direction to the first direction is referred to as “second direction”, and the first direction and the second direction are collectively referred to. In this case, it is called “drive gear rotation direction”. The first direction is the direction in which the arrow A1 shown in FIGS. The second direction is the direction in which the arrow A2 shown in FIGS.

  As shown in FIG. 6, the gear member 275 includes a front wall portion 275A, a tooth portion 275B, two inner wall portions 275C, two first extending portions 275D, two second extending portions 275E, and two protrusions. Part 275F. The front wall portion 275A forms a front end portion of the gear member 275. An insertion hole 275G through which the support shaft 59A is inserted is formed at the center of the front wall portion 275A. The tooth portion 275B stands rearward from the peripheral end portion of the front wall portion 275A and extends in the driving gear rotation direction. The tooth portion 275B meshes with the tooth portion 273A (see FIG. 5) of the intermediate gear 273. Therefore, the gear member 275 receives the rotational driving force of the decorative body motor 202 from the intermediate gear 273. In this example, the tooth part 275B and the tooth part 273A have the same number of teeth. That is, the outer diameter of the gear member 275 is the same as the outer diameter of the intermediate gear 273. The two inner wall portions 275C are wall portions erected rearward from a portion between the tooth portion 275B and the insertion hole 275G in the front wall portion 275A. The two inner wall portions 275C extend along the drive gear rotation direction. The two inner wall portions 275C are opposed to each other with the insertion hole 275G interposed therebetween.

  The two first extending portions 275D are wall portions that extend substantially linearly from the end portions of the two inner wall portions 275C in the second direction to the tooth portion 275B. On the other hand, the two second extending portions 275E are wall portions that extend substantially linearly from the end portions of the two inner wall portions 275C in the first direction to the tooth portion 275B. The extending direction of the first extending portion 275D and the extending direction of the second extending portion 275E both intersect the drive gear rotation direction. In this example, the two first extending portions 275D and the two second extending portions 275E are both connected to the front wall portion 275A. The two protruding portions 275F protrude in the first direction from the end portions of the second extending portions 275E on the side approaching the axis C.

  The first extending portion 275D provided on one of the two inner wall portions 275C has a second extending portion 275E provided on the other of the two inner wall portions 275C, along the drive gear rotation direction. Opposite the gap 276. That is, two gaps 276 are formed inside the gear member 275. The gap 276 is provided at a position that is symmetric with respect to the axis C.

  The two small gears 277 are disposed in the two gaps 276, respectively. That is, the two small gears 277 are arranged at equal intervals along the drive gear rotation direction. The two small gears 277 are rotatable about an axis D that extends substantially in the front-rear direction, and are rotatable about the axis C. The axis D is displaced as the small gear 277 rotates around the axis C. The outer diameter of the small gear 277 is shorter than the shortest distance from the tip of the protruding portion 275F to the first extending portion 275D along the first direction. On the outer peripheral surface of the small gear 277, a tooth portion 277A is formed in the circumferential direction. That is, the tooth portion 277A extends along the rotation direction around the axis D. Of each tooth forming the tooth portion 277A, the protruding portion 275F can enter between two teeth adjacent to each other along the circumferential direction. As a result, the protrusion 275F can be engaged with the tooth portion 277A, and the rotation about the axis D of the small gear 277 can be restricted. “Bite” is an example of “engagement”.

  A housing portion 299 is formed inside the gear member 275. The accommodating portion 299 is a space surrounded by the front wall portion 275A and the two inner wall portions 275C.

  As shown in FIG. 7, the cam gear 280 has a substantially cylindrical shape extending along the axis C, and is rotatably supported by the support shaft 59A (see FIG. 5). The axis that becomes the rotation center of the cam gear 280 coincides with the axis that becomes the rotation center of the gear member 275. A tooth portion 281 is formed on the outer peripheral surface of the front portion of the cam gear 280. The tooth portion 281 is a concavo-convex portion extending over the drive gear rotation direction. The tooth portion 281 is housed in the housing portion 299 and meshes with the tooth portions 277A of the two small gears 277 from the axis C side (see FIG. 6). In other words, the tooth portion 281 is in contact with the tooth portion 277A from one side in the direction orthogonal to the axis C.

  At the center of the outer peripheral surface of the cam gear 280 in the substantially front-rear direction, a flange 282 is formed in the circumferential direction. The flange portion 282 faces the two small gears 277 from the rear (see FIG. 5). That is, the flange portion 282 restricts the backward displacement of the two small gears 277.

  Two cam surfaces 285 are formed on the rear end surface of the cam gear 280. The two cam surfaces 285 are arranged along the drive gear rotation direction and form an annular shape in rear view. That is, of the two cam surfaces 285, the end portion in the second direction of one cam surface 285 is connected to the end portion in the first direction of the other cam surface 285.

  Each cam surface 285 includes a first cam surface 285A, a second cam surface 285B, a third cam surface 285C, a fourth cam surface 285D, and a fifth cam surface 285E. The first cam surface 285A extends parallel to the drive gear rotation direction. The second cam surface 285B extends rearward along the second direction from the end of the first cam surface 285A in the second direction. An end portion of the second cam surface 285B in the second direction is disposed on the rear side of the first cam surface 285A. The third cam surface 285C extends forward from the second direction end of the second cam surface 285B along the second direction. The fourth cam surface 285D extends along the second direction from the end of the third cam surface 285C in the second direction. The fourth cam surface 285D is disposed in front of the first cam surface 285A. The fifth cam surface 285E extends rearward along the second direction from the second direction end of the fourth cam surface 285D. The end portion in the second direction of the fifth cam surface 285E is connected to the end portion in the first direction of the first cam surface 285A included in the other cam surface 285.

<2-2-2. Supporting part 240>
As shown in FIG. 8, the support part 240 includes support wall parts 242 and 244, a decorative body support part 246, a connection part 248, and a sensor 253 (see FIG. 4). The support wall portions 242 and 244 are wall portions erected rearward from the support body 59 (see FIG. 5) at positions facing each other with the intermediate gear 273 interposed therebetween. The support wall portions 242 and 244 are substantially rectangular in a side view, and are arranged in order from the left side along the left-right direction. Circular support holes 243 are respectively formed in the center portions of the support wall portions 242 and 244 in the front-rear direction. In FIG. 8, the support hole 243 of the support wall portion 244 out of the two support holes 243 is illustrated. Hereinafter, an axis that passes through the centers of the two support holes 243 and extends in the left-right direction is referred to as an axis E.

  The decorative body support portion 246 includes an erection portion 247, an extension portion 249, and a sliding portion 250. The erection part 247 is a substantially rectangular wall part as viewed from the back, and spans the support wall parts 242 and 244 on the rear side of the intermediate gear 273. Shaft portions 247A are formed at both ends in the left-right direction of the erection portion 247, respectively. The shaft portion 247A extends in the left-right direction. By inserting each shaft portion 247A into each support hole 243, the decorative body support portion 246 can swing around the axis E. An insertion hole (not shown) formed in a circular shape with the axis A as the center is formed in the central portion in the left-right direction of the installation portion 247. The extending portion 249 extends upward from the central portion in the left-right direction among the upper end portions of the erection portion 247. The sliding portion 250 is a cylindrical body that extends leftward from the upper end portion of the extending portion 249. In this example, the sliding portion 250 can swing toward the front side or the rear side about the axis E. The sliding portion 250 is in contact with the cam surface 285 (see FIG. 7) of the cam gear 280 from the rear (see FIG. 4).

  The connecting portion 248 passes through the above-described center hole (not shown) of the support body 59 and the above-described center hole (not shown) of the rotating member 51, and substantially between the swing member 52 and the installation portion 247. A cylinder extending in the direction. The connecting portion 248 of this example is formed integrally with the rear surface of the swing member 52. A fastening hole (not shown) facing backward is formed at the rear end portion of the connecting portion 248. The screw 241 is inserted into the above-described insertion hole of the installation part 247 and fastened to the fastening hole of the connection part 248. That is, the connecting portion 248 connects the swing member 52 and the installation portion 247, and the swing member 52 is supported by the decorative body support portion 246 so as to be swingable about the axis E.

  The swing member 52 is located in front of the installation part 247. Accordingly, the installation portion 247 is biased counterclockwise (in the direction of the arrow V shown in FIG. 8) about the axis E by the weight of the swinging member 52 when viewed from the right side. The swinging portion 247 is restricted from swinging about the axis E by the sliding portion 250 coming into contact with the cam surface 285. The sliding portion 250 is pressed toward the cam surface 285 (see FIG. 7). Therefore, regardless of the direction in which the cam gear 280 is urged about the axis C, the frictional force directed in the direction opposite to the direction in which the cam gear 280 is urged is applied to the sliding portion 250 and the cam surface 285. Occurs between.

  As shown in FIG. 4, the sensor 253 is provided in a portion of the support body 59 that is to the left of the support wall portion 244 and below the installation portion 247. The sensor 253 in this example is a transmissive sensor. The sensor 253 detects a detection plate (not shown) that protrudes downward from the lower part of the right end of the erection part 247. The detected plate of this example is formed integrally with the erection part 247 and can swing integrally with the swinging member 52 around the axis E. When the sensor 253 detects the plate to be detected, the swing member 52 is in the intermediate swing position (see FIGS. 10 and 11 and the like). The intermediate rocking position is a rocking position of the rocking member 52 where the rear surface of the rocking member 52 is substantially parallel to the front surface 51 </ b> A of the rotating member 51. When the sliding portion 250 comes into contact with the first cam surface 285A, the swing member 52 is in the intermediate swing position.

<2-2-3. Overview of Oscillating Operation of Oscillating Member 52>
Since the swing support mechanism 200 connected to the decorative body motor 202 has the above-described configuration, the swing member 52 swings from the intermediate swing position as follows.

  As shown in FIG. 5, the decorative body motor 202 rotates the motor gear 202A in a first specific direction (in the direction of the arrow B1) that is clockwise when viewed from the back. The rotational driving force of the decorative body motor 202 is transmitted to the intermediate gear 273 via the connecting gear 271. Intermediate gear 273 rotates in the first rotation direction (the direction of arrow M1). As the intermediate gear 273 rotates, the gear member 275 rotates in the first direction (arrow A1 direction in FIG. 12). The two protrusions 275F are engaged with the two teeth 277A, respectively (see FIG. 12).

  As the gear member 275 further rotates in the first direction, the second extending portion 275E biases the small gear 277 in the first direction via the protruding portion 275F. The two small gears 277 rotate and move in the first direction together with the gear member 275 in a state where the rotation about the axis D is restricted. Since the tooth portion 277A meshes with the tooth portion 281 of the cam gear 280, the two small gears 277 rotate the cam gear 280 (see FIG. 5) in the first direction. The cam gear 280 rotates in the first direction against the frictional force generated between the sliding portion 250 and the cam surface 285.

  The cam surface 285 that rotates in the first direction slides relative to the sliding portion 250. More specifically, the first cam surface 285A, the second cam surface 285B, the third cam surface 285C, the fourth cam surface 285D, and the fifth cam surface 285E slide with respect to the sliding portion 250 in this order. Since the contact position between the sliding portion 250 and the cam surface 285 is displaced in the front-rear direction, the decorative body support portion 246 swings about the axis E. The swing member 52 located at the intermediate swing position swings around the axis E together with the decorative body support portion 246. As a result, the direction in which the front surface 52A (see FIG. 3) of the swing member 52 faces changes.

  On the other hand, when the decorative body motor 202 rotates the motor gear 202A in the second specific direction (the direction of arrow B2 in FIG. 5) opposite to the first specific direction, the intermediate gear 273 is rotated in the second rotation direction (FIG. 5). In the direction of arrow M2). As the intermediate gear 273 rotates, the gear member 275 rotates in the second direction (arrow A2 direction in FIG. 9). The protruding portion 275F is separated from the tooth portion 275B in the second direction (see FIG. 9), and the two small gears 277 are both rotatable about the axis D. As the gear member 275 further rotates in the second direction, the first extending portion 275D comes into contact with the small gear 277 and urges it in the second direction. The two small gears 277 each rotate and move in the second direction. That is, the gear member 275 functions as a drive gear that rotates the small gear 277.

  In this case, the tooth portion 281 of the cam gear 280 receives a force directed in the second direction by the small gear 277 that rotates and moves in the second direction. However, the cam gear 280 maintains a stationary state without rotating in the second direction due to a frictional force generated by the sliding portion 250 being pressed against the cam surface 285. In other words, when the small gear 277 rotates and moves in the second direction, the sliding portion 250 (see FIG. 5) and the cam surface 285 (see FIG. 5) depend on the force that the cam gear 280 receives from the small gear 277. A frictional force directed toward the first direction is generated between the cam gear 280 and the rotation of the cam gear 280 in the second direction. That is, when the small gear 277 rotates and moves in the second direction, the sliding portion 250 and the cam surface 285 function as an applying unit that applies a force directed to the cam gear 280 in the first direction. Since the cam gear 280 remains stationary without rotating in the second direction, the two small gears 277 rotate around the axis D and roll with respect to the tooth portion 281 when rotating in the second direction. To do.

<2-3. Rotation Support Mechanism 300>
As shown in FIG. 8, the rotation support mechanism 300 is provided on the rear surface of the support body 59 (see FIG. 5). An intermediate gear 273, two engaging portions 305, a pair of detected portions 310, and a sensor 315 are provided. In FIG. 8, only one of the two engaging portions 305 is shown. The intermediate gear 273 is a rotating body that is provided on the swing support mechanism 200 described above and that can rotate about the axis A. That is, the intermediate gear 273 is a rotating body that is shared by the swing support mechanism 200 and the rotation support mechanism 300.

  The two engaging portions 305 are a pair of claw portions provided on the intermediate gear 273 at positions facing each other across the axis A. The two engaging portions 305 extend forward from the inner peripheral surface surrounding the circular hole 273B of the intermediate gear 273. The two engaging portions 305 are inserted into the above-described central hole (not shown) of the rotating member 51 (see FIG. 3), and engage with the inner peripheral surface surrounding the central hole from the inside. Accordingly, the engaging portion 305 connects the intermediate gear 273 and the rotating member 51, and the intermediate gear 273 supports the rotating member 51. Therefore, the engaging portion 305, the intermediate gear 273, and the rotating member 51 can be rotated integrally around the axis A as the decorative body motor 202 is driven to rotate. In other words, the intermediate gear 273 can rotate the rotating member 51 around the axis A as the decorative body motor 202 is driven to rotate. Note that the connecting portion 248 described above is disposed between the two engaging portions 305.

  The pair of detected portions 310 are plate-like bodies arranged at positions facing each other across the axis A, and protrude in a direction away from the axis A from the tooth portion 273A of the intermediate gear 273. The detected part 310 of this example is formed integrally with the intermediate gear 273.

  The sensor 315 is attached to the support body 59 (see FIG. 4) at a position that is lower left with respect to the intermediate gear 273. The sensor 315 of this example is a transmissive sensor. The sensor 315 can detect any one of the detected parts 310 at a predetermined rotational position among the pair of detected parts 310. The predetermined rotation position in this example is a position displaced by approximately 45 ° in the second rotation direction (arrow M2 direction) from the position directly below the axis A (see FIG. 8).

  In this example, when the sensor 315 detects the detected part 310 in the predetermined rotation position, the rotation member 51 is in the initial rotation position (see FIGS. 3 and 10). The initial rotation position is the rotation position of the rotation member 51 in which the rectangular recess 51B extends from the upper left to the lower right in the front view. In this example, the swing member 52 (see FIG. 3) is at a predetermined swing position according to the rotational position of the intermediate gear 273. When the rotation member 51 is in the initial rotation position, the first cam surface 285A (see FIG. 7) of the cam gear 280 is in contact with the sliding portion 250, and the swing member 52 is in the intermediate swing position.

  The outline of the operation of the rotation support mechanism 300 having the above configuration is as follows. As shown in FIG. 5, when the decorative body motor 202 rotates the motor gear 202A in the first specific direction (arrow B1 direction), the intermediate gear 273 rotates in the first rotation direction (arrow M1 direction). The rotating member 51 rotates in the first rotation direction integrally with the intermediate gear 273. On the other hand, when the decorative body motor 202 rotates the motor gear 202A in the second specific direction (arrow B2 direction), the rotating member 51 rotates integrally with the intermediate gear 273 in the second rotation direction (arrow M2 direction).

<3. Operation of the rendering device 30>
With reference to FIGS. 3, 5, and 9 to 14, an operation in which the effect device 30 displaces the decorative body 55 will be described. The rendering device 30 of the present example performs a first operation, a second operation, and the like as an operation for moving the decorative body 55. The first operation is an operation of the effect device 30 that rotates the rotating member 51 in a state where the swing member 52 is positioned at the intermediate swing position when the decorative body 55 moves between the lower end position and the upper end position. It is. The second operation is an operation of the rendering device 30 that swings the swing member 52 in addition to the first operation.

<3-1. First Operation of Staging Device 30>
The first operation of the rendering device 30 will be described with reference to FIGS. 3, 5, 9, and 10. The effect device 30 before operation is in an initial state. The initial state is a state of the effect device 30 in which the decorative body 55 is positioned at the lower end position, the rotating member 51 is positioned at the initial rotating position, and the swinging member 52 is positioned at the intermediate swinging position.

  As shown in FIG. 3, as the motor 62 of the vertical drive mechanism 40 is driven to rotate, the arm member 70 that has been in the first rotational position rotates counterclockwise around the support shaft 72 (in the direction of arrow P). The moving member 110 moves upward from the lower end position.

  As shown in FIG. 5, simultaneously with the rotational drive of the motor 62 (see FIG. 3), the decorative body motor 202 rotationally drives the motor gear 202A in the second specific direction (arrow B2 direction). Along with the rotation of the motor gear 202A, the rotating member 51 rotates in the second rotation direction (arrow M2 direction) together with the intermediate gear 273.

  Intermediate gear 273 transmits the rotational driving force of motor gear 202 </ b> A in the second specific direction to gear member 275. Gear member 275 rotates in the second direction (the direction of arrow A2 shown in FIG. 9). As shown in FIG. 9, the two first extending portions 275 </ b> D are in contact with the two small gears 277 and urged in the second direction. The two small gears 277 rotate and move in the second direction around the axis C while rolling with respect to the tooth portion 281. Since the cam gear 280 does not rotate, the swing member 52 maintains a state of being positioned at the intermediate swing position. Accordingly, the decorative body 55 moves upward from the lower end position in a state where the rotating member 51 (see FIG. 3) rotates in the second direction and the swinging member 52 (see FIG. 3) is in the intermediate swinging position. .

  When the arm member 70 rotates to the second rotation position (see FIG. 11), which is a rotation position extending from the support shaft 72 to the upper right, the motor 62 stops rotating. The rotating member 81 and the moving member 110 stop moving upward at the upper end position. Even after the motor 62 stops rotating, the decorative body motor 202 continues to rotate. Therefore, even after the decorative body 55 moves to the upper end position, the rotating member 51 continues to rotate in the second direction (arrow M2 direction) (see FIGS. 10 and 11).

  After a predetermined time has elapsed since the decorative body 55 has moved to the upper end position, the motor 62 is driven to rotate in the direction opposite to that when the decorative body 55 is raised. Thereby, the arm member 70 in the second rotation position rotates clockwise (in the direction of arrow S in FIG. 10) around the support shaft 72 in a front view. The rotating member 81 moves downward from the upper end position while rotating clockwise in front view. Both the moving member 110 and the decorative body 55 move downward from the upper end position.

  Even when the decorative body 55 moves downward from the upper end position, the decorative body motor 202 is continuously driven to rotate. Thereby, even when the decorative body 55 moves downward, the rotation member 51 continues to rotate in the second rotation direction, and the swing member 52 maintains the state in the intermediate swing position.

  When the arm member 70 rotates to the first rotation position (see FIG. 3), all of the rotation member 81, the moving member 110, and the decorative body 55 move to the lower end position, and the motor 62 stops rotating. The decorative body 55 stops at the lower end position. Further, when the sensor 315 detects one of the pair of detected parts 310, the decorative body motor 202 stops rotating. Thereby, the rotating member 51 stops at the initial rotation position. The rendering device 30 returns to the initial state and ends the first operation.

<3-2. Second Operation of Staging Device 30>
The second operation of the rendering device 30 will be described with reference to FIGS. 3, 5, 8, and 12 to 14. The rendering device 30 before executing the second operation is in an initial state. In the following description, the operation of the decorative body 55 similar to the first operation will be described in a simplified manner. In FIG. 13, a diagram in which the cam surface 285 is developed along the rotation direction of the cam gear 280 is schematically shown together with the sliding portion 250. Further, the front-rear position of the sliding portion 250 shown in FIG. 13A corresponds to the swing position of the swing member 52 shown in FIG. Similarly, FIG. 13 (b) corresponds to FIG. 14 (b), FIG. 13 (c) corresponds to FIG. 14 (c), and FIG. 13 (d) corresponds to FIG.

  As shown in FIGS. 3 and 5, the motor 62 of the vertical drive mechanism 40 moves the moving member 110 upward from the lower end position, so that the decorative body 55 moves upward from the lower end position. At the same time, the decorative body motor 202 rotationally drives the motor gear 202A in the first specific direction (the direction of arrow B1 in FIG. 5). As the decorative body motor 202 is driven to rotate, the rotating member 51 rotates together with the intermediate gear 273 in the first rotation direction (the arrow M1 direction shown in FIG. 5). Intermediate gear 273 transmits the rotational driving force of motor gear 202 </ b> A in the first specific direction to gear member 275.

  As shown in FIG. 12, the gear member 275 rotates in the first direction (arrow A1 direction). In a state where the protruding portion 275F is engaged with the tooth portion 277A of the small gear 277, the second extending portion 275E biases the small gear 277 in the first direction. The two small gears 277 rotate the cam gear 280 in the first direction. As a result, the cam surface 285 (see FIG. 7) rotates in the first direction, and the swing member 52 (see FIG. 8) swings about the axis E.

  The swing operation of the swing member 52 will be described in detail with reference to FIGS. The sliding portion 250 sequentially slides with respect to the first cam surface 285A, the second cam surface 285B, the third cam surface 285C, the fourth cam surface 285D, and the fifth cam surface 285E. In this case, the sliding portion 250 is pressed against the cam surface 285 by the weight of the swinging member 52. Therefore, the sliding portion 250 can slide stably without being separated from the cam surface 285 rotating in the first direction.

  While the sliding portion 250 slides with respect to the first cam surface 285A (see FIG. 13A), the contact position between the sliding portion 250 and the cam surface 285 is not displaced in the front-rear direction. Is located at the intermediate swing position (see FIG. 14A).

  While the sliding portion 250 slides on the second cam surface 285B after the first cam surface 285A (not shown), the contact position between the sliding portion 250 and the cam surface 285 is displaced rearward. As a result, the swing member 52 (see FIG. 8) swings from the intermediate swing position in the counterclockwise direction (in the direction of arrow W in FIG. 8) in the right side view about the axis E.

  When the sliding portion 250 slides on the end in the first direction of the third cam surface 285C after the second cam surface 285B (see FIG. 13B), the swing member 52 is in the first swing position (see FIG. 14 (b)). The first swing position is the position of the clockwise end of the swing range around the axis E as viewed from the right side. When the swing member 52 is in the first swing position, the front surface 52A of the swing member 52 faces upward from the direction in which the front surface 51A of the rotating member 51 faces. When the swing member 52 is in the first swing position, the sliding portion 250 is at the rear end position of the movable range.

  While the sliding portion 250 slides with respect to the third cam surface 285C (see FIG. 13B), the contact position between the sliding portion 250 and the cam surface 285 is displaced forward. As a result, the swing member 52 swings counterclockwise (in the direction of arrow V shown in FIG. 8) about the axis E as viewed from the right side. The swing member 52 swings from the first swing position to the second swing position (see FIG. 14C) via the intermediate swing position. The second swing position is the position of the counterclockwise end in the right side view in the swing range about the axis E. When the swing member 52 is in the second swing position, the direction in which the front surface 52A of the swing member 52 faces is lower than the direction in which the front surface 51A of the rotation member 51 faces. When the swing member 52 is in the first swing position, the sliding portion 250 is at the front end position of the movable range.

  While the sliding portion 250 slides with respect to the fourth cam surface 285D after the third cam surface 285C (see FIG. 13C), the contact portion between the sliding portion 250 and the cam surface 285 is in the front-rear direction. Does not displace. As a result, the swing member 52 is maintained in the second position.

  While the sliding portion 250 slides with respect to the fifth cam surface 285E after the fourth cam surface 285D (not shown), the contact position between the sliding portion 250 and the cam surface 285 is displaced rearward. Thereby, the swing member 52 swings from the second swing position clockwise about the axis E in the right side view (in the direction of arrow W in FIG. 8). When the sliding portion 250 slides again with respect to the first cam surface 285A after the fifth cam surface 285E, the swing member 52 returns to the intermediate swing position.

  Therefore, while the sliding portion 250 slides with one of the two cam surfaces 285 formed on the cam gear 280, the swing member 52 moves from the intermediate swing position to the first swing position and the second swing position. It returns to the intermediate swing position through the positions in order. As the sliding portion 250 slides with respect to the two cam surfaces 285 of the cam gear 280, the swing member 52 repeatedly swings between the first swing position and the second swing position, Move up and down visually.

  As shown in FIG. 14, when the decorative body 55 moves from the lower end position to the upper end position, the motor 62 (see FIG. 3) stops rotating and the decorative body motor 202 (see FIG. 5) continues to rotate. . With the decorative body 55 in the upper end position, the rotation member 51 rotates in the first rotation direction (the direction of the arrow M1), and the swing member 52 reciprocates between the first swing position and the second swing position. Swing.

  After a predetermined time has elapsed since the decorative body 55 has moved to the upper end position, the motor 62 is driven to rotate, and the decorative body 55 moves downward from the upper end position. While the decorative body 55 moves downward, the rotating member 51 continues to rotate, and the swinging member 52 continues to swing back and forth. After the decorative body 55 moves to the lower end position, the motor 62 and the decorative body motor 202 stop rotating. The rendering device 30 returns to the initial state and stops the second operation.

  In the pachinko machine 1 of this example, the first action is executed when the jackpot determination is made, and the second action is executed during the jackpot game after the notification. The performance device 30 can continuously attract the player's interests even after the jackpot determination is made by sequentially executing the first action and the second action.

<4. Example of action and effect of the present disclosure>
As described above, when the decorative body motor 202 rotationally drives the motor gear 202A in the first specific direction, the gear member 275 rotates in the first direction. The two small gears 277 rotate and move in the first direction in a state where the rotation about the axis C is restricted. Accordingly, the two intermediate gears 273 rotate the cam gear 280, and the swing member 52 swings between the first swing position and the second swing position. On the other hand, when the decorative body motor 202 rotationally drives the motor gear 202A in the second specific direction, the gear member 275 rotates in the second direction. The two small gears 277 rotate and move in the second direction. In this case, since the cam gear 280 does not rotate, the small gear 277 that rotates in the second direction rolls with respect to the tooth portion 281. The two small gears 277 perform different operations depending on the direction in which the gear member 275 rotates. Therefore, the rendering device 30 in which the movement of the small gear 277 is diversified is realized.

  By diversifying the movement of the small gear 277, the power transmission unit 270 allows the rotational driving force of the decorative body motor 202 to be transmitted to the cam gear 280, and the rotational driving force of the decorative body motor 202 is the cam gear. It switches to the state where transmission to 280 is restricted. In other words, as the movement of the small gear 277 is diversified, the rendering device 30 is in a state in which the swing member 52 is allowed to swing and a state in which the swing member 52 is restricted from swinging. Switch. Thereby, the rendering device 30 can be switched between an operation in which the swing member 52 swings and an operation in which the swing member 52 does not swing. Therefore, the movement of the decorative body 55 becomes various. Therefore, the rendering device 30 can enhance the rendering effect when the decorative body 55 is displaced.

  The rotating member 51 rotates about the axis A according to the direction in which the decorative body motor 202 rotates the motor gear 202A. That is, according to the direction in which the decorative body motor 202 rotates and drives the motor gear 202A, the rendering device 30 is in a state where the rotating member 51 rotates and the swinging member 52 swings, and the rotating member 51 rotates and swings. The member 52 is switched to a state where it does not swing. Depending on the direction in which the decorative body motor 202 is rotationally driven, the manner of operation of the decorative body 55 varies greatly. Therefore, the rendering device 30 can further enhance the rendering effect when the decorative body 55 is displaced.

  The small gear 277 is in a state in which the rotation about the axis D is restricted only by the protruding portion 275F biting into the tooth portion 277A. Therefore, the rendering device 30 can simplify the mechanism that restricts the rotation of the small gear 277.

  When the gear member 275 rotates in the second direction, the small gear 277 rotates and moves in the second direction while being in contact with the tooth portion 281. In this case, since the cam gear 280 is restricted from rotating in the second direction, the small gear 277 that contacts the tooth portion 281 rotates in the second direction while rotating about the axis D. On the other hand, when the gear member 275 rotates in the first direction, the small gear 277 is rotationally moved in the first direction while being restricted from rotating about the axis D and in contact with the tooth portion 281. As a result, the cam gear 280 rotates in the first direction against the frictional force generated between the sliding portion 250 and the cam surface 285. In other words, the rendering device 30 switches between a state where the rotation of the cam gear 280 is allowed and a state where the rotation of the cam gear 280 is restricted, so that the swinging member 52 is allowed to swing, It is possible to switch to a state where the swing of 52 is restricted. Therefore, the rendering device 30 can control the rotation operation of the cam gear 280 according to the operation state of the small gear 277 and cause the swing member 52 to swing.

  Further, since the rotation of the cam gear 280 is allowed and the rotation of the cam gear 280 is restricted according to the operation state of the small gear 277, the method for transmitting the driving force of the decorative body motor 202 is diversified. To do. In this example, the swing member 52 is connected to the cam gear 280 via the decorative body support portion 246, and the swing member 52 swings as the cam gear 280 rotates in the first direction. Therefore, the rendering device 30 can convert the rotational force transmitted from the gear member 275 to the small gear 277 into the swinging motion of the swinging member 52.

  The tooth portion 277A extends in parallel with the rotation direction around the axis D, and the tooth portion 281 extends in parallel with the drive gear rotation direction. When the gear member 275 rotates in the second direction, each tooth forming the tooth portion 277A comes into contact with each tooth forming the tooth portion 281 and the small gear 277 rolls relative to the cam gear 280. . Therefore, the load applied from the small gear 277 to the tooth portion 281 is not easily increased. Therefore, the rendering device 30 can stably rotate the gear member 275 in the second direction.

  The protruding portion 275F can be engaged with the tooth portion 277A of the small gear 277 only by protruding from the second extending portion 275E. Therefore, the rendering device 30 can simplify the mechanism that restricts the rotation of the small gear 277.

  The first extending portion 275D and the second extending portion 275E face each other with the small gear 277 interposed therebetween. The assembly operator only needs to house the small gear 277 in the gap 276 formed between the first extending portion 275D and the second extending portion 275E, and the small gear 277 moves along with the rotation of the gear member 275. Thus, it can be rotated around the axis C. Therefore, the rendering device 30 can improve the assemblability of the small gear 277.

  Two small gears 277 are arranged at equal intervals along the rotation direction of the drive gear. Therefore, the rotational force transmitted from the gear member 275 to each small gear 277 is dispersed. Therefore, since the load applied to each small gear 277 is reduced, the rendering device 30 can have a long life.

  The rendering device 30 includes a decorative body motor 202 that rotates the gear member 275. Therefore, the rendering device 30 can accurately control the timing at which the gear member 275 starts to rotate and the time and direction in which the gear member 275 rotates. Therefore, the rendering device 30 can stabilize the rotation of the gear member 275. The rendering device 30 can stabilize the swing of the swing member 52 by stabilizing the rotation of the gear member 275.

  The tooth portion 281 of the cam gear 280 meshes with the tooth portion 277A of the small gear 277 from the axis C side. That is, the small gear 277 meshes with the tooth portion 281 from the side opposite to the axis C. The small gear 277 is further away from the tooth portion 281 with respect to the axis C. Therefore, the small gear 277 that rotates in the first direction easily rotates the cam gear 280 in the first direction. Therefore, the rendering device 30 can efficiently transmit the rotational force of the gear member 275 in the first direction to the cam gear 280. In this example, since the decorative body motor 202 rotates the gear member 275, the rendering device 30 can achieve power saving.

  The configuration in which the sliding portion 250 is pressed against the cam surface 285 generates a frictional force that faces the first direction when the small gear 277 rotates in the second direction. When the frictional force is generated, the rotation of the cam gear 280 in the first direction is restricted. Therefore, the rendering device 30 can simplify the configuration of the applying unit that is a unit that applies a force toward the first direction to the cam gear 280.

  As the sliding portion 250 slides with respect to the cam surface 285 rotating in the first rotation direction, the decorative body support portion 246 swings about the axis E. Therefore, the rendering device 30 can convert the rotational force of the gear member 275 into the swinging force of the decorative body support 246.

  The sliding portion 250 is pressed against the cam surface 285 by the weight of the swing member 52. Therefore, the sliding part 250 can slide stably with respect to the rotating cam surface 285. Therefore, the rendering device 30 can stably swing the swing member 52.

  An intermediate gear 273 shared by the rotation support mechanism 300 and the swing support mechanism 200 is connected to the decorative body motor 202. That is, the rotation support mechanism 300 and the swing support mechanism 200 also serve as the decorative body motor 202 that is a drive source. The rendering device 30 can reduce the number of drive sources of the rotation support mechanism 300 and the swing support mechanism 200. Therefore, the rendering device 30 can simplify the mechanism for displacing the decorative body 55.

  The cam gear 280 includes two cam surfaces 285, and the second cam surface 285B and the third cam surface 285C are alternately arranged along the second direction. As a result, the swinging member 52 swings back and forth twice while the cam gear 280 rotates once. Therefore, the swing operation of the swing member 52 is speeded up. Therefore, the rendering device 30 can further enhance the rendering effect when the decorative body 55 is displaced.

  In the above embodiment, the pachinko machine 1 is an example of the “game machine” of the present invention. The gear member 275 is an example of the “first rotating member” in the present invention. The small gear 277 is an example of the “operation member” or “first gear member” in the present invention. The cam gear 280 is an example of the “second rotating member” or “second gear member” in the present invention. The tooth portion 277A is an example of the “first engagement portion” or “first tooth portion” in the present invention. The tooth portion 281 is an example of the “concave portion” and “second tooth portion” of the present invention. The protruding portion 275F is an example of the “second engaging portion” in the present invention. The sliding portion 250, the cam surface 285, and the decorative body support portion 246 are examples of the “applying means” of the present invention. The predetermined direction is an example of the “substantially front-rear direction” of the present invention. The axis C is an example of the “first axis” in the present invention. The axis D is an example of the “second axis” in the present invention.

  Of course, the present invention is not limited to the above-described embodiment, and various modifications are possible. The rotating member rotated by the small gear 277 is not limited to the cam gear 280. For example, the rotating member rotated by the small gear 277 may be a gear extending substantially along the front-rear direction. In this case, the configuration may be such that the rotational driving force of the decorative body motor 202 is transmitted to another member such as a rotational decorative body by the gear being rotated by the small gear 277.

  The sliding portion 250 is not limited to being pressed against the cam surface 285 by the weight of the swinging member 52. For example, a slightly compressed compression spring may be disposed between the extending portion 249 of the decorative body support portion 246 and the rear surface of the support body 59. In this case, the sliding portion 250 comes into contact with the cam surface 285 so as not to be pressed, and the frictional force generated between the sliding portion 250 and the cam surface 285 is greatly reduced as compared with the above embodiment. In the case where the small gear 277 rotates and moves in the second direction, for example, when the frictional force generated between the support shaft 59A and the cam gear 280 faces the first direction, the cam gear 280 rotates in the second direction. May be regulated. Even in this case, the small gear 277 can roll with respect to the tooth portion 281. That is, when the small gear 277 rotates and moves in the second direction, a portion of the cam gear 280 that contacts the support shaft 59A and the support shaft 59A apply a force that faces the cam gear 280 in the first direction. It may function as a granting means.

  The small gear 277 is not limited to being attached to the gear member 275. For example, only one small gear 277 may be attached to the gear member 275, or three or more small gears 277 may be attached. When three or more small gears 277 are attached, they may be arranged at equal intervals along the drive gear rotation direction or may not be arranged at equal intervals.

  The protruding portion 275F is not limited to being provided in the second extending portion 275E. The protruding portion 275F may protrude in the second direction from the first extending portion 275D. In this case, when the gear member 275 rotates in the second direction, the protruding portion 275F is engaged with the tooth portion 277A, and the rotation about the axis D of the small gear 277 is restricted.

  The number of cam surfaces 285 formed on the cam gear 280 is not limited to two. The cam surface 285 may be one or three or more. For example, when only one cam surface 285 is formed, the second cam surface 285B and the third cam surface 285C may be formed so that the gradient with respect to the drive gear rotation direction is gentler than in the above embodiment. Good. In this case, the swing amount of the swing member 52 with respect to the rotation amount of the motor gear 202A becomes small. Therefore, the rendering device 30 can accurately control the swing position of the swing member 52.

  The rotation center of the cam gear 280 is not limited to the axis C extending in the front-rear direction. The rotation center of the cam gear 280 may be, for example, an axis extending in the left-right direction (hereinafter referred to as a first axis). In this case, the cam gear 280 may be formed in a cylindrical shape extending in the left-right direction, and the cam surface 285 may be formed on the outer peripheral surface surrounding the first axis of the cam gear 280. For example, the cam surface 285 includes a portion extending in a direction approaching the first axis along the rotation direction around the first axis, and a portion spaced from the first axis, and the sliding portion 250 includes the cam surface 285. However, it may contact from the opposite side (for example, the front side) to the first axis. Thereby, the contact position of the sliding part 250 and the cam surface 285 is displaced in the front-rear direction as the cam gear 280 rotates around the first axis. Therefore, the swing member 52 swings about the axis E.

  The effect device 30 may be configured to linearly move the decorative body 55 in the left-right direction instead of the up-down direction. In addition, the effect device 30 may be configured to linearly move the decorative body 55 in a direction inclined with respect to the vertical direction and the horizontal direction in a front view, for example.

  The small gear 277 is not limited to being urged by the second extending portion 275E to rotate in the first direction. Hereinafter, a gear member 375 that is a first modification of the gear member 275 (see FIG. 6) and a small gear 377 that is a first modification of the small gear 277 (see FIG. 6) will be described with reference to FIG.

  The gear member 375 has the same configuration as that of the gear member 275 (see FIG. 6) except that the protrusion 275F (see FIG. 6) is not provided and the extended portion 375B is provided. The extending portion 375B is a columnar body that extends rearward from a portion on the front side of the gap 276 in the front wall portion 275A of the gear member 375. The extending portion 375B is formed integrally with the front wall portion 275A, and is disposed at a distance from the first extending portion 275D.

  The small gear 377 can rotate about the axis D, and can rotate about the axis C. The small gear 377 includes a tooth portion 377A. The tooth portion 377A has the same shape as the tooth portion 277A and meshes with the tooth portion 281 of the cam gear 280. The small gear 377 is provided with a central hole 377B formed in a circular shape around the axis C. A plurality of concave portions 377C are formed on the inner peripheral surface surrounding the central hole 377B in the circumferential direction. Each recess 377C is recessed in an arc shape in a direction away from the axis D. Each recessed portion 377C can accommodate an extended portion 375B.

  According to the above configuration, when the gear member 375 rotates in the first direction (arrow A1 direction), the extending portion 375B is accommodated in any one recess 377C of the small gear 377. The extending portion 375B and the recessed portion 377C are engaged. As a result, the small gear 377 is in a state in which rotation about the axis D is restricted. As the gear member 375 further rotates in the first direction, the extending portion 375B urges the small gear 377 in the first direction to rotate and move in the first direction. The small gear 377 rotates the cam gear 280 in the first direction. Accordingly, the swing member 52 (see FIG. 3) can swing between the first swing position and the second swing position.

  On the other hand, when the gear member 375 rotates in the second direction (arrow A2 direction), the first extending portion 275D comes into contact with the small gear 277 and rotates in the second direction. At this time, the extending portion 375B is separated from any portion of the inner peripheral surface surrounding the central hole 377B, and the small gear 377 is allowed to rotate about the axis D.

  The first extending portion 275D further rotates the gear member 375 in the second rotation direction. Accordingly, the small gear 377 rotates and moves in the second direction while rolling with respect to the tooth portion 281. The cam gear 280 does not rotate in the first direction.

  As described above, the small gear 377 moves differently depending on the rotation direction of the gear member 375. Therefore, the movement of the small gear 377 is diversified. The extending portion 375B extends rearward from the front wall portion 275A. Therefore, when the assembly operator places the small gear 377 in the gap 276, the extending portion 375B serves as a mark as an assembly position. Further, when the small gear 277 is disposed in the gap 276, the extended portion 375B is disposed inside the central hole 377B, so that the small gear 377 is not easily dropped from the gear member 375. Therefore, the assemblability of the small gear 377 to the gear member 375 is improved.

  In the present modification, the gear member 375 is an example of the “first rotating member” in the present invention. The small gear 377 is an example of the “operation member” in the present invention. The tooth portion 377A is an example of the “first engagement portion” in the present invention. The extending portion 375B is an example of the “second extending portion” in the present invention.

  Further, the small gear 277 is not limited to being provided in the power transmission unit 270 (see FIG. 5) that transmits the rotational driving force of the decorative body motor 202 to the swing member 52. Hereinafter, the shaft coupling member 400 newly provided in the present modification and the gear member 475 which is a second modification of the gear member 275 will be described with reference to FIG. In this modification, the gear member 475 is provided in a mechanism different from the power transmission unit 270 (see FIG. 5).

  The shaft connecting member 400 has a cylindrical shape extending substantially in the front-rear direction, and has a cylindrical hole 402A formed inside. A shaft member (not shown) extending along the axis C is fitted into the cylindrical hole 402A. The shaft member is connected to a drive motor (not shown). Therefore, the shaft member and the shaft coupling member 400 can be integrally rotated in the first direction or the second direction as the drive motor rotates.

  The cylindrical portion 402 is provided with two first extending portions 411, two second extending portions 412, and two projecting portions 416. The first extending portion 411, the second extending portion 412, and the protruding portion 416 are all formed integrally with the cylindrical portion 402.

  The two first extending portions 411 and the two second extending portions 412 extend from the outer peripheral surface of the cylindrical portion 402 toward the side opposite to the axis C. The two first extending portions 411 are arranged at symmetrical positions with the axis C therebetween. Similarly, the two second extending portions 412 are also arranged at symmetrical positions with the axis C therebetween. Each second extending portion 412 is arranged with a gap 450 in the second direction with respect to each first extending portion 411.

  A small gear 277 is disposed in the gap 450. A gear member 475 is provided on the opposite side to the axis C with respect to the two small gears 277. The gear member 475 is a substantially annular rotating member that can rotate around the axis C.

  The gear member 475 includes an inner tooth portion 475A and an outer tooth portion 475B. The inner tooth portion 475A is a tooth portion formed on the inner peripheral surface of the gear member 475, and the outer tooth portion 475B is a tooth portion formed on the outer peripheral surface of the gear member 475. Both the inner tooth portion 475A and the outer tooth portion 475B are formed over the rotational direction about the axis C. The inner tooth portion 475A meshes the respective tooth portions 277A of the two small gears 277. The outer tooth portion 475B meshes with a specific gear (not shown).

  According to the above configuration, when the shaft member (not shown) rotates in the first direction (arrow A1 direction) with the drive of the drive motor (not shown), the shaft connecting member 400 rotates in the first direction. The protruding portion 416 engages with and engages with the tooth portion 277A of the small gear 277. As a result, the small gear 277 is in a state where the rotation about the axis D is restricted. When the shaft connecting member 400 further rotates in the first direction, the second extending portion 412 urges the small gear 277 in the first direction via the protruding portion 416 to rotate and move in the first direction. Since the tooth portion 277A and the inner tooth portion 475A mesh with each other, the small gear 277 rotates the gear member 475 in the first direction. That is, the small gear 277 functions as a drive gear that rotates the gear member 475. As a result, the specific gear (not shown) that meshes with the outer tooth portion 475B rotates. In other words, the driving force of the driving motor (not shown) is allowed to be transmitted to the specific gear.

  On the other hand, when the drive motor rotates the shaft coupling member 400 in the second direction, the first extending portion 411 contacts the small gear 277 and rotates in the second direction. At this time, the protrusion 416 is separated from the small gear 277 in the second direction, and the small gear 277 is allowed to rotate about the axis D.

  When the first extending portion 411 further rotates the small gear 277 in the second direction, the small gear 377 starts rotating in the second direction. At this time, the gear member 475 receives a force in the second direction from the small gear 277. However, this force is smaller than the force required for the gear member 475 to rotate the stationary specific gear. That is, when the small gear 277 rotates and moves in the second direction, the gear member 475 is stopped by being given a force from the specific gear in the first direction. Therefore, the small gear 277 that rotates and moves in the second direction rotates about the axis D to roll with respect to the inner tooth portion 475A. Even if the small gear 277 rotates, the gear member 475 does not rotate, so that the drive force of the drive motor (not shown) is restricted from being transmitted to the specific gear.

  As described above, since the small gear 277 moves differently depending on the rotation direction of the shaft connecting member 400, the movement of the small gear 277 is diversified. In the present modification, the shaft connecting member 400 is an example of the “first rotating member” in the present invention. The gear member 475 is an example of the “second rotating member” or “second gear member” in the present invention. The inner tooth portion 475A is an example of the “concave portion” and “second tooth portion” in the present invention.

  It should be noted that all elements described in the claims, the description, and the drawings (for example, an image display device, a start port, etc.) are physically single unless explicitly stated to limit the number. Alternatively, there may be a plurality of arrangements, and the arrangement may be changed as appropriate. Further, the names (element names) given to the elements are merely given for convenience in describing the present case, and there is no particular awareness that a special meaning is caused thereby. Therefore, what is an element is not limitedly interpreted only by the element name. For example, the “rendering device” may be hardware alone or may include software.

  Furthermore, it is easy for a person skilled in the art to determine whether a plurality of elements among all the above elements should be integrally configured as appropriate, or whether one element is divided into a plurality of elements. Since it is clear that all patterns are within the expected range even if not all the patterns are described in the description etc., the statement that they are clearly excluded in the claims etc. Needless to say, all of these are included in the scope of the right according to the present invention. Therefore, merely adopting the difference in configuration within the range to the gaming machine because it is not described in the present embodiment does not mean that the right according to the present invention is avoided. . The same applies to differences in obvious ranges that can be easily considered by those skilled in the art from the present embodiment in the configuration and shape of each element.

<5. Remarks>
Hereinafter, the configuration of the present disclosure and the effects thereof will be exemplified. The parentheses noted below in the configuration illustrate the corresponding configuration of the present disclosure.

  A rendering device provided in a gaming machine (pachinko machine 1), a first direction centering on a first axis (axis C) extending in a predetermined direction (substantially front-rear direction), and a second opposite to the first direction A first rotating portion (first extending portion 275D) extending in a direction intersecting with the first direction, and the second extending relative to the first extending portion. A first rotating member (gear members 275 and 375, shaft coupling) having a second extending portion (second extending portion 275E) provided at an interval on the direction side and extending across the second direction. Member 400) and a member that is urged by the first extending portion or the second extending portion and moves in a direction in which the first rotating member rotates, and the first axis and An operating member (small gears 277, 377) rotatable around a parallel second axis (axis D), and the first When the rolling member rotates in the first direction, the operation member is in a state in which rotation about the second axis is restricted, while the first rotating member rotates in the second direction, An effect device (effect device 30) comprising switching means for rotating the operating member about the second axis.

  According to the above configuration, when the first rotating member rotates in the first direction, the operating member moves in the first direction without rotating around the second axis. On the other hand, when the first rotating member rotates in the second direction, the operating member moves in the second direction while rotating around the second axis. Therefore, the operation member moves differently depending on the direction in which the first rotation member rotates. Therefore, a rendering device that diversifies the movement of the operating member is realized.

  In the production device, the switching unit is provided in a first engagement portion (tooth portions 277A and 377A) provided in the operation member and the second extension portion, and the first rotation member is provided in the first rotation member. When rotating in the direction, a second engagement portion (protrusion portions 275F, 416) that engages with the first engagement portion may be provided. In this case, when the second engaging portion is engaged with the first engaging portion, the switching unit can bring the operating member into a state in which the rotation is restricted. Therefore, the rendering device can simplify the mechanism that restricts the rotation of the operating member.

  In the rendering device, the switching means contacts the operation member from one side in a direction orthogonal to the first axis, and has an uneven portion (tooth portion 281) formed in an uneven shape along the first direction. And a second rotating member (cam gear 280, gear member 475) rotatable about the first axis, and an applying means for applying a force directed toward the second direction to the second rotating member. (Sliding portion 250, cam surface 285, decorative body support portion 246). In this case, when the first rotating member rotates in the first direction, the operating member moves in the first direction in a state in which the rotation is restricted and is in contact with the uneven portion. As a result, the second rotating member rotates in the first direction. On the other hand, when the first rotating member rotates in the second direction, the operating member moves in the second direction while contacting the concavo-convex portion. In this case, the rotation of the second rotating member in the second direction is restricted by the force applied from the applying unit. Thereby, the operating member moves in the second direction while rotating around the second axis, and the second rotating member does not rotate. Therefore, the rendering device can switch between a state in which the rotation of the second rotation member is allowed and a state in which the rotation of the second rotation member is restricted according to the rotation direction of the first rotation member.

  In the production device, the switching unit is provided in a first engagement portion (tooth portions 277A and 377A) provided in the operation member and the second extension portion, and the first rotation member is provided in the first rotation member. When rotating in the direction, the second engaging portion (projecting portions 275F, 416) that engages with the first engaging portion, and the operating member from one side in the direction orthogonal to the first axis, A second rotating member (cam gear 280, gear member 475) having an uneven portion (tooth portion 281) formed in an uneven shape along the first direction and rotatable about the first axis; and the second An applying means (sliding portion 250, cam surface 285, decorative body supporting portion 246) for applying a force in the second direction to the rotating member is provided, and the operating member is a first gear member ( Small gears 277, 377), and the first engaging portion is centered on the second axis. The first tooth portions (tooth portions 277A and 377A) extending in the rotation direction, the second rotation member is a second gear member (cam gear 280, gear member 475), and the uneven portion is the first tooth portion. A second tooth portion (tooth portion 281, inner tooth portion 475 </ b> A) that extends parallel to the direction and meshes with the first tooth portion may be used. In this case, when the first rotating member rotates in the second direction, the operating member can reduce a load applied to the second rotating member. Therefore, the rendering device can stably rotate the first rotating member in the second direction.

  In the effect device, the second engaging portion protrudes from the second extending portion toward the operating member, and when the first rotating member rotates in the first direction, the second engaging portion bites into the first tooth portion. The protrusion part (protrusion part 275F, 416) which can be inserted may be sufficient. In this case, the operation member is in a state in which the rotation is restricted only by the protrusion portion biting into the first tooth portion. Therefore, the rendering device can simplify the mechanism that restricts the rotation of the operating member.

  In the effect device, the first extending portion and the second extending portion may be opposed to each other with the operation member interposed therebetween. In this case, since the operating member is disposed between the first extending portion and the second extending portion, the rendering device can improve assemblability.

  In the rendering device, a plurality of the operation members are arranged along a direction parallel to the first direction, and the first rotation member includes the first extension part and the second extension part. You may provide corresponding to each of an operation member. In this case, the rotational force transmitted from the first rotating member to the operating member is dispersed. Therefore, since the load applied to each operation member is reduced, the rendering device can have a long life.

  The rendering device may include a driving unit (decorative body motor 202) that rotates the first rotating member in the first direction and the second direction by being rotationally driven. In this case, the rendering device can stabilize the rotation of the first rotating member.

  In the effect device, the operation member may be provided on the opposite side of the first axis with respect to the uneven portion. In this case, the operating member is separated from the uneven portion with respect to the first axis. The operation member moving in the first direction easily rotates the second rotation member in the first direction. Therefore, the rendering device can efficiently transmit the rotational force of the first rotating member in the first direction to the second rotating member.

  In the effect device, the applying unit may include a contact portion (sliding portion 250) that contacts the second rotating member. In this case, when the first rotating member rotates in the second direction, the frictional force generated by the contact between the contact portion and the second rotating member is directed toward the first direction, so that force is applied to the second rotating member. Is done. Therefore, the rendering device can simplify the configuration of the providing unit.

  In the rendering device, the providing means is provided on the second rotating member, and extends along the first direction to one side (front side) of the predetermined direction (second cam surface 285B); A surface including a second surface (third cam surface 285C) extending along the first direction to the other side (rear side) opposite to the one side, and the rotation of the second rotating member A cam surface (cam surface 285) that slides with respect to the contact portion, and a swing support member that supports the contact portion and swings as the contact portion slides with respect to the cam surface (decorative body support portion 246). And may be provided. In this case, when the first rotating member rotates in the second direction, a frictional force generated by contact between the contact portion and the cam surface is applied to the second rotating member, so that the rotation of the second rotating member is restricted. The On the other hand, when the first rotating member rotates in the first direction, the second rotating member rotates in the first direction, so that the contact portion slides with respect to the cam surface and the swing support member swings. Therefore, the rendering device can convert the rotational force of the first rotation member into the swing force of the swing support member.

  A gaming machine (pachinko machine 1) provided with the above-described production device. In this case, the gaming machine has the same effect as the above-described effect device.

DESCRIPTION OF SYMBOLS 1 Pachinko machine 30 Production | presentation apparatus 246 Decoration body support part 250 Sliding part 275,375 Gear member 275D, 411 1st extension part 275E, 412 2nd extension part 275F, 416 Projection part 277,377 Small gear 277A, 377A Tooth Portion 280 Cam gear 281 Tooth portion 285 Cam surface 375B Extension portion 400 Shaft coupling member 475 Gear member 475A Inner tooth portions C and D Axes

Claims (6)

A production device provided in a gaming machine,
A member that rotates in a first direction centering on a first axis extending in a predetermined direction and a second direction opposite to the first direction, the first extending extending across the first direction A first rotating member having an extending portion and a second extending portion that is provided on the second direction side with respect to the first extending portion and that extends across the second direction. When,
A member that is urged by the first extending portion or the second extending portion and moves in a direction in which the first rotating member rotates, and is a second axis that is parallel to the first axis along with the movement. An operating member rotatable about
When the first rotating member rotates in the first direction, the operation member is set in a state in which rotation about the second axis is restricted, while the first rotating member rotates in the second direction. In this case, there is provided an effect device comprising: a switching unit that makes the operation member rotatable about the second axis. The switching means is
A first engagement portion provided on the operating member;
A second engaging portion that is provided in the second extending portion and engages with the first engaging portion when the first rotating member rotates in the first direction;
The rendering device according to claim 1, further comprising: The switching means is
A second member that contacts the operation member from one side in a direction orthogonal to the first axis, has a concavo-convex portion formed in a concavo-convex shape along the first direction, and is rotatable about the first axis. A rotating member;
The rendering device according to claim 1, further comprising: an imparting unit that imparts a force toward the second direction to the second rotating member. The switching means is
A first engagement portion provided on the operating member;
A second engaging portion that is provided in the second extending portion and engages with the first engaging portion when the first rotating member rotates in the first direction;
A second member that contacts the operation member from one side in a direction orthogonal to the first axis, has a concavo-convex portion formed in a concavo-convex shape along the first direction, and is rotatable about the first axis. A rotating member;
An applying means for applying a force toward the second direction to the second rotating member;
The operating member is a first gear member;
The first engagement portion is a first tooth portion extending in a rotation direction around the second axis,
The second rotating member is a second gear member;
The rendering device according to claim 1, wherein the uneven portion is a second tooth portion extending in parallel with the first direction and meshing with the first tooth portion.   The second engaging portion protrudes from the second extending portion toward the operation member, and can engage with the first tooth portion when the first rotating member rotates in the first direction. The rendering device according to claim 4, wherein the rendering device is a protruding portion.   The rendering device according to claim 1, wherein the first extending portion and the second extending portion are opposed to each other with the operation member interposed therebetween.

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