JP6167120B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine provided with a movable body.

  For example, a pachinko machine, which is one of the representative examples of gaming machines, has a game area where a pachinko ball is launched on the front side of a game board set in the machine, and displays effects such as a change display of symbols. The symbol display device to be performed is arranged so that the display surface can be viewed from the front side. This pachinko machine displays symbols on the symbol display device when a pachinko ball wins a prize opening such as a start prize opening provided in the game area, and a predetermined combination as a result of the symbol fluctuation display. When the symbol is stopped and displayed, a so-called jackpot that is advantageous to the player is generated. In addition, a movable body corresponding to the motif of the pachinko machine is arranged on the game board of the pachinko machine, etc., and the movable body performs a predetermined presentation operation in accordance with the change display of the symbol on the symbol display device. (For example, refer patent document 1).

JP 2008-100120 A

  Here, the gaming machine described in Patent Document 1 includes a movable body that rotates with respect to the game board, and includes a relay terminal board as an electrical component provided on the movable body and a control unit provided on the game board side. Connected by signal line. In such a configuration, since the signal line is twisted with the rotation of the movable body, it is necessary to rotate the movable body within a range in which the signal line is not broken with the twist, and the operation is not interesting.

  In view of the above-described problems inherent in the prior art, the present invention has been proposed to suitably solve these problems, and provides a gaming machine capable of increasing the degree of freedom of operation of a movable body having electrical components. For the purpose.

In order to overcome the above-mentioned problems and achieve the intended purpose, a gaming machine according to claim 1 of the present application is:
A rotary movable body (130) having an electrical component (141) is provided so as to be rotatable with respect to the mounting portion (101), and a control unit positioned on the mounting portion (101) side and the rotary movable body (130). In a gaming machine configured to electrically connect an electrical component (141),
The attachment portion (101) is provided with a rotating connection unit (70) in which a rotating member (82) that rotates as the rotating movable body (130) rotates is accommodated in a case body (72). The rotation connection unit (70) includes a connector connection portion (79a) to which a connector of wiring connected to the control portion side is connected, and a first conductive portion (80) to which the control portion is electrically connected. (79) holds the casing body (72), said electrical component connector connecting portion to which the connector of the wiring is connected leading to (141) (87a) and said electrical components (141) are electrically connected The rotating substrate (87) having the second conducting portion (90) is configured to be held by the rotating member (82), and the first conducting portion (80) and the second conducting portion are rotated when the rotating member (82) is rotated. The portion (90) is configured to be electrically conductive by sliding in the extending direction of the rotation axis (L) ,
Said annular support portion around the rotational axis (L) is a rotatable member (130) (124) is provided in the mounting portion (101) to be separated in the transverse direction from the rotation axis (L) Rutotomoni, An annular wall portion (135) extending annularly around the rotation axis (L) and overlapping the support portion (124) in the direction intersecting the rotation axis (L) is provided on the rotary movable body (130). In response to the rotation of the rotary movable body (130), the support portion (124) is configured to receive a force acting in the direction intersecting the rotation axis (L) from the annular wall portion (135) .
The case body (72) includes a restricting portion (77) protruding in an annular shape centering on the rotation axis (L),
The rotating member (87) has a restricted portion (83), and the outer peripheral surface of the restricted portion (83) is the inner periphery of the restricting portion (77) as the rotating movable body (130) rotates. An opening (84) for exposing the connector connecting portion (87a) of the rotating substrate (87) to the surface of the regulated portion (83) facing the rotating movable body (130), and configured to be in sliding contact with the surface. ) Is formed,
The annular wall portion (135) is positioned on the outer peripheral side of the restricting portion (77), and the opposed surface of the restricted portion (83) is positioned on the inner peripheral side of the annular wall portion (135). It is a summary.
According to the first aspect of the present invention, the first conductive portion and the second conductive portion of the rotary connection unit are brought into sliding contact and are electrically connected to each other, so that the electrical component can be used regardless of the number of rotations in one direction of the rotary movable body. In addition, the electrical connection state of the control unit can be maintained. In addition, the support for receiving the force acting in the crossing direction of the rotation axis from the rotary movable body is not provided in the rotary connection unit, but is provided in the mounting portion where the rotary connection unit is disposed, thereby providing a load on the rotary connection unit. Can be reduced. Thereby, damage and deformation | transformation of a rotation connection unit can be prevented, and since the relative position of a 1st conduction | electrical_connection part and a 2nd conduction | electrical_connection part can be kept constant, an electric component and a control part can be rotated freely rotating a movable body. The electrical connection state of can be reliably maintained.
Further, by configuring the regulated portion of the rotating member to be in sliding contact with the inner peripheral surface of the regulating portion provided on the case body, the displacement of the rotational position of the rotating member is regulated, and the electrical components and the electrical control unit are electrically connected. The connection state can be reliably maintained.

The invention according to claim 2
The rotary movable body (130) is provided with a shaft fixing portion (133) for fixing the rotating shaft (131) rotating by the driving force of the driving means (111), and the shaft fixing portion (133) and The gist is that a connecting wall (134) for connecting the annular wall (135) is provided.
According to the invention which concerns on Claim 2 , the axis | shaft fixing | fixed part and annular wall part which are provided in a rotation movable body can be simultaneously reinforced with a connection wall part.

The invention according to claim 3
An annular insertion member (150) is inserted between the annular wall portion (135) and the support portion (124), and the rotation axis (L) is rotated along with the rotation of the rotary movable body (130). The force acting in the intersecting direction is configured to be supported by the support portion (124) via the insertion member (150),
The insertion member (150) includes a cylindrical first intermediate portion (151) that opens in the extending direction of the rotation axis (L), and an end of the first intermediate portion (151) from the rotation axis ( L) and a second interposition part (152) extending in the intersecting direction of L), the first interposition part (151) is interposed between the annular wall part (135) and the support part (124), The second interposition part between the projecting end part of the support part (124) and the rotary movable body (130) or between the projecting end part of the annular wall part (135) and the mounting part (101). (152) is interposed,
The rotating wall (130) facing the protruding end of the support part (124) across the second interposition part (152) or the annular wall part (135) across the second interposition part (152) The mounting portion (101) facing the projecting end portion is provided with a projecting portion (136) projecting toward the second interposed portion (152), and the projecting end portion of the projecting portion (136) is The gist is that it is configured to contact the second interposition part (152).
According to the third aspect of the present invention, the frictional resistance that can be generated between the support portion and the annular wall portion as the rotary movable body rotates by inserting the insertion member between the support portion and the annular wall portion. Therefore, the rotary movable body can be smoothly rotated.
Further, the protrusion provided on the rotating movable body or the mounting portion is configured to contact the second interposition portion provided on the insertion member, so that it is between the protruding end portion of the support portion and the rotating movable body, or in an annular shape. The frictional resistance that can occur between the protruding end portion of the wall portion and the mounting portion can be reduced, and the rotating movable body can be smoothly rotated.

The invention according to claim 4
The protrusion (136) is provided so as to be aligned with the protruding end of the support portion (124) or the protruding end of the annular wall (135) in the extending direction of the rotation axis (L). This is the gist.
According to the invention of claim 4 , the second interposition is provided between the protruding end portion or the protruding portion of the annular wall portion provided on the rotary movable body and the protruding end portion of the protruding portion or the support portion provided on the attachment portion. The part can be supported stably.

  According to the gaming machine according to the present invention, it is possible to increase the degree of freedom of operation of a movable body having an electrical component.

It is a front view which shows the pachinko machine which concerns on an Example. It is a front view which shows the game board which concerns on an Example. It is the sectional view on the AA line in FIG. It is a disassembled perspective view which shows the state which looked at the movable production apparatus based on an Example from the front side. It is a disassembled perspective view which shows the state which looked at the movable production | presentation apparatus based on an Example from the back side. FIG. 3 is an exploded view of the movable effect device taken along line BB in FIG. 2. It is the sectional view on the AA line in FIG. 2, and has expanded and shown the attaching part and a part of rotation movable body. It is the sectional view on the AA line in FIG. 2, and has expanded and showed the rotation connection unit. It is a disassembled perspective view which shows the state which looked at the rotary movable body which concerns on an Example from the front side.

  Next, a gaming machine according to the present invention will be described below with reference to the accompanying drawings by way of preferred embodiments. In the embodiment, a pachinko machine that plays a game using a pachinko ball (game ball) as a game medium will be described as an example. Further, in the following description, “front”, “rear”, “left”, and “right” are states when the pachinko machine is viewed from the front side (player side) as shown in FIG. 1 unless otherwise specified. It points at.

(About pachinko machine 10)
As shown in FIG. 1, the pachinko machine 10 according to the embodiment includes an outer frame 11 that is formed in a rectangular frame shape and is fixed to an installation frame base (not shown) of a game shop. Further, in the pachinko machine 10, a middle frame 12 as a main body frame on which a game board 20 described later is detachably held is assembled to the front side of the opening of the outer frame 11 so as to be opened and closed and detachable. Below the game board 20 in the middle frame 12, a ball launcher (not shown) that launches a pachinko ball toward the front surface (game area 21a) of the game board 20 is disposed. Furthermore, a front frame 13 as a decorative frame is assembled to the pachinko machine 10 so as to be openable and closable on the front side of the middle frame 12. The front frame 13 is provided with a window plate 13a that covers the front surface (game area 21a) of the game board 20 in a state where it can be seen through from the front of the machine. At a lower position of the front frame 13, a ball tray 15 for storing the pachinko balls before being supplied to the hitting position of the pachinko balls by the ball launcher is integrally assembled. The tray 15 is also configured to open and close integrally. The game board 20 is provided with a symbol display device 17 capable of variably displaying various symbols (see FIG. 2). In the embodiment, as the symbol display device 17, a drum-type display device in which various symbols are arranged and displayed on the display surface 17 a composed of the outer peripheral surfaces of a plurality of rotatable rotating drums (see FIG. 3) is used. As the symbol display device 17, a conventionally known display device capable of variably displaying various symbols such as a liquid crystal display device, an LED display device, and a belt-type display device can be used as the symbol display device.

(About game board 20)
As shown in FIG. 2, the game board 20 includes a flat plate member 21 and an installation member 50 (see FIG. 3) attached to the rear side of the plate member 21. In addition, the symbol display device 17 is detachably disposed on the installation member 50, and the display surface 17 a of the symbol display device 17 is disposed on the front side via a frame-shaped decorative body 25 (described later) provided on the plate member 21. It is comprised so that it can visually recognize from. The game board 20 displays the symbols in a variable manner on the display surface 17a of the symbol display device 17 when a pachinko ball launched into the game area 21a wins the start winning opening 41a of the start winning portion 41. A display effect such as a symbol variation effect that is stopped and displayed later is performed. In addition, the game board 20 is configured such that the movable effect device 100 is installed on the front surface of the installation member 50 so that the rotary movable body 130 of the movable effect device 100 can be viewed from the front of the pachinko machine 10. The movable body 130 performs an effect by rotating operation or light emission in association with the symbol variation effect on the symbol display device 17.

(About the plate member 21)
The plate member 21 is configured by attaching a decorative synthetic resin sheet or the like on which various patterns or the like are drawn on the surface of a wood board formed in a substantially rectangular shape. As shown in FIG. 2, a substantially circular game area 21a in which a pachinko ball can flow down is defined on the front surface of this plate member 21 (between the window plate 13a). Further, a through hole 22 (see FIG. 3) is formed in the plate member 21 (game area 21a) so as to penetrate in the front-rear direction. A certain frame-shaped decorative body 25 is disposed from the front side. The display surface 17a of the symbol display device 17 is configured to face the front of the game board 20 through a display window 29 provided so as to penetrate the frame-shaped decorative body 25 back and forth. Around the frame-shaped decorative body 25, a start winning portion 41, a special winning portion 42, and a normal winning portion 43 are arranged as a winning portion (winning device) that can win a pachinko ball flowing down the game area 21a. Yes. Specifically, at the lower position of the frame-shaped decorative body 25, there is provided a start winning portion 41 provided with upper and lower start winning ports 41a through which pachinko balls flowing down the game area 21a can win. Below the start winning portion 41, a special winning portion 42 provided with a special winning opening 42a through which a pachinko ball flowing down the game area 21a can be awarded is arranged. Further, a normal winning portion 43 provided with a special winning opening 42a through which a pachinko ball flowing down the gaming area 21a can be awarded at a position along the lower edge of the gaming area 21a at the lower left of the frame-shaped decorative body 25. Is arranged. On the left side of the frame-shaped decorative body 25, a ball passage gate 44 having a gate port 44a that allows passage of pachinko balls in the game area 21a is disposed. On the plate member 21, pachinko balls that have flowed down without winning any of the various winning portions 41, 42, 43 (excluding the ball passing gate 44) are provided at the bottom of the game area 21a, that is, below the special winning portion 42. An out port 23 for discharging is formed on the back side. The plate member 21 may be formed of a transparent synthetic resin material such as acrylic or polycarbonate.

  As shown in FIG. 2, the start winning portion 41 is provided with a pair of wing members 41 b that can swing so that their upper ends are close to and away from each other at the left and right positions sandwiching the lower start winning port 41 a. By swinging the blade member 41b by a solenoid (not shown), the lower start winning opening 41a is opened so that a pachinko ball can be won. In the pachinko machine 10, symbol variation starts on the display surface 17 a of the symbol display device 17 when a pachinko ball that has won the start winning opening 41 a of the start winning unit 41 is detected by a start winning sensor (not shown). It has come to be.

  As shown in FIG. 2, the special prize winning section 42 is provided with an opening / closing member 42b for closing and opening the special prize opening 42a. The opening / closing member 42b is opened and closed by a solenoid (not shown) to thereby open the special prize opening 42a. Can be opened and closed. In the pachinko machine 10, when the symbols are stopped and displayed on the symbol display device 17 in a predetermined symbol combination (for example, three sets of the same symbols) as a result of the symbol variation effect performed by the symbol display device 17, the so-called "" A big hit occurs. As a result, in the pachinko machine 10, the special winning opening 42a of the special winning portion 42 is opened, and the pachinko balls won in the special winning opening 42a are detected by a special winning sensor (not shown), so that a large number of winning balls Is configured to be paid out to the ball tray 15. FIG. 2 shows a state where the special winning opening 42a is closed by the opening / closing member 42b.

  As shown in FIG. 2, the ball passing gate 44 is provided upstream of the start winning portion 41 and the special winning portion 42 in the game area 21a, and the pachinko ball that has passed through the gate port 44a of the ball passing gate 44. So that the game area 21a can flow downward and can enter the start winning port 41a of the start winning unit 41, the special winning port 42a of the special winning unit 42, or the normal winning port 43a of the normal winning unit 43. It is configured. The ball passage gate 44 is provided with a gate sensor (not shown) that outputs a detection signal that triggers a change display of a normal symbol in a normal symbol display device (not shown) when a pachinko ball passing through the gate port 44a is detected. ing. In the pachinko machine 10, whether or not to open the blade member 41b of the start winning portion 41 when the pachinko ball passing through the gate port 44a of the ball passage gate 44 is detected by a gate sensor (not shown). A lottery (determination) is performed.

(About the frame-shaped decorative body 25)
As shown in FIGS. 2 and 3, the frame-shaped decorative body 25 includes a base plate portion 25 a that abuts on the front surface of the plate member 21 and serves as a screwing portion to the plate member 21, and the base plate portion 25 a. A fitting piece 25b that protrudes rearward from the rear surface and is inserted into the through-hole 22 and protrudes forward from the front surface of the base plate 25a, and is formed on the left and right edges from the upper edge of the frame-shaped decorative body 25. And a hook-like portion 25c extending over the portion. The frame-shaped decorative body 25 is attached by inserting the fitting piece 25b into the through-hole 22 and screwing it through the base plate portion 25a. The frame-shaped decorative body 25 is a frame-shaped member formed in accordance with the opening edge of the through hole 22, and defines a display window 29 and an effect window 30 that open in the front-rear direction. Here, the production window 30 and the display window 29 are formed on the frame-shaped decorative body 25 in a state of being vertically divided by a window forming member 31 extending left and right between the left and right side edges of the bowl-shaped part 25c. Yes. And the display surface 17a of the symbol display device 17 attached to the installation member 50 faces the display window 29 provided below the window forming member 31 from the rear side.

  As shown in FIGS. 2 and 3, inside the opening of the presentation window 30 provided above the display window 29 (above the window forming member 31) in the frame-shaped decorative body 25, A rotary movable body 130 (described later) is positioned so that it can be viewed from the front side. That is, the frame-shaped decorative body 25 is configured to enclose the display window 29 that the display surface 17a of the symbol display device 17 faces and the effect window 30 that the rotary movable body 130 faces. The rotary movable body 130 is configured to rotate around a rotary shaft 131 extending in the front-rear direction, and the presentation window 30 is formed in a size and shape that allows the rotary movable body 130 to rotate inside. .

  As shown in FIG. 3, the frame-shaped decorative body 25 is driven into the game area 21a by providing the hook-shaped portion 25c so as to protrude forward from the front surface of the game board 20 forming the game area 21a. The pachinko ball is prevented from flowing down across the display window 29 and the production window 30 by the hook-shaped portion 25c. As shown in FIG. 2, the frame-shaped decorative body 25 is formed with a stage 27 on the upper surface of the lower edge portion that forms the lower edge of the display window 29 for rolling the pachinko ball taken from the game area 21 a to the left and right. In addition, a ball insertion portion 26 is provided that opens to the game area 21a on the left side of the bowl-shaped portion 25c and guides the pachinko balls taken from the game area 21a to flow down to the left side of the stage 27. The pachinko ball guided from the ball insertion portion 26 to the stage 27 is discharged from the discharge portion of the stage 27 to the game area 21a after rolling the stage 27. A start winning portion 41 having an upper start winning opening 41 a that opens upward is disposed below the stage 27, so that pachinko balls discharged from the stage 27 do not pass through the stage 27. As compared with the case where the vicinity of the start winning portion 41 is reached, it is easier to win the start winning opening 41a on the upper side of the start winning portion 41. In addition, a ball passage 28 is formed on the right side of the bowl-shaped portion 25c to allow a pachinko ball that rolls the bowl-shaped portion 25c to the right to pass below the frame-shaped decorative body 25.

(About the installation member 50)
The installation member 50 is made of a synthetic resin material, and as shown in FIG. 3, the installation plate 50 has an opening on the front side in which an outer peripheral plate portion 50b is formed to extend forward from the outer peripheral edge of the installation plate portion 50a formed in a substantially rectangular shape. It is formed in a box shape. The installation member 50 is attached to the plate member 21 in a state in which the front end of the outer peripheral plate portion 50b is in contact with the rear surface of the plate member 21, and on the rear side of the plate member 21, the front surface of the installation plate portion 50a and each outer peripheral plate portion. The inner surface of 50b is comprised so that the installation space 52 which can accommodate a member is defined. The symbol display device 17 is detachably installed on the installation member 50 through an installation opening 51 that is provided behind the display window 29 so as to penetrate the installation plate portion 50a back and forth. The display surface 17 a faces the through-hole 22. In addition, the rotary movable body 130 of the embodiment is configured to protrude forward from the installation member 50 and to be positioned inside the presentation window 30.

  As shown in FIG. 3, the installation member 50 is provided with a base member 53 whose front surface is decorated at the opening front end portion of the installation space 52. The base member 53 is provided so as to be close to the rear end upper side of the window forming member 31 provided in the frame-shaped decorative body 25 and to extend to the left and right along the window forming member 31. The board 20 is configured such that the front surface of the base member 53 can be visually recognized from the lower edge portion of the effect window 30 formed on the upper side of the window forming member 31. A mounting portion 101 (see FIG. 7) that supports the rotary movable body 130 of the movable effect device 100 on the front side is fixed to the rear end surface of the base member 53 so that the mounting portion 101 is positioned in the installation space 52. The rotary movable body 130 supported by the mounting portion 101 is disposed in front of the base member 53, and the rotary movable body 130 rotates at the front end position of the game board 20 (inside the effect window 30). It is like that. The installation member 50 is provided with a background decoration plate 54 for decorating the back of the rotatable movable body 130. The background decoration plate 54 is disposed at the rear end portion of the installation space 52 facing the front surface of the installation plate portion 50a, and the center portion overlaps the rear of the rotary movable body 130 and faces left and right and above the rotary movable body 130. It is configured to extend greatly.

(About control device)
On the rear surface of the game board 20 (installation member 50), a main control device (not shown) that performs overall control relating to the game, and an effect control device that performs overall control related to the effect in response to a command from the main control device ( A control device such as a display control device (not shown) that controls the symbol display device 17 in response to a command from the effect control device is detachably disposed. The main control device includes a detection signal from a start winning sensor that detects a pachinko ball winning in the start winning opening 41a, a detection signal from a special winning sensor that detects a pachinko ball winning in a special winning opening 42a, a gate opening A detection signal from a gate sensor that detects a pachinko ball passing through 44a and a detection signal from a normal winning sensor (not shown) that detects a pachinko ball that has won a normal winning opening 43a are input. The main control device includes a main control CPU capable of executing control operations in a predetermined procedure, a main control ROM storing a control program for the main control CPU, and a main control RAM capable of writing and reading necessary data. And other electronic components (both not shown).

The main controller updates the values of various random numbers such as a hit determination random number, a hit design random number, and a variation pattern distribution random number every predetermined cycle, and the updated value is stored in a setting area of the main control RAM. The value before update is rewritten by storing (setting), and random number update processing (random number generation processing) is executed. For example, in the main control device, when a detection signal is input from the start winning sensor, the main control CPU acquires a hit determination random number according to the input timing of the detection signal, and the hit determination random number Compare with the judgment value and perform a lottery (big hit judgment) as to whether or not to win. In the main control device, when the result of the hit determination is a win, the hit effect is determined from the variation pattern table including only the hit effect. On the other hand, when the result of the hit determination is out of place, the out effect is determined from the variation pattern table including only the out effect. The determination of the winning effect and the disappointing effect is performed by a random number acquired by the main control CPU, similarly to the winning determination. The variation pattern of the hit effect and the off-stage effect determined from the variation pattern table specifies at least the variation time and the content of the effect of the symbol variation effect. Then, in the pachinko machine 10, the display control device causes the symbol display device 17 to perform the symbol variation effect based on the control signal of the effect control device output according to the lottery result of the main control device. Further, in the pachinko machine 10, based on the control signal of the effect control device output in accordance with the lottery result of the main control device, the rotary movable body 130 is caused to rotate or emit light, or from a speaker (not shown). Sound effects are output. The movable effect device 100 may be configured to produce an effect based on a detection signal from a special prize sensor, a gate sensor, or a normal prize sensor.

(About movable effect device 100)
As shown in FIGS. 4, 5, and 7, the movable effect device 100 is attached to the installation member 50 (game board 20) and is rotatably supported by the rotation shaft 131 with respect to the installation unit 101. In addition, a rotary movable body 130 having a light emitting substrate (electrical component) 141 and drive mechanisms 115, 116, and 117 disposed on the mounting portion 101 and driving the rotary movable body 130 to rotate are provided. Here, the rotary movable body 130 has a rotary shaft 131 fixed to the rear surface, the rotary movable body 130 is positioned in front of the mounting portion 101, and the rotary movable body 130 is in a predetermined direction (in the embodiment, the front-rear direction). ), And is rotatably supported by the mounting portion. The rear end side of the rotating shaft 131 is connected to driving mechanisms 115, 116, and 117 attached to the mounting portion 101, and when the rotating shaft 131 rotates by driving of the driving mechanisms 115, 116, and 117, the rotating shaft 131 rotates. The rotary movable body 130 is configured to rotate in conjunction with the rotation. That is, the movable effect device 100 is configured such that the rotary movable body 130 rotates around a rotation axis (straight line L shown in FIG. 8 and the like) extending in the front-rear direction as the drive mechanisms 115, 116, 117 are driven. Has been. And in this movable production | presentation apparatus 100, the insertion member 150 is inserted between the rotation movable body 130 and the attaching part 101, and it is comprised so that the slidability at the time of rotation of the rotation movable body 130 may be improved. .

  The movable effect device 100 is configured to electrically connect the light emitting substrate 141 of the rotatable movable body 130 to an effect control device disposed on the rear side of the game board 20 via a wiring, a relay substrate, or the like. Based on the control signal of the effect control device, the light emitting body (LED) 142 of the light emitting substrate 141 is controlled to emit light, whereby the light emission display by the rotary movable body 130 is performed. Here, as shown in FIGS. 6 and 7, the mounting portion 101 of the movable effect device 100 includes a light emitting board 141 provided on the rotary movable body 130 and an effect control device provided on the attachment portion 101 side (game board 20). The rotary connection unit 70 (see FIG. 8) is relayed. The rotary connection unit 70 of the movable effect device 100 is electrically connected to the conductive piece (first conductive portion) 80 electrically connected to the effect control device and the light emitting substrate 141 to rotate the rotary movable body 130. Accordingly, a conductive surface portion (second conductive portion) 90 that rotates about the rotation axis L is provided, and the conductive surface portion 90 and the conductive piece 80 are in sliding contact with each other to be conductive.

(About mounting part 101)
As shown in FIGS. 3, 6, and 7, the attachment portion 101 includes drive attachment members 102, 103 to which drive mechanisms 115, 116, 117 that rotate the movable movable body 130 and an in-situ sensor 114 are attached; And a support cover 120 that is attached to the drive attachment members 102 and 103 and supports the rotary movable body 130, and the support cover 120 supports a force acting in the crossing direction of the rotation axis L accompanying the rotation of the rotary movable body 130. Is configured to do. The mounting portion 101 is for holding the rotary connection unit 70 between a first holding frame portion 110 described later of the drive mounting members 102 and 103 and a second holding frame portion 125 described later of the support cover 120. The unit accommodating portion 126 is configured to be defined. The drive mechanisms 115, 116, and 117 include a drive motor 115, a drive gear 116, and a driven gear 117, and the drive gear 116 is fixed to an output shaft 115 a that protrudes from the drive motor 115 as a drive source. A driven gear 117 fixed to the rotating shaft 131 is configured to mesh with the drive gear 116. That is, the drive mechanisms 115, 116, and 117 are configured to be able to rotationally drive the rotary movable body 130 together with the rotary shaft 131 as the drive motor 115 is driven. The original position sensor 114 detects the detection piece 117a provided on the outer periphery of the driven gear 117, whereby the rotation original position of the rotary movable body 130 (in the embodiment, the front surface of the rotary movable body 130 is in the state shown in FIG. (Rotation position) is detected.

  Here, as shown in FIG. 3, the mounting portion 101 is accommodated in an installation space 52 defined by the installation member 50, and is located inside the presentation window 30 of the frame-shaped decorative body 25 and is a base member 53. Further, the rotary movable body 130 is supported so as to perform a rotating operation and light emission display on the front side. In other words, the presence of the rotary movable body 130 is enhanced by causing the rotary movable body 130 to perform a rotating operation and light emission display at a position close to the player side. In addition, the rotary movable body 130 performs the rotating operation and the light emitting display at a position close to the decoration of the frame-shaped decorative body 25 and the base member 53 positioned around the presentation window 30 in the frame-shaped decorative body 25, thereby rotating the movable movable body. The effect of decoration is enhanced by strengthening the relationship between 130 and surrounding decorations. Further, the background decoration plate 54 is provided at the rear end portion of the installation space 52 to ensure the distance between the background decoration plate 54 and the rotary movable body 130 to the maximum, so that the background decoration plate 54 and the rotary movable body are secured. By emphasizing the impression that the rotary movable body 130 is pushed forward due to the perspective difference with respect to 130, the presence of the rotary movable body 130 is enhanced. Here, the attachment portion 101 is supported by a base member 53 provided at the front end portion of the installation space 52. Thereby, the rotary movable body 130 rotating on the front side of the base member 53 can be supported by the rotary shaft 131 formed with a minimum length, and the rotational direction of the rotary axis L by the centrifugal force accompanying the rotation of the rotary movable body 130. Prevents rattling. In addition, the attachment portion 101 is provided with a support portion 124 (described later) that supports the rotary movable body 130, and a force that acts in the direction intersecting the rotation axis L as the rotary movable body 130 rotates is supported by the support portion 124. The rotation movable body 130 is prevented from rattling in the crossing direction of the rotation axis L.

(About drive mounting members 102 and 103)
As shown in FIG. 6 and FIG. 7, the mounting portion 101 includes a rear member 102 and an intermediate member 103 as drive mounting members 102 and 103, and the rear member 102 and the intermediate member 103 are assembled. Thus, a space (gear housing space 111) is defined on the inner side. The drive mounting members 102 and 103 are respectively formed with cylindrical insertion holes 106 at positions aligned in the front-rear direction on the rear member 102 and the intermediate member 103, and the rotation shaft 131 of the rotatable movable body 130 is inserted in the front-rear direction. The hole 106 is inserted from the front side. The insertion hole portion 106 is provided with a bearing member 107 that supports the rotary shaft 131 so that the rotary shaft 131 rotates smoothly. The bearing member 107 is made of polyacetal (POM) or the like having excellent self-lubricity, and is inserted into the insertion hole portion 106 and has a receiving cylinder 107a in which a receiving hole for inserting the rotating shaft 131 is formed. A flange 107 b that protrudes outward from the end of the receiving tube 107 a and is regulated by contact with the insertion hole 106 is provided. A retaining member 108 is attached to the rotating shaft 131 at an end protruding rearward of the drive mounting members 102 and 103 through the insertion hole portion 106 of the rear member 102, and the retaining member 108 is attached to the rear side. The rotating shaft 131 is configured not to come out forward by coming into contact with the flange 107b of the bearing member 107 in which the receiving cylinder 107a is inserted into the insertion hole portion 106 of the member 102 from the rear side. That is, the rotary shaft 131 is sandwiched between the insertion hole portions 106 of the drive mounting members 102 and 103 via the bearing member 107. The driven gear 117 is housed in the gear housing space 111 of the drive mounting members 102 and 103 so as to rotate integrally with the rotating shaft 131.

  Further, as shown in FIG. 5, the rear surface of the rear member 102 is provided with a motor attachment portion 105 to which the drive motor 115 is attached. A gear through hole 105a that opens into the gear housing space 111 is formed in the motor attachment portion 105, and an output shaft 115a of the drive motor 115 attached to the motor attachment portion 105 is connected to the gear housing space 111 through the gear through hole 105a. The drive gear 116 fixed to the output shaft 115 a is positioned in the gear housing space 111 and meshes with the driven gear 117 fixed to the rotary shaft 131. Further, the mounting portion 101 has an in-situ sensor 114 mounted on a sensor mounting portion 109 formed on the rear surface of the intermediate member 103 (the surface on the gear housing space 111 side), and the detection piece 117a provided on the driven gear 117 is geared. The in-situ sensor 114 can detect within the accommodation space 111. The sensor mounting portion 109 of the intermediate member 103 is formed so that an exposure port 109b into which the original position sensor 114 is fitted penetrates forward and backward, and the detection piece 117a can be detected by fitting into the exposure port 109b. The original position sensor 114 can be aligned with the position.

  As shown in FIGS. 4, 6, and 7, a first holding frame portion 110 for holding the rotary connection unit 70 is formed on the front wall 104 of the intermediate member 103. The first holding frame portion 110 is formed in a rectangular frame shape that protrudes forward from the front wall 104 of the intermediate member 103. The first holding frame portion 110 is aligned with a second holding frame portion 125 (described later) provided on the support cover 120 in the front-rear direction, and the first holding frame portion 110, the front wall 104, and the support cover 120 (described later). A unit housing portion 126 is defined inside the second holding frame portion 125 and the cover base portion 121, and the rotational connection unit 70 is held inside the unit housing portion 126. The first holding frame portion 110 includes a first upper frame portion 110a that forms the upper side, a first lower frame portion 110b that forms the lower side, and a first side frame portion 110c that forms the left and right sides. . Here, the first holding frame portion 110 is formed to be slightly larger than the upper and lower and left and right outlines of the rotary connection unit 70, and the rotary connection unit 70 is vertically and horizontally located inside the first holding frame portion 110. It can be moved slightly.

  That is, when the support cover 120 that receives a force in the direction intersecting the rotation axis L from the rotary movable body 130 is displaced relative to the intermediate member 103 (wobbles), the rotary connection unit 70 in the unit accommodating portion 126. Can be displaced following the support cover 120. The first side frame portion 110c on the right side of the first holding frame portion 110 is formed in a concave shape in which a portion corresponding to the position where the exposure port 109b is formed opens left and right and forward. The first upper frame portion 110a of the first holding frame portion 110 is formed with a concave first concave portion 110d that opens upward and downward and forward, and a second concave portion 125d described later provided in the support cover 120; Alignment with the first recess 110d defines an open portion 101a that exposes the upper connector connecting portion 79a of the rotary connecting unit 70 upward of the mounting portion 101 (see FIG. 4 and FIG. 4). (See FIG. 5). The opening portion 101 a is formed so as to face an upper connection opening 78, which will be described later, of the rotary connection unit 70, and the upper connection opening 78 is exposed upward from the mounting portion 101. The edge of the first recess 110d is provided so as to protrude upward, and protects the connector of the wiring connected to the upper connector connection 79a of the rotary connection unit 70.

  Further, as shown in FIGS. 4 and 6, the support member 120 is provided on the front wall 104 of the intermediate member 103 at a position adjacent to the outside of the first side frame portions 110 c on both the left and right sides of the first holding frame portion 110. The fixed receiving part 112 which fixes the fixed protrusion 122 mentioned later is formed. The fixed receiving portion 112 is formed in a cylindrical shape that opens forward, and is provided so that the fixed protrusion 122 of the support cover 120 can be fitted from the front side. The fixed protruding portion 122 is fitted into the fixed receiving portion 112. By combining, the support cover 120 is prevented from being detached from the intermediate member 103. Here, the left first side frame portion 110c is provided with two fixed receiving portions 112 spaced apart from each other in the vertical direction. The fixed protrusion 122 is formed in a semi-cylindrical shape by connecting both ends of the U-shaped wall to the first side frame part 110c, and the fixed protrusion 122 is fitted along the first side frame part 110c. The movement of the fitted fixed protrusion 122 in the vertical and horizontal directions can be restricted. Similarly, the right first side frame portion 110c is also spaced apart in the vertical direction so that the two fixed receiving portions 112 are connected to the first side frame portion 110c at both ends of the U-shaped wall to form a semi-cylindrical shape. The fixed protrusion 122 can be fitted along the first side frame part 110c, and movement of the fitted fixed protrusion 122 in the vertical and horizontal directions is restricted. Between the upper and lower fixed receiving portions 112 provided integrally on the outer side (right side) of the right first side frame portion 110c, a connector for wiring connected to the in-situ sensor 114 is covered from the front side for protection. A sensor protection wall 109a is formed, and the upper and lower fixed receiving portions 112 are connected by the sensor protection wall 109a.

(About support cover 120)
As shown in FIGS. 4 and 6, the support cover 120 includes a flat cover base portion 121 extending in the direction intersecting the rotation axis L. A holding frame portion 125, a positioning pin 123 (see FIGS. 5 and 6), a fixed protrusion 122, and a support portion 124 are provided. The support cover 120 is formed with a communication port 121a so as to penetrate the cover base 121 in the front-rear direction, and has a rectangular frame shape. The support cover 120 is provided with a fixed projection 122 fixed to the fixed receiving portion 112 of the intermediate member 103 with a screw so as to face the fixed receiving portion 112, and rotationally connected to the intermediate member 103. A second holding frame portion 125 that holds the unit 70 is provided to face the first holding frame portion 110 of the intermediate member 103. The support cover 120 is provided between the rotary movable body 130 and the rotary connection unit 70, and a light emitting substrate 141 provided in the rotary movable body 130 and a rotary board 87 (see FIG. 8) of the rotary connection unit 70 described later. Is connected to the communication port 121a. Further, on the front surface of the cover base 121 in the support cover 120, a support portion 124 (described later) that receives a force acting in the crossing direction of the rotation axis L from the rotary movable body 130 is provided.

  As shown in FIGS. 5 and 6, the second holding frame portion 125 is formed in a rectangular frame shape that protrudes rearward from the rear surface of the cover base 121 of the support cover 120. The second holding frame portion 125 is aligned in the front-rear direction with the first holding frame portion 110 provided on the intermediate member 103, and the first holding frame portion 125, the cover base 121, and the first holding portion in the intermediate member 103. A unit housing portion 126 is defined inside the frame portion 110 and the front wall 104, and the rotary connection unit 70 is held in the unit housing portion 126. The second holding frame portion 125 includes a second upper frame portion 125a that constitutes the upper side, a second lower frame portion 125b that constitutes the lower side, and a second side frame portion 125c that constitutes the left and right sides. Yes. The inner side surface of the second holding frame part 125 is aligned with the upper and lower and left and right outlines of the rotary connection unit 70.

  Further, as shown in FIGS. 5 and 6, the first side frame portions 110 c on both the left and right sides of the second holding frame portion 125 are provided with cylindrical fixed protrusions 122 protruding rearward. The fixed protrusions 122 are provided so as to face the fixed receiving portions 112 of the intermediate member 103 in the front-rear direction. The fixed protrusions 122 are inserted into the fixed receiving portions 112 of the intermediate member 103 from the front side, and the rear side The intermediate member 103 and the support cover 120 are assembled by screwing the screw inserted through the fixed receiving portion 112 into the fixed protrusion 122. In addition, in a state where the support cover 120 is assembled to the drive mounting members 102 and 103, between the rear surface of the cover base 121 of the support cover 120 facing the rotary connection unit 70 and the front surface of the front wall 104 of the intermediate member 103. The front-rear dimension is configured to be slightly larger than the front-rear dimension of a case body 72 (see FIG. 7) described later in the rotary connection unit 70. The unit housing portion 126 includes the drive mounting members 102 and 103 in a state where movement of the rotary connection unit 70 between the front wall 104 of the intermediate member 103 and the cover base 121 of the support cover 120 is restricted. It is assembled on the front side. Furthermore, a plurality of (four in the embodiment) positioning pins 123 (see FIG. 5) projecting rearward from the inner four corners of the second holding frame 125 are formed on the rear surface of the cover base 121 of the support cover 120. . The positioning pins 123 are inserted into four positioning holes 73 formed in a case body 72 (to be described later) in the rotary connection unit 70 and function to position the rotary connection unit 70 inside the unit housing portion 126. .

  Thus, the rotary connection unit 70 is configured to hold the rotary connection unit 70 inside the intermediate member 103 and the support cover 120 without using fixing means such as screws. Note that the rotary connection unit 70 has upper, lower, left and right frame portions 110a, 110b, 110c, 110c of the first holding frame portion 110 and upper, lower, left and right frame portions 125a, 125b, 125c, 125c of the second holding frame portion 125. It is supported by positioning of the positioning pin 123 and the positioning hole 73 at a position spaced inward. That is, the support cover 120 is fixed to the fixed receiving portion 112 provided on the intermediate member 103 with the fixed protrusion 122 and fixed by screws, and the unit housing portion defined between the intermediate cover 103 and the support cover 120. The rotary connection unit 70 accommodated in 126 is configured to be positioned by positioning pins 123 inserted into the positioning holes 73 of the rotary connection unit 70. The rotational connection unit 70 positioned by the positioning pin 123 in the unit accommodating portion 126 is provided to be spaced downward with respect to the first upper frame portion 110a, and the support cover 120 is upward with respect to the intermediate member 103. When displaced, it is configured to follow the support cover 120 and move toward the first upper frame portion 110a. Further, the rotary connection unit 70 is provided so as to be spaced apart upward from the first lower frame portion 110b, and follows the support cover 120 when the support cover 120 is displaced downward relative to the intermediate member 103. 1 It is comprised so that it can move toward the lower frame part 110b. Further, the rotary connection unit 70 is provided inwardly with respect to the left and right first side frame portions 110c, and when the support cover 120 is displaced in the left-right direction relative to the intermediate member 103, the support cover is provided. It is configured to follow 120 and move toward one of the first side frame portions 110c.

  The second upper frame portion 125a of the second holding frame portion 125 is formed with a concave second concave portion 125d that opens upward and downward and forward, and a first concave portion 110d provided in the intermediate member 103; Alignment with the second recess 125d defines an open portion 101a that exposes the upper connector connecting portion 79a of the rotary connecting unit 70 upward of the mounting portion 101 (see FIG. 4 and FIG. 4). (See FIG. 5). The opening portion 101 a is formed so as to face an upper connection opening 78, which will be described later, of the rotary connection unit 70, and the upper connection opening 78 is exposed upward from the mounting portion 101. The edge of the second recess 125d is provided so as to protrude upward, and protects the connector of the wiring connected to the upper connector connection portion 79a (see FIG. 8) of the rotary connection unit 70.

(About support part 124)
As shown in FIGS. 4, 6, and 7, the front surface of the cover base 121 of the support cover 120 extends along the opening edge of the communication port 121 a and forwards (the movable body base of the rotary movable body 130). A support portion 124 is provided to protrude toward the (132 side). The support portion 124 extends along the front surface of the cover base 121, is formed in an annular shape around the rotation axis L, and is radially separated from the rotation shaft 131 of the rotatable movable body 130. Here, in the movable effect device 100 of the embodiment, the rear end side of the rotary shaft 131 whose front end portion is fixed to the movable body base 132 of the rotary movable body 130 is the mounting portion 101 (specifically, the drive mounting members 102 and 103). ), And the movable body base 132 is spaced forward from the bearing member 107 (insertion hole portion 106). The body 130 is configured to easily rattle in the direction intersecting the rotation axis L by centrifugal force. On the other hand, the support part 124 is configured to overlap a part of the rotary movable body 130 (specifically, an annular wall part 135 to be described later) in the intersecting direction of the rotation axis L. L is configured to receive a force acting in the crossing direction of L (a force that causes the movable movable body 130 to be displaced in a direction in which the rotation axis L is tilted with a centrifugal force).

  As described above, the movable effect device 100 is provided with the support portion 124 on the support cover 120 provided as a separate member from the rotation connection unit 70, and the force acting in the direction intersecting the rotation axis L with the rotation of the rotary movable body 130. The rotation movable body 130 fixed to the tip end portion of the rotation shaft 131 is prevented from rattling in the crossing direction of the rotation axis L with the rotation, and the rotation movable body 130 rotates with the rotation. The burden on the rotary connection unit 70 due to the force acting in the direction intersecting the axis L is reduced. In addition, the movable effect device 100 supports the rotation shaft 131 by the front and rear (the support portion 124 and the bearing member 107) sandwiching the rotation connection unit 70, so that the rotation axis L is intersected with the rotation of the rotation movable body 130. Is suppressed from acting on the rotary connection unit 70. The rotary movable body 130 of the embodiment is provided with an annular wall portion 135 that protrudes rearward on the rear surface of the movable body base 132 that faces the front surface of the cover base 121 of the support cover 120. The annular wall portion 135 and the annular support portion 124 are provided so as to overlap in the direction in which the rotation axis L intersects. The support cover 120 is configured so that the support portion 124 receives a force that acts in the crossing direction of the rotation axis L from the annular wall portion 135. Note that, in the relationship between the annular wall 135 and the support portion 124 of the support cover 120, the diameter of the inner peripheral surface of the support 124 is slightly larger than the diameter of the outer peripheral surface of the annular wall 135. An annular insertion member 150 made of a highly slidable material (for example, POM) is inserted between the support portion 124 and the annular wall portion 135.

(About rotary connection unit 70)
As shown in FIG. 8, the rotary connection unit 70 is electrically connected to a case body 72 having a base substrate 79 electrically connected to the effect control device and a light emitting substrate 141 of the rotary movable body 130. And a rotating member 82 having a rotating substrate 87 connected to. In the rotation connecting unit 70, a rotating member 82 is rotatably supported by a case body 72. The rotary connection unit 70 is configured such that the conductive piece 80 of the base substrate 79 and the conductive surface portion 90 of the rotary substrate 87 are in contact with each other to relay the electrical connection between the effect control device and the light emitting substrate 141. ing.

  As shown in FIG. 8, the case body 72 has a rectangular plate-like rear case 72a on which a base substrate 79 is placed on the front surface, and a box shape that opens to the rear, and the rear end opening is an outer edge of the rear case 72a. A front case 72b provided to match the shape, and a locking claw (not shown) provided on one of the rear case 72a and the front case 72b is locked in a locking hole provided on the other member. The unit internal space 72c, which is fixed to each other and can accommodate the base substrate 79 and the rotating member 82, is defined inside. An upper connection opening 78 opening upward is formed on the upper surface of the case body 72 formed by the rear case 72a and the front case 72b, and the upper connector connection portion 79a provided in the base substrate 79 is formed by the upper connection opening 78. The connection port is exposed above the case body 72. The upper connection opening 78 is provided at a position corresponding to the opening 101a (the first recess 110d and the second recess 125d) formed in the mounting portion 101. That is, the connector of the wiring (not shown) that is electrically connected to the effect control device is inserted into the mounting portion 101 via the opening 101a (the first concave portion 110d and the second concave portion 125d) of the mounting portion 101. Then, it is inserted into the case body 72 of the rotary connection unit 70 through the upper connection opening 78 and connected to the upper connector connection portion 79 a of the base substrate 79. Further, positioning holes 73 (see FIGS. 4 and 5) corresponding to positioning pins 123 provided in the support cover 120 are formed at the four corners of the case body 72 so as to penetrate the front case 72b and the rear case 72a in the front-rear direction. Has been. The rotary connection unit 70 is positioned with respect to the support cover 120 by inserting a positioning pin 123 of the support cover 120 into the positioning hole 73 provided in the case body 72 from the front side. That is, the rotary connection unit 70 (case body 72) can move within the unit housing portion 126 following the support cover 120 when the rotary movable body 130 rotates, and the direction of rotation of the rotation axis L The relative position of the rotary connection unit 70 and the rotary movable body 130 is prevented from shifting.

  As shown in FIG. 8, the rear case 72a has a shaft insertion hole 74 through which the rotary shaft 131 is inserted, and a cylindrical rear side regulation portion 75 that opens forward and the shaft insertion hole 74 opens at the bottom. Is provided. The shaft insertion hole 74 is provided corresponding to the insertion position of the rotary shaft 131 and is formed in a circular shape having a diameter slightly larger than the outer diameter of the rotary shaft 131 so as not to interfere with the rotary shaft 131. The rear restricting portion 75 has an inner peripheral shape that matches the outer peripheral shape of a protruding end portion of a shaft engaging cylinder 85 (described later) of the rotating member 82, and the outer peripheral shape of the rear restricting portion 75 is the base substrate. 79 has a shape matching the inner peripheral shape of the substrate through-hole 79 b provided corresponding to the insertion position of the rotary shaft 131. Then, the base substrate 79 is bonded to the front surface of the rear case 72a in a state where the substrate through hole 79b is fitted to the rear side restricting portion 75 and aligned, so that the base substrate 79, the rotating substrate 87, The relative position is prevented from shifting. In addition, the rear case 72 a has the shaft engaging tube 85 of the rotating member 82 fitted inside the rear side restricting portion 75 and comes into contact with the bottom surface, so that the rotating member 82 is further rearward with respect to the case body 72. In addition to restricting the movement, displacement of the rotating member 82 in the intersecting direction of the rotation axis L is also regulated.

  As shown in FIG. 8, the front case 72b is formed in a rectangular frame shape with a case communication port 76a formed so as to penetrate the case front wall 76 facing the rear case 72a in the front-rear direction. On the front surface of the case front wall 76 in the front case 72b, a front side restricting portion 77 that extends along the opening edge of the case communication port 76a and projects forward (to the movable body base 132 side of the rotatable movable body 130). Is provided. The inner circumferential surface of the front side restricting portion 77 is formed to have substantially the same shape as the outer circumferential surface of a shaft cylinder portion 83 (described later) of the rotating member 82 (actually slightly larger in diameter than the outer circumferential surface of the shaft cylinder portion 83). In addition, the outer peripheral surface of the shaft tube portion 83 is formed so as to be in sliding contact with the inner peripheral surface of the front side restricting portion 77 as the rotating member 82 rotates. In addition, the diameter of the inner peripheral surface of the front regulating portion 77 is smaller than the diameter of the outer peripheral surface of a plate-like portion 86 described later of the rotating member 82, and the front surface of the plate-like portion 86 is on the rear surface of the front case 72b. The rotating member 82 comes into contact with the case body 72 so as not to come out forward. The projecting dimension of the front restricting portion 77 is substantially the same as the longitudinal dimension of the shaft cylinder portion 83 of the rotating member 82, and the front surface of the plate-like portion 86 of the rotating member 82 is brought into contact with the rear surface of the front case 72b. In this state, the front end position of the front regulating portion 77 and the front end position of the shaft tube portion 83 of the rotating member 82 are configured to be aligned.

  As shown in FIG. 8, the base substrate 79 is formed with a substrate through-hole 79 b having a diameter larger than that of the rotation shaft 131 at a position where the rotation shaft 131 is inserted so as to penetrate in the front and rear direction. The base substrate 79 is fixed in a state where the substrate through-hole 79b is fitted to the outer peripheral surface of the rear regulating portion 75 of the rear case 72a and is aligned with the front surface of the rear case 72a. In addition, a connector for wiring that is electrically connected to the effect control device is connected to the front surface of the upper end portion of the base substrate 79 that is separated from the substrate through hole 79b (out of the position where the rotating member 82 is disposed). A connector connecting portion 79a is provided. The upper connector connection portion 79a is provided on the front surface of the base substrate 79 so that the connection port faces upward, and the connection port includes the upper connection opening 78 and the opening portion 101a (the first recess 110d and the second recess 125d). It is comprised so that it may expose upwards of the attaching part 101 through.

  As shown in FIG. 8, on the outer edge side of the front surface of the base substrate 79 from the substrate through hole 79b, there are provided a plurality of conductive pieces 80 that are in sliding contact with a conductive surface portion 90 described later formed on the rear surface of the rotating substrate 87. Yes. The conductive piece 80 is configured by a metal leaf spring, and one end side is fixed to the front surface of the base substrate 79 and is connected to a circuit formed on the base substrate 79 (a circuit in which the upper connector connection portion 79a is provided). The other end side close to the substrate through-hole 79b is always provided forwardly away from the base substrate 79, and is provided on the base substrate 79 side so as to be elastically deformable. The conductive piece 80 contacts the conductive surface portion 90 of the rotating substrate 87 while being urged so as to be pressed. When the rotating substrate 87 rotates with the rotation of the rotating member 82, the conductive piece 80 comes into sliding contact with the conductive surface portion 90. Note that the end of the conductive piece 80 that is in contact with the conductive surface portion 90 is formed in a curved shape with a convex side near the conductive surface portion 90 and is in contact with the conductive surface portion 90 with a curved surface. Thereby, it is comprised so that the conduction | electrical_connection piece 80 may contact the conduction | electrical_connection surface part 90 stably.

  As shown in FIG. 8, the rotating member 82 includes a plate-like portion 86 with which the front surface of the rotating substrate 87 abuts, and a shaft tube portion 83 that fits into the case communication port 76 a of the case body 72. It is comprised so that it may hold | maintain inside in the state which exposed the back surface of back. The rotating member 82 is an annular base material holding member that sandwiches the outer peripheral edge portion of the rotating substrate 87 between the circular plate-like base material 82a covering the front surface of the rotating substrate 87 and the outer peripheral edge portion of the base material 82a. 82b. The base material holding member 82b is configured to support the outer peripheral edge portion of the rotating substrate 87 from the rear side and sandwich the outer peripheral edge portion of the rotating substrate 87 with the base material 82a. A front connector connecting portion 87a provided on the front surface of the rotating substrate 87 is housed inside the shaft tube portion 83 and is formed so as to penetrate the front plate 83a that forms the front surface of the shaft tube portion 83 in the front-rear direction. Further, it is exposed to the front of the rotary connection unit 70 through the front connection opening 84. On the rear surface of the rotating substrate 87, a plurality of circular strip-shaped conducting surface portions 90 that are concentric with the rotation axis L as the center are provided. The conductive surface portion 90 is provided at a position where a plurality of conductive pieces 80 provided on the base substrate 79 are in contact with each other, and when the rotary substrate 87 rotates, the conductive pieces urged away from the base substrate 79 forward. The end portion of 80 is relatively moved along the conductive surface portion 90 and is in sliding contact with the conductive surface portion 90, whereby the contact state between the conductive surface portion 90 and the conductive piece 80 is maintained.

  As shown in FIG. 8, the front plate 83 a of the shaft tube portion 83 is provided with a cylindrical shaft engagement tube 85 that protrudes rearward. In addition, a shaft engagement hole 85a through which the rotation shaft 131 is inserted is formed. Here, the outer peripheral surface of the rotating shaft 131 has a D-shape in a sectional view in which a part thereof is cut out in a planar shape over the entire extending direction of the rotating axis L, and the shaft engaging hole 85a is formed in the rotating shaft 131. The cross-sectional view is a D-shape that matches the outer peripheral shape. As a result, the rotating member 82 rotates about the rotation axis L together with the rotation shaft 131. Since the shaft engaging cylinder 85 protrudes rearward and has a large contact area with the outer peripheral surface of the rotating shaft 131, the rotating substrate 87 is prevented from being displaced from the base substrate 79 as the rotating member 82 rotates. Thus, the contact state between the conductive piece 80 and the conductive surface portion 90 can be maintained. The outer peripheral surface of the shaft engaging cylinder 85 is fitted into a substrate through hole 87b formed in the rotating substrate 87, and the rotating member 82 rattles against the case body 72 when the rotating member 82 rotates. It works to prevent. Further, the shaft engaging cylinder 85 is fitted inside the rear side restricting portion 75 provided on the front surface of the rear case 72a constituting the case body 72, and the outer periphery of the shaft engaging cylinder 85 when the rotating member 82 rotates. The surface is configured to be in sliding contact with the inner peripheral surface of the rear side regulating portion 75. In addition, the shaft cylinder portion 83 has a shape in which the outer peripheral surface is aligned with the inner peripheral surface of the front side regulating portion 77 provided in the front case 72b constituting the case body 72, and when the rotating member 82 rotates. The outer peripheral surface of the shaft tube portion 83 is configured to be in sliding contact with the inner peripheral surface of the front side restricting portion 77. That is, the rotating member 82 is in sliding contact with the front regulating portion 77 and the rear regulating portion 75 located at the front end portion and the rear end portion of the case body 72 in a state where the rotation shaft 131 is inserted through the shaft engaging cylinder 85. It is configured to rotate. As a result, the rotating member 82 is restricted from rattling with respect to the rotating shaft 131 and can rotate stably.

  As shown in FIG. 8, the front connection opening 84 is formed at a position avoiding the shaft engaging tube 85 in the front plate 83 a of the shaft tube portion 83, and the communication port formed in the support cover 120. It faces 121a from the rear. That is, the connector of the wiring electrically connected to the movable-side connector connecting portion 141b (described later) provided on the light-emitting substrate 141 of the rotary movable body 130 is inserted into the mounting portion 101 through the communication port 121a. Then, it is inserted into the rotary member 82 of the rotary connection unit 70 through the front connection opening 84 and connected to the front connector connecting portion 87 a of the rotary board 87. The wiring that connects the front connector connecting portion 87a and the movable connector connecting portion 141b (described later) follows the rotating movable body 130 and the rotating member 82 that rotate simultaneously with the rotation of the rotating shaft 131, and the communication port 121a. It moves between the opening edge and the rotating shaft 131. Here, the movable body base 132 of the rotary movable body 130 is provided with an annular annular wall portion 135 (described later) located inside the communication port 121a, and the front connector connecting portion 87a and the movable side connector. The wiring that connects the connecting portion 141b (described later) is inserted inside the annular wall portion 135, so that the wiring does not come into contact with the communication port 121a. The diameter of the communication port 121a formed in the support cover 120 is larger than the diameter of the front plate 83a in the shaft tube portion 83, and the entire front surface of the front plate 83a is located behind the communication port 121a. It is like that.

(About rotating movable body 130)
As shown in FIGS. 3 and 9, the rotary movable body 130 has a movable base 132 having a fixed front end of a rotary shaft 131 (see FIG. 5) that rotates in conjunction with the drive mechanisms 115, 116, and 117. And a decorative cover 137 attached to the movable body base 132, and a light emitting unit 140 that is disposed inside the decorative cover 137 and the movable body base 132 and performs a light emission effect. The rotatable movable body 130 rotates in one direction around the rotation axis L along the rotation axis 131 or rotates in the forward and reverse directions at a rotation angle of less than one rotation according to a control signal from the effect control device. Oscillating motion (forward / reverse rotation motion) is performed. In addition, the movable base 132 is driven and attached to the movable base 132 in the extending direction of the rotation axis L passing through the center of the rotary shaft 131 with the rotary connection unit 70 positioned between the drive mounting members 102 and 103. The members 102 and 103 are separated from each other with the rotary connection unit 70 interposed therebetween. The light-emitting unit 140 includes a light-emitting substrate 141 having a light-emitting body 142 (LED) that irradiates light forward, and light radiated forward from the light-emitting body 142 of the light-emitting substrate 141 to the opening 138a of the decorative cover 137. , 138b, 138c.

(About movable body base 132)
As shown in FIG. 9, the movable body base 132 is a plate-like member formed in a shape based on a horizontally long rectangular shape at the rotation original position (the posture shown in FIG. 2) of the rotary movable body 130, and has an outer edge shape. Is substantially aligned with the outer edge shape of the light emitting substrate 141 and is formed so as to close the rear opening of the decorative cover 137. As shown in FIGS. 5, 6, and 7, the movable body base 132 is provided with a shaft fixing portion 133 that fixes the front end portion of the rotating shaft 131. The shaft fixing portion 133 is provided in a cylindrical shape protruding rearward along the extending direction of the rotation axis, and is formed so that a shaft fitting hole 133a into which the front end portion of the rotation shaft 131 is inserted opens rearward. . The shaft fitting hole 133a of the shaft fixing portion 133 is formed in a D-shape in sectional view that matches the shape of the outer peripheral surface of the rotating shaft 131. Thereby, the movable body base 132 rotates integrally with the rotating shaft 131.

  As shown in FIG. 5 and FIG. 7, the movable body base 132 is formed with a movable side connection opening 132 a that opens in the front-rear direction at a position adjacent to the shaft fixing portion 133. The movable-side connector connecting portion 141b provided on the light emitting substrate 141 is exposed to the rear of the rotatable movable body 130 through 132a. Note that the movable-side connector connecting portion 141b is provided on the rear surface of the light-emitting substrate 141 with the connection port facing backward, and the connection port of the movable-side connector connecting portion 141b faces the movable-side connection opening 132a from the front side. It has become.

(About the annular wall 135)
As shown in FIGS. 5, 6, and 7, the rear surface of the movable body base 132 has an annular wall portion 135 that protrudes rearward from the position where the shaft fixing portion 133 and the movable side connection opening 132 a are formed. It is provided so as to form an annular shape around the rotation axis L. That is, the wiring connected to the light emitting substrate 141 of the rotatable movable body 130 and drawn out to the rear side of the rotatable movable body 130 through the movable side connection opening 132 a passes through the inside of the annular wall portion 135 of the movable body base 132. Thus, the rotary connection unit 70 is connected to the rotary substrate 87. Here, the annular wall portion 135 is configured to be inserted from the front side into the opening of the support portion 124 provided in the support cover 120, and the annular wall portion 135 and the support portion 124 are arranged in a direction intersecting the rotation axis L. It is supposed to overlap. The annular wall portion 135 protrudes rearward (rotational connection unit 70 side) from the rear surface of the movable body base 132 toward the front surface of the rotary connection unit 70, and the front surface of the front plate 83 a of the axial tube portion 83. It is provided so as to protrude rearward from the position. Thereby, the malfunction that wiring is exposed outside is prevented. An annular insertion member 150 is inserted between the annular wall portion 135 and the support portion 124, and the rotary movable body 130 is provided on the support cover 120 via the insertion member 150. It is supported by the part 124.

(About the protrusion 136)
As shown in FIGS. 6 and 7, the rear surface of the rotary movable body 130 is provided with a protrusion 136 that protrudes rearward, with the rotational axis of the rotary movable body as the center. The protrusion 136 is provided on the outer peripheral side with respect to the annular wall 135 so as to be continuous in an annular shape centering on the rotation axis of the rotary movable body. The protrusion 136 is provided so as to have substantially the same diameter as the diameter of the support portion 124 provided on the support cover 120, and the protrusion end portion of the protrusion 136 and the protrusion end portion of the support portion 124. An annular insertion member 150 is interposed between the two. And it is comprised so that the protrusion end part of the protrusion 136 and the protrusion end part of the support part 124 may oppose on both sides of the 2nd interposition part 152 provided in the insertion member 150. FIG.

(About connecting wall 134)
As shown in FIGS. 6 and 7, a connecting wall portion 134 for reinforcing the annular wall portion 135 and the shaft fixing portion 133 is provided on the rear surface of the movable body base 132. The connecting wall portion 134 is provided so as to protrude rearward inside the annular wall portion 135, and one end side is connected to the annular wall portion 135 and the other end side is connected to the shaft fixing portion 133. A plurality of (three in the embodiment) connecting wall portions 134 are provided so as to extend radially around the shaft fixing portion 133. Accordingly, the connecting wall 134 acts to increase the strength of the proximal end portion of the annular wall portion 135 to which a force pressing the support portion 124 in the direction intersecting the rotation axis L is applied, and the rotational force is directly applied from the rotation shaft 131. The connecting wall portion 134 acts to increase the strength of the base end portion of the shaft fixing portion 133 that is transmitted. As described above, the annular wall portion 135 and the shaft fixing portion 133 can be reinforced at the same time by the connecting wall portion 134, thereby preventing the shape of the movable body base 132 from becoming complicated. As shown in FIGS. 6 and 7, the connecting wall portion 134 has one end portion connected to the annular wall portion 135 and the protruding dimension of the other end portion connected to the shaft fixing portion 133. And a shaft fixing portion connected to the base end portion of the annular wall portion 135 connected to one end portion of the connecting wall portion 134 and the other end portion of the connecting wall portion 134. The strength of the base end portion of 133 is further increased.

(Relationship between the insertion member 150, the annular wall portion 135, and the support portion 124)
The insertion member 150 is made of a synthetic resin such as polyacetal (POM) having a high self-lubricating property. As shown in FIGS. 4, 6, and 7, the insertion member 150 includes a cylindrical first interposed portion 151 that is inserted into the support portion 124 and opens forward and backward, and a front end of the first interposed portion 151. And an annular plate-like second interposition part 152 extending in the crossing direction of the rotation axis L from the part. The first interposition part 151 is provided in a longitudinal dimension in which the second interposition part 152 is not in contact with the rotary connection unit 70 in a state where the second interposition part 152 is in contact with the protruding end of the support part 124.

  The first interposed portion 151 is formed so that the diameter of the outer peripheral surface is substantially equal to the diameter of the inner peripheral surface of the support portion 124, and the diameter of the inner peripheral surface is the same as that of the outer peripheral surface of the annular wall 135. It is formed so as to be substantially equal to the diameter dimension. Accordingly, the rotary movable body 130 is configured to be supported by the support portion 124 via the first interposed portion 151 of the insertion member 150. When the rotary movable body 130 swings in the crossing direction of the rotation axis L due to centrifugal force as the rotary movable body 130 rotates, the force acting in the crossing direction of the rotation axis from the annular wall portion 135 of the rotary movable body 130 is generated. The inner peripheral surface of the support portion 124 that acts in the radial direction of the insertion member 150 and that is in the radial direction with respect to the first intermediate portion 151 of the insertion member 150 is in sliding contact with the outer peripheral surface of the first intermediate portion 151. It has come to be transmitted to. That is, by providing the movable body base 132 with the annular wall portion 135 that overlaps the support portion 124 of the support cover 120 in the intersecting direction of the rotation axis L, the intersecting direction of the rotation axis from the annular wall portion 135 of the rotatable movable body 130 is provided. Is applied to the inner peripheral surface of the support portion 124 provided on the support cover 120. In addition, since the annular wall portion 135 that defines the wiring path in the rotary movable body 130 is also used as a support target by the support portion 124, the complicated shape of the rotary movable body 130 is prevented. In the movable effect device 100, the support 124 is provided separately from the rotary connection unit 70, so that the force acting on the rotary connection unit 70 from the force that acts from the rotary movable body 130 in the crossing direction of the rotation axis line. It is configured not to be. Further, when the rotary movable body 130 rotates, the annular wall portion 135 is in sliding contact with the inner peripheral surface of the first interposed portion 151, and the outer peripheral surface of the first interposed portion 151 is in sliding contact with the inner peripheral surface of the support portion 124. As a result, the frictional resistance that can occur between the support portion 124 and the annular wall portion 135 as the rotary movable body 130 rotates is reduced.

  As shown in FIGS. 6 and 7, the second interposed portion 152 has a diameter dimension of the inner peripheral surface smaller than that of the inner peripheral surface of the support portion 124 and the protrusion 136, and a diameter size of the outer peripheral surface of the support portion. 124 and the protrusion 136 are formed so as to be larger in diameter than the outer peripheral surface. Moreover, the 2nd interposition part 152 is comprised so that it may contact | abut with the protrusion end part of the support part 124, and may cover the said protrusion end part from the front side. As a result, a force acting on the mounting portion 101 side from the protrusion 136 of the rotary movable body 130 is transmitted to the protruding end portion of the support portion 124 via the insertion member 150. That is, the movable movable body 130 rotates with the rotation by providing the movable body base 132 with the protruding portion 136 so that the protruding end portion of the support cover 120 faces the protruding end portion of the support portion 124 from the front. The force acting on the mounting portion 101 side from the annular wall portion 135 of the rotary movable body 130 when swung in the direction intersecting the axis L can be received by the protruding end portion of the support portion 124 provided on the support cover 120. The support portion 124 is provided separately from the rotary connection unit 70 so that the force acting on the mounting portion 101 side from the rotary movable body 130 does not become a load on the rotary connection unit 70. . In addition, when the rotary movable body 130 rotates in the crossing direction of the rotation axis L due to centrifugal force when the rotary movable body 130 rotates, the protruding end portion of the protrusion 136 is in sliding contact with the front surface of the second interposition portion 152, and The rear surface of the second interposition part 152 is in sliding contact with the protruding end part of the support part 124, and the frictional resistance that can be generated between the support part 124 and the protrusion 136 with the rotation of the rotary movable body 130 is reduced.

(About the decorative cover 137 and the light emitting unit 140)
The decorative cover 137 is made of a synthetic resin having light shielding properties, and constitutes the front surface of the rotary movable body 130 as shown in FIG. The decorative cover 137 is provided in a box shape opened rearward by a front wall portion 138 and a peripheral wall portion 139 extending rearward from the outer edge of the front wall portion 138, and is fixed to the movable body base 132 by fixing means such as screws. Has been. Openings 138 a, 138 b, and 138 c that emit light output from the light emitting unit 140 toward the front of the rotatable movable body 130 are formed in the front wall portion 138 of the decorative cover 137. In addition, a concave notch 139a that is opened rearward is formed in the peripheral wall portion 139 of the decorative cover 137. The decorative cover 137 is provided with openings 138a, 138b, and 138c as a first opening 138a that is positioned in the extending direction of the rotation axis L, and an upper right position and an upper left position with respect to the first opening section 138a. The formed second opening 138b and the third opening 138c provided so as to extend to the left and right below the first opening 138a and the second opening 138b are formed. Incidentally, the rotary movable body 130 of the embodiment expresses the face of the robot, the first opening 138a corresponds to the nose of the robot, the pair of second openings 138b corresponds to the eyes of the robot, The three openings 138c correspond to the mouth of the robot.

  As shown in FIG. 9, the light emitting unit 140 is positioned between the front wall portion 138 of the decorative cover 137 and the movable body base 132 so as to be vertically and horizontally surrounded by the peripheral wall portion 139 of the decorative cover 137. It is housed inside the movable body 130. The light emitting unit 140 includes a light emitting substrate (electrical component) 141 having a light emitting body (LED) 142 capable of outputting light forward and a front surface of the light emitting substrate 141. 141, a light regulating member 145 that partitions each light irradiation range of the plurality of light emitters 142, a color film 146 made of a colored transparent synthetic resin material that covers the light regulating member 145 from the front side, a color film 146, and a light regulating member A first lens member 147 made of a light-transmitting material provided so as to cover the opening 138a, 138b, 138c of the decorative cover 137, and the upper and left and right sides from the peripheral wall 139 of the decorative cover 137. And a second lens member 148 made of a light-transmitting material disposed so as to protrude from each other. In the light emitting unit 140, the rear surface of the light emitting substrate 141 provided on the rearmost side of the light emitting unit 140 faces the front surface of the movable body base 132, and the first lens member provided on the frontmost side of the light emitting unit 140. 147 is arranged so as to fit inside the decorative cover 137 from behind. A movable connector is connected to the rear surface of the light emitting substrate 141 facing the front surface of the movable body base 132 at a position corresponding to the movable-side connection opening 132a formed in the movable body base 132. A side connector connecting portion 141b is provided.

  As shown in FIG. 9, on the front surface of the light emitting substrate 141, a light emitting area corresponding to the openings 138a, 138b, and 138c of the decorative cover 137, which is a region where the light emitters 142 (groups of light emitters 142) are disposed. A plurality of 142a, 142b, and 142c are provided. Specifically, a first light emitting region 142 a having one light emitter 142 is provided at a position overlapping the first opening 138 a of the decorative cover 137 in the front-rear direction. In addition, a pair of left and right second light emitting regions 142b in which a plurality of light emitting bodies 142 are arranged in parallel vertically and horizontally on the front surface of the light emitting substrate 141 so as to overlap the second opening 138b of the decorative cover 137 in the front-rear direction. Is provided. Further, on the front surface of the light emitting substrate 141, there is a third light emitting region 142c in which a plurality of light emitting bodies 142 are arranged at equal intervals on the left and right at positions overlapping the third opening 138c of the decorative cover 137. Is provided. The light regulating member 145 has a mesh-like through-hole penetrating in the front-rear direction corresponding to each light-emitting body 142 disposed in the second light-emitting region 142b in a portion corresponding to the second light-emitting region 142b of the light-emitting substrate 141. The formed partition part 145a is formed. The partition part 145a limits the irradiation range of the light irradiated from each light emitter 142 of the second light emitting region 142b to the range of the hole, so that the second light emitting region 142b when viewed from the front of the rotatable movable body 130. The light from each of the light emitters 142 can be visually recognized without overlapping. Further, the color film 146 is disposed so as to cover the partition portion 145a corresponding to the second light emitting region 142b of the light emitting substrate 141 from the front side. The color film 146 is a sheet having the same color (black in the embodiment) as the light restricting member 145, and reduces the visibility of the light restricting member 145 when the rotary movable body 130 is viewed from the front, while the light emitting substrate 141. The light of the light emitter 142 is transmitted in front of the rotatable movable body 130. The first lens member 147 is provided with a plurality of protruding fitting lens portions 147a that are fitted into the respective openings 138a, 138b, and 138c provided in the decorative cover 137 from the rear side. The fitting lens portion 147a is configured to change the traveling direction of the light emitted from the openings 138a, 138b, and 138c.

  As shown in FIG. 9, the second lens member 148 is fitted into the notch 139a formed in the peripheral wall 139 of the decorative cover 137 from the rear side. The light emitting substrate 141 is provided with a substrate protruding portion 141a that protrudes outward from between the notch 139a and the front surface of the movable body base 132 on the rear side of the second lens member 148. A light emitter 142 is also arranged on the front surface of the substrate protrusion 141a. In other words, the front surface of the substrate protruding portion 141a is a fourth light emitting region 142d in which the light emitting body 142 that irradiates the second lens member 148 with light is disposed.

  The members 141, 142, 145, 146, 147, and 148 constituting the light emitting unit 140 are sandwiched between the movable body base 132 and the decorative cover 137 without using fixing means such as screws, and the rotary movable body 130. Are arranged. Specifically, the first lens member 147 is provided in a size that can be accommodated in a space defined by the inner surface of the decorative cover 137 and is fitted to the openings 138a, 138b, and 138c of the decorative cover 137. The joint lens part 147a is positioned on the decorative cover 137 by fitting from behind. The first lens member 147 is formed in a box shape opened rearward, and the color film 146 and the light regulating member 145 are accommodated in a space defined by the inner surface. A concave concave surface portion 147b opened rearward is formed at a position aligned with the notch portion 139a at the rear end portion of the first lens member 147, and the notch portion 139a of the decorative cover 137 and the concave surface of the first lens member 147 are formed. The second lens member 148 is disposed so that the front surface is in contact with the portion 147b. Further, the decorative cover 137 is formed with a positioning protrusion 139b protruding rearward at the center of the inner edge of the notch 139a, and the positioning protrusion 139b is formed in the positioning groove 148a formed on the front surface of the second lens member 148. Is inserted, the second lens member 148 is positioned with respect to the decorative cover 137. Further, the second lens member 148 is provided with an extraction restricting piece 148b that comes into contact with both ends of the notch 139a of the decorative cover 137 from the inside, and the notch 139a is formed by the extraction restricting piece 148b. The detachment of the second lens member 148 from the outside to the outside is restricted. Then, by fixing the movable body base 132 to the decorative cover 137 from the rear side with the light emitting unit 140 disposed inside the decorative cover 137, the light emitting unit 140 is fixed to the inside of the rotary movable body 130 without rattling. It has come to be. The second opening 138b of the decorative cover 137, the second light emitting region 142b of the light emitting substrate 141 corresponding to the second opening 138b, the partitioning portion 145a of the light regulating member 145 corresponding to the second light emitting region 142b, The color film 146 constitutes a display unit that can display a pattern (symbol) such as a character by a set of light emitting points by controlling turning on and off of the plurality of light emitters 142 with the rotary movable body 130 viewed from the front. doing.

(Operation of Example)
Next, the operation of the pachinko machine 10 according to the above-described embodiment will be described.

  The pachinko machine 10 of the embodiment is configured to include a movable effect device 100 having a rotary movable body 130 that can rotate. In the movable effect device 100, the rotary movable body 130 having the light emitting substrate 141 is provided so as to be rotatable with respect to the attachment portion 101, and the effect control device and the rotary movable body 130 located on the attachment portion 101 side (game board 20). The light emitting substrate 141 is configured to be electrically connected. In the pachinko machine 10, a rotation connection unit 70 for electrically connecting the effect control device and the light emitting substrate 141 of the rotary movable body 130 is disposed in the mounting portion 101. In the rotation connection unit 70, a rotating member 82 that rotates as the rotary movable body 130 rotates is accommodated in the case body 72, and the effect control device is electrically connected to the conductive piece 80 on the case body 72 side. The light emitting substrate 141 of the rotary movable body 130 is electrically connected to the conduction surface portion 90 on the rotating member 82 side, and the conduction piece 80 and the conduction surface portion 90 are in sliding contact and are electrically connected when the rotation member 82 rotates. Has been. In other words, the conductive piece 80 and the conductive surface portion 90 of the rotary connection unit 70 are in sliding contact with each other to maintain an electrical connection state, so that the light emitting substrate 141 and the effect control device are controlled regardless of the number of rotations of the rotary movable body 130 in one direction. The electrical connection state can be maintained.

  Here, in the movable effect device 100, the rear end portion (movable body base 132) of the rotary movable body 130 is fixed to the tip portion of the rotary shaft 131 extending in the front-rear direction, and the mounting portion 101 is attached to the rotary shaft 131. When the rotary movable body 130 is rotated, the front end side of the rotary shaft 131 is greatly swung in the crossing direction of the rotation axis L. . In addition, the rotary movable body 130 of the movable effect device 100 has a shape in which the dimension from the rotation axis L to the upper and lower edges and the dimension from the rotation axis L to the left and right edges are different from each other. The load of the rotary movable body 130 acting on the rotation changes in the crossing direction (left-right direction) of the rotation axis L when the rotary movable body 130 is rotated. For these reasons, as the rotary movable body 130 rotates, a force acts in the direction in which the rotation axis L intersects. When the force that acts in the crossing direction of the rotation axis L is supported by the rotation connecting unit 70, the rotation connecting unit 70 is deformed and the relative connection between the rotation connecting unit 70 conducting piece 80 and the conducting surface 90 is caused. It is conceivable that the conductive state of the conductive piece 80 and the conductive surface portion 90 cannot be maintained due to the change in position. On the other hand, in the movable effect device 100, the support portion 124 is provided in the attachment portion 101 so as to be separated from the rotation axis L of the rotary movable body 130 in the intersecting direction. The support 124 is configured to receive a force acting in the crossing direction of L. That is, the load on the rotary connection unit 70 is received by receiving a force acting from the rotary movable body 130 in the crossing direction of the rotation axis L of the rotary movable body 130 by the support portion 124 provided on the mounting portion 101 of the rotary movable body 130. Can be reduced. Accordingly, damage and deformation of the rotary connection unit 70 can be prevented and the relative positions of the conductive piece 80 and the conductive surface portion 90 can be kept constant. Therefore, even when the rotary member 82 rotates, the base substrate 79 and the rotary substrate 87 can be maintained. Can be maintained in a conductive state. That is, it is possible to reliably maintain the electrical connection state of the light emitting substrate 141 and the effect control device while freely rotating the rotatable movable body 130.

  In addition, the rotary connection unit 70 is accommodated in the unit accommodating portion 126 in a state of being spaced apart from the first holding frame portion 110 of the intermediate member 103 and the second holding frame portion 125 of the support cover 120, and the support portion 124 is provided. The support cover 120 is connected to the support cover 120 via positioning pins 123. As a result, when the support cover 120 receiving the force in the direction intersecting the rotation axis L from the rotary movable body 130 is displaced relative to the drive mounting members 102 and 103 (intermediate member 103), the support cover 120 Following this, the rotary connection unit 70 can be displaced in the unit accommodating portion 126. That is, since the relative position between the rotary connection unit 70 and the second holding frame portion 125 of the support cover 120 can be made constant, a force in the direction intersecting the rotation axis L is received from the rotary movable body 130. The support cover 120 can be prevented from acting so as to press the rotary connection unit 70, and deformation and breakage of the rotary connection unit 70 can be prevented. Further, when the rotary connection unit 70 is displaced in accordance with the displacement of the support cover 120, interference with the first holding frame portion 110 of the intermediate member 103 that defines the unit housing portion 126 is avoided, so that the rotational connection is achieved. The deformation and breakage of the unit 70 can be prevented. Accordingly, the relative positional relationship between the conductive piece 80 and the conductive surface portion 90 of the rotary connection unit 70 can be maintained, and the electrical connection state between the effect control device and the light emitting substrate 141 while the rotary movable body 130 is rotating. Can be prevented from being interrupted.

  In addition, the rotary connection unit 70 of the movable effect device 100 holds the base substrate 79 having the conduction piece 80 and the upper connector connection portion 79a to which the connector of the wiring connected to the effect control device side is connected to the case body 72. The rotating substrate 87 having the front surface connector connecting portion 87a connected to the conductive surface portion 90 and the wiring connector connected to the light emitting substrate 141 is held by the rotating member 82 so that the rotating member 82 can be rotated by the case body 72. Configured to hold. Here, the case body 72 of the rotary connection unit 70 is provided with a front-side restricting portion 77 projecting in an annular shape around the rotation axis L of the rotary movable body 130, and the outer periphery of the rotary member 82 of the rotary connection unit 70. The surface is configured to slide in contact with the inner peripheral surface of the front-side restricting portion 77, and the rotating member 82 rotates with the rotation of the rotatable movable body 130. That is, by configuring the outer peripheral surface of the rotating member 82 to be in sliding contact with the inner peripheral surface of the front side restricting portion 77 provided on the case body 72, the rotational position shift of the rotating member 82 is restricted, and the light emitting substrate 141 and the effect are produced. The electrical connection state of the control device can be reliably maintained.

  Further, the support portion 124 provided in the support cover 120 is provided in an annular shape around the rotation axis L of the rotary movable body 130, and the rotary movable body 130 extends in an annular shape around the rotational axis L. An annular wall 135 that overlaps the support 124 is provided in the direction intersecting the rotation axis L. An annular insertion member 150 is inserted between the annular wall portion 135 and the support portion 124, and a force acting in the direction intersecting the rotation axis L of the rotatable movable body 130 with the rotation of the rotatable movable body 130. Is supported by the support portion 124 via the insertion member 150. That is, by inserting the insertion member 150 between the support portion 124 and the annular wall portion 135, the frictional resistance that can be generated between the support portion 124 and the annular wall portion 135 as the rotary movable body 130 rotates is reduced. Therefore, the rotary movable body 130 can be smoothly rotated.

  In addition, the rotary movable body 130 is provided with a rotary shaft 131 that rotates by the driving force of the drive motor 115, and is configured to rotate by the rotation of the rotary shaft 131, and a shaft fixed for fixing the rotary shaft 131. A portion 133 is provided. The rotating movable body 130 is provided with a connecting wall portion 134 that connects the shaft fixing portion 133 and the annular wall portion 135 provided on the rotating movable body 130. That is, by configuring the shaft fixing portion and the annular wall portion provided in the rotary movable body to be connected by the connecting wall portion, the shaft fixing portion and the annular wall portion can be simultaneously reinforced by the connecting wall portion.

  The insertion member 150 includes a cylindrical first interposed portion 151 that opens in the extending direction (front-rear direction) of the rotation axis L of the rotatable movable body 130, and the rotation axis L from the front end portion of the first interposed portion 151. And a second interposed portion 152 extending in the crossing direction of the first intermediate portion 151. The first interposed portion 151 is interposed between the annular wall portion 135 and the support portion 124, and the protruding end portion of the support portion 124 and the rotary movable body. The second interposition part 152 is interposed between the second interposition part 152 and the intervening part 130. The rotating movable body 130 that faces the protruding end portion of the support portion 124 with the second interposed portion 152 interposed therebetween is provided with a protruding portion 136 that protrudes toward the second interposed portion 152, and the protruding portion 136. The projecting end portion is configured to abut against the second interposition portion 152. That is, the protrusion 136 provided on the rotary movable body 130 is configured to abut on the second interposition part 152 provided on the insertion member 150, so that the protrusion end portion of the support portion 124 and the rotary movable body 130 are arranged. Thus, the frictional resistance that can occur can be reduced, and the rotatable movable body 130 can be smoothly rotated. The second interposition part 152 is configured to be interposed between the projecting end part of the annular wall part 135 and the support cover 120, and the support is opposed to the projecting end part of the annular wall part 135 with the second interposition part 152 interposed therebetween. Even if the cover 120 is provided with a protrusion 136 that protrudes toward the second interposed portion 152 and the protruding end portion of the protrusion 136 is in contact with the second interposed portion 152, the same effect can be obtained. .

  Further, the protrusion 136 is provided so as to be aligned with the protruding end portion of the support portion 124 or the protruding end portion of the annular wall portion 135 in the extending direction of the rotation axis. Accordingly, the second interposed portion 152 can be stably supported between the protrusion 136 provided on the rotary movable body 130 and the protruding end portion of the support portion 124 provided on the support cover 120. In the configuration in which the second interposed portion 152 is interposed between the protruding end portion of the annular wall portion 135 and the support cover 120 and the protrusion 136 is provided on the support cover 120, the protrusion 136 is formed on the annular wall. A similar effect can be achieved by providing the protruding end portion of the portion 135 so as to be aligned in the extending direction of the rotation axis.

(Example of change)
The present invention is not limited to the above-described embodiments, and can be modified as follows.
(1) In the embodiment, the rotary movable body is configured to include the light emitting substrate as an electrical component. However, a drive source such as a drive motor or a drive solenoid, a sensor, or the like may be included as an electrical component.
(2) In the embodiment, the rotational axis of the rotary movable body is configured to extend forward and backward, but the present invention is not limited thereto, and the rotational axis may be configured to extend left and right or up and down.
(3) In the embodiment, the annular wall portion is positioned on the inner peripheral side of the support portion. However, the support portion is positioned on the inner peripheral side of the annular wall portion, and the rotation axis is rotated along with the rotation of the rotary movable body. You may comprise so that the force which acts on the crossing direction may be provided to the outer peripheral surface of a support part from the inner peripheral surface of the annular wall part of a rotary movable body.
(4) In the embodiment, the rotary movable body is configured to rotate a plurality of times in one direction. However, the rotary movable body may always be configured to rotate within a rotation range of less than one rotation.
(5) In the embodiment, the rod-shaped rotation shaft extending on the rotation axis is provided. However, an annular rotation shaft centered on the rotation axis may be employed. For example, one end side of the annular rotary shaft may be fixed to the rotary movable body, and the other end side of the rotary shaft may be rotationally driven by a drive mechanism.
(6) In the embodiment, the mounting portion of the movable effect device is configured by the drive mounting member (intermediate member and rear member) and the support cover, but the support cover is not provided, and the intermediate member and rear member of the drive mounting member are not provided. You may comprise so that a unit accommodating part may be provided inside and a rotation connection unit may be accommodated in this unit accommodating part, and a support part may be provided in the front surface of an intermediate member.
(7) In the embodiment, the annular insertion member is interposed between the annular wall portion provided on the rotary movable body and the support portion provided on the attachment portion (support cover). It is good also as a structure which an annular wall part contact | abuts directly to a support part without providing a member and receives the force which acts on the crossing direction of a rotating shaft line from an annular wall part directly.
(8) In an Example, with respect to the insertion member, the 1st interposition part interposed between an annular wall part and a support part, and the 2nd interposition part interposed between the protrusion end part and protrusion part of a support part The first intervening portion interposed between the annular wall portion and the supporting portion, and the first intervening portion interposed between the protruding end portion of the supporting portion (or the protruding end portion of the annular wall portion) and the protruding portion. Only one of the two interposition parts may be provided on the insertion member.
(9) In the embodiment, the support portion is provided in an annular shape centering on the rotation axis, but is not limited thereto. In other words, the support portion may be a plurality of protrusions arranged on the same circumference around the rotation axis, may be provided in an elliptical shape surrounding the rotation axis, or other than circular A plurality may be provided along the shape (for example, rectangular shape). Further, the support portion may be provided at a position that is separated from the rotation axis by one side.
(10) In the embodiment, the annular wall portion protrudes from the rotary movable body (movable body base) toward the rotary connection unit, and extends radially outward from the shaft cylindrical portion of the rotary member to Although it is configured to protrude rearward from the front / rear position of the front plate, the diameter of the annular wall portion is made smaller than the diameter size of the shaft tube portion so that the annular wall portion extends from the rotary movable body to the front plate of the shaft tube portion. You may comprise so that it may protrude toward the front. In this case, the wiring for electrically connecting the electrical component of the rotary movable body and the rotary substrate of the rotary connection unit is between the shaft cylinder portion of the rotary member in the rotary connection unit and the front side regulating portion of the case body. It can prevent being pinched.
(11) In the embodiment, the rotary connection unit is housed in the unit housing portion in a state of being spaced inward from the first holding frame portion of the intermediate member and the second holding frame portion of the support cover, and has a support portion. Although it is configured to be coupled to the cover via a positioning pin, the rotary connection unit may be coupled to the support cover by a fixing means such as a screw.
(12) In the embodiment, the rotary connection unit is housed in the unit housing portion in a state of being spaced inward from the first holding frame portion of the intermediate member and the second holding frame portion of the support cover, and has a support portion. Although it was configured to be coupled to the cover via a positioning pin, the rotary connection unit may be coupled to the intermediate member via a positioning pin provided on the intermediate member.
(13) In the embodiment, a display window and an effect window are provided separately on the frame-shaped decorative body, and the rotary movable body is positioned inside the effect window. However, the frame-shaped decorative body rotates inside the display window of the frame-shaped decorative body. You may comprise so that a movable body may be located and to rotate in the said display window, or to light-emit.
(14) In the embodiment, the movable effect device is arranged on the game board by fixing the attachment portion of the movable effect device to the base member provided in the installation space. You may arrange | position a movable production | presentation apparatus in a game board by arrange | positioning so that it may move with respect to a member.
(15) In the embodiment, the rotary connection unit relays the electrical connection between the electrical component provided in the rotatable rotating movable body and the control unit provided on the mounting portion side, but is not limited thereto. It is not a thing. For example, an electrical component provided in a movable body that reciprocates in a linear direction with respect to the attachment portion, a control portion provided on the attachment portion side, and a connection unit that relays electrical connection between the electrical component and the control portion are provided. The electrical component and the control unit are configured to be electrically conducted by sliding contact between the first conducting unit and the second conducting unit provided in the connection unit, and the reciprocating operation of the movable unit is performed in accordance with the reciprocating operation of the movable unit. It can also comprise so that the force which acts on the direction which cross | intersects a direction may be received in the support part provided in the attaching part.
(16) In the embodiment, a pachinko machine that is one type of gaming machine has been described as an example. However, the present invention may be applied to a slot machine that uses a gaming medal as a gaming medium.

70 Rotation Connection Unit 72 Case Body 77 Front Restriction Part (Regulation Part)
79 Base board 79a Upper connector connection (connector connection)
80 conduction piece (first conduction part)
82 Rotating member 83 Shaft cylinder part (regulated part)
84 Front connection opening (opening)
87 Rotating board 87a Front connector connection (connector connection)
90 conduction surface part (second conduction part)
DESCRIPTION OF SYMBOLS 101 Attachment part 124 Support part 130 Rotating movable body 131 Rotating shaft 133 Shaft fixing part 134 Connection wall part 135 Annular wall part 136 Protrusion part 141 Light emitting substrate 150 Interposing member 151 1st interposition part 152 2nd interposition part L Rotation axis

Claims (4)

A gaming machine in which a rotary movable body having an electrical component is provided so as to be rotatable with respect to a mounting portion, and is configured to electrically connect a control unit located on the mounting portion side and an electrical component of the rotary movable body. In
The attachment portion is provided with a rotation connecting unit in which a rotating member rotating in accordance with the rotation of the rotary movable body is accommodated in a case body, and the rotation connecting unit is a wiring connector connected to the control portion side. Connector connection part to which the connector of the wiring connected to the said electrical component is connected while holding the base substrate which has the 1st conduction | electrical_connection part to which the connector connection part and this control part which were electrically connected were connected the rotational substrate section and said electrical component has a second conductive portion that is electrically connected, is configured to hold the rotary member, the rotation first conductive portion and the second conductive portion is the rotation at the time of the rotating member It is configured to be electrically conductive by sliding in the extending direction of the axis ,
The supporting portion of the annular around the rotation axis of the rotatable member is provided in the mounting portion to be separated in the transverse direction from the axis of rotation Rutotomoni, it extends annularly around the axis of rotation the rotary An annular wall portion that overlaps the support portion in the direction intersecting the axis is provided on the rotary movable body, and the force acting in the direction intersecting the rotational axis from the annular wall portion as the rotary movable body rotates is supported by the support. Configured to receive in the department ,
The case body includes a restricting portion that protrudes in an annular shape around the rotation axis,
The rotating member has a regulated portion, and the outer peripheral surface of the regulated portion is configured to be in sliding contact with the inner circumferential surface of the regulating portion as the rotary movable body rotates. An opening exposing the connector connecting portion of the rotating board is formed on the surface facing the rotating movable body,
A gaming machine, wherein the annular wall portion is located on an outer peripheral side of the restricting portion, and the opposed surface of the restricted portion is located on an inner peripheral side of the annular wall portion . The rotary movable body is provided with a shaft fixing portion for fixing a rotating shaft that rotates by a driving force of a driving means, and a connecting wall portion that connects the shaft fixing portion and the annular wall portion. Item 1. The gaming machine according to Item 1 . An annular insertion member is inserted between the annular wall portion and the support portion, and the force acting in the crossing direction of the rotation axis along with the rotation of the rotary movable body is passed through the insertion member. Configured to support the support portion;
The insertion member includes a cylindrical first interposition part that opens in an extending direction of the rotation axis, and a second interposition part that extends in an intersecting direction of the rotation axis from an end of the first interposition part. The first interposition part is interposed between the annular wall part and the support part, and between the projecting end part of the support part and the rotary movable body, or the projecting end part of the annular wall part and the The second interposition part is configured to be interposed between the attachment part,
The rotating movable body facing the protruding end portion of the support portion across the second interposed portion or the attachment portion facing the protruding end portion of the annular wall portion across the second interposed portion includes the first 3. A gaming machine according to claim 1 or 2 , wherein a projecting portion projecting toward the intervening portion is provided, and a projecting end portion of the projecting portion is in contact with the second intervening portion. The gaming machine according to claim 3 , wherein the protrusion is provided so as to be aligned in a direction in which the rotation axis extends with respect to the protruding end of the support portion or the protruding end of the annular wall portion.

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