JP5643703B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine provided with a movable effect device that produces an effect by an operation.

  A pachinko machine, which is a typical gaming machine, has a frame-shaped decorative body (so-called center accessory) formed in a frame shape at a substantially central position of a gaming area defined on the surface of the gaming board. A design display device such as a liquid crystal type or a drum type that displays a plurality of symbols in a variably displayed manner through the opening of the frame-shaped decorative body is faced from behind, and below the frame-shaped decorative body in the game board Many proposals have been proposed in which a start winning device that starts fluctuations in the symbol display device by winning a pachinko ball (game ball) or a special winning device that opens at a big hit or the like is arranged at the position. In such a pachinko machine, the pachinko ball launched into the game area gradually flows down due to its own weight while bouncing off by contact with a game nail or the like implanted in the game area, and starts in the process of flowing down the game area. By winning the winning device, various game effects such as reach effects accompanying the symbol variation are made on the symbol display device, and when the symbols stop on the symbol display device in a predetermined combination, a so-called big hit occurs, and the game A special prize device provided on the board is configured to be opened to obtain a large number of prize balls.

  Further, as described in Patent Document 1, the pachinko machine described above is provided with a movable effect device provided with a movable member that performs a required operation on the decorative member, and the movable member is used as the symbol display device. There are also known pachinko machines that are operated in accordance with the game effects performed in, thereby improving the visual effect and enhancing the fun of the game. In the pachinko machine described in Patent Document 1, by arranging a light emitter made of an LED or the like with respect to the movable member, not only the operation effect by the movable member but also the light emitter according to the operation of the movable member. The light emission mode is changed.

JP 2007-54140 A

  However, as in the pachinko machine described in Patent Document 1, there are many known movable effect devices configured to perform an effect by swinging the movable member by attaching one movable member to one rotation shaft. Yes. However, there is a drawback that the effect of improving the decorativeness and the diversification of the production mode due to the operation of the movable member are limited only by causing the single movable member to perform a constant swinging operation. In addition, as in Patent Document 1, it is possible to improve the decorativeness, etc., if the movable members are individually attached to a plurality of rotating shafts and the plurality of movable members are swung. The installation space for the movable member is increased, and the installation space for other game parts is also pressed.

  That is, the present invention has been proposed in order to suitably solve this problem in view of the above-mentioned problems inherent in the movable effect device for a gaming machine according to the prior art, and improves the decoration / effect effect with a simple configuration. An object of the present invention is to provide a gaming machine including a movable effect device.

In order to solve the above-mentioned problem and achieve the intended purpose, the invention according to claim 1 of the present invention provides:
In a gaming machine equipped with a movable effect device (31) that performs an effect by movement,
The movable effect device (31)
An apparatus body (33) in which the first drive means (45) is disposed;
A first body disposed in the apparatus main body (33) and connected to the first driving means (45) and supported by the apparatus main body (33) so as to be rotatable about the first rotation shaft (110). 1 movable body (60),
The first movable body (60) is connected to the second driving means (81) provided on the first movable body (60) and connected to the first movable body (60). a second movable body (90, 100) and rotatably supported about a second rotational axis (85) of which the axis line extends in a direction perpendicular to the axis along the first rotation axis (110),
An axis along the first rotating shaft (110) passes through an intermediate position of the second rotating shaft (85), and the second movable shaft is disposed at one end of the second rotating shaft (85). A first effect body (90) as a body is attached, and a second effect body (100) as a second movable body is attached to the other end of the second rotation shaft (85),
The first movable body (60) is rotationally displaced between a first position and a second position where the second effect body (100) is located at a stop position of the first effect body (90) at the first position. Configured to be able to
The first effect body (60) of the first movable body (60) located on the front side of the second effect body (100) of the first movable body (60) in the first position. 90) is provided with a covering member (120) for covering the first effect body (90) and the second effect body (100),
When the first movable body (60) is rotationally displaced to the first position and the second position, the first effect body (90) and the second effect body (100) are exposed to the front side of the gaming machine alone. The summary is as follows.

In this way, the first movable body that rotates about the first rotation axis in accordance with the driving of the first driving means can rotate about the second rotation axis that extends in a direction intersecting the first rotation axis. Since the second movable body is arranged so that the second movable body rotates as the second driving means is driven, the first movable body and the second movable body are combined.・ Three-dimensional operation is realized. That is, by providing the second movable body having a different rotation axis direction with respect to the first movable body, it is possible to improve the decorativeness and diversify the production mode by the movable effect device. In addition, since the axis line along the first rotation axis and the axis line along the second rotation axis are configured to be orthogonal to each other, a composite and three-dimensional structure of the first movable body and the second movable body is formed. Operation is realized. Further, an axis line along the first rotating shaft passes through an intermediate position of the second rotating shaft, and a first effect body as a second movable body is attached to one end of the second rotating shaft. By attaching the second effect body as the second movable body to the other end portion of the second rotational shaft, when the first movable body is rotated, the rotation center of the first movable body is always sandwiched. Since the first effect body and the second effect body are rotated in a state where the first effect body and the second effect body are positioned, and each of the first effect body and the second effect body is rotated in accordance with the rotation accompanying the first movable body, more complex- Three-dimensional operation is realized. In addition, the covering member covers the front side of the second effect body with the first movable body in the first position, and the front side of the first effect body with the first movable body in the second position. Since the covering member is configured to cover, the effect body exposed on the front side of the gaming machine is switched to the first effect body and the second effect body in accordance with the rotation operation of the first movable body. As described above, the effect body exposed on the front side of the gaming machine is switched in accordance with the combined and three-dimensional operation of the first movable body and the second movable body (first effect body and second effect body). Further improvement of the decorativeness by the movable effect device and diversification of the effect mode can be achieved.

  According to the gaming machine according to the present invention, the first and second movable bodies can be operated in a complex and three-dimensional manner, so that it is possible to enhance the interest of the game by the movement of the movable body.

It is a front view which shows the pachinko machine which concerns on the Example of this invention. It is a front view which shows the game board which concerns on an Example. It is a front view which shows the installation member which concerns on an Example, Comprising: While a movable base body is hold | maintained in a 1st position, the state which has a 1st and 2nd production body in a reference position is shown. It is a front view which shows the left movable production | presentation apparatus which concerns on an Example, Comprising: While a movable base body is hold | maintained in a 1st position, the state which has a 1st and 2nd production body in a reference position is shown. It is a front view of the installation member which expands and shows the arrangement position of the left movable production device concerning an example, (a) shows the state where the decoration covering member covered the 2nd production body, (b) In (a), the state which removed the decoration coating | coated member is shown. It is a front view of the installation member which expands and shows the arrangement position of the left movable production device concerning an example, (a) shows the state where the decoration covering member covered the 1st production body, (b) In (a), the state which removed the decoration coating | coated member is shown. FIG. 4 is an exploded view of the apparatus main body and the movable base body in the movable effect device according to the embodiment, where the apparatus main body shows a state viewed from the front, and the movable base body shows a state viewed from the back. It is the sectional view on the AA line of FIG. It is a disassembled perspective view which shows the apparatus main body of the movable production | presentation apparatus which concerns on an Example in the state seen from the front. It is an exploded view of each component in the AA line cross section of FIG. It is a perspective view which shows the annular member which concerns on an Example, (a) shows the state seen from the front side, (b) shows the state seen from the back side. It is a rear view of the movable production | presentation apparatus which concerns on an Example, Comprising: The installation position of the wiring pressing member which hold | suppresses a flat cable is expanded and shown. It is a disassembled perspective view which shows the movable base body which concerns on an Example, Comprising: A motor cover and a light emission decoration cover are abbreviate | omitted and shown. It is a perspective view which shows the relationship between the base | substrate part of the base main body which concerns on an Example, and an annular member. The base part and cover body of the base main body which concerns on an Example are shown, (a) is the figure which looked at the base part from the arrangement | positioning side of a 1st effect body, (b) is arrangement | positioning of a 2nd effect body. It is the figure seen from the installation side. The base part and cover body of the base main body which concern on an Example are shown, (a) is the figure which looked at the base part from the inside of 2nd mechanism accommodation space, (b) is the inside of 2nd mechanism accommodation space. It is the figure seen from. It is a disassembled perspective view of the 1st production body which concerns on an Example, (a) shows the state seen from the back side, (b) shows the state seen from the front side. It is explanatory drawing which shows the relationship between the LED board for 1st effect bodies which concerns on an Example, and the 1st rotation support base body in a 1st effect body, Comprising: (a) is the state which has a 1st effect body in a reference position. (B) shows a state in which the first effector is rotated by a predetermined angle from the reference position. It is explanatory drawing which shows the relationship between the LED board for 2nd effect bodies which concerns on an Example, and the 2nd rotation support base body in a 2nd effect body, Comprising: (a) is the state which has a 2nd effect body in a reference position. (B) shows a state in which the second effector is rotated by a predetermined angle from the reference position. It is explanatory drawing which shows the operation | movement of the movable base body which concerns on an Example in the state seen from the back side, Comprising: (a) shows the state in which a movable base body exists in a 1st position, (b) The state in two positions is shown. It is explanatory drawing which shows operation | movement of the 1st effect body and 2nd effect body which concern on an Example. It is explanatory drawing which shows the state which wound the flat cable to the wiring winding part which concerns on an Example, Comprising: (a) shows the state in which a movable base body exists in a 1st position, (b) shows a movable base body in a 2nd position. Shows the state. It is AA sectional view taken on the line of FIG. 4, Comprising: The connection part of the annular member which concerns on an Example, and a cylindrical connection part is expanded and shown.

  Next, the gaming machine according to the present invention will be described in detail below with reference to the accompanying drawings by way of preferred embodiments. In each embodiment, a pachinko machine that plays a game using a pachinko ball as a game ball will be described as an example. In the following description, “front”, “rear”, “left”, and “right” refer to the pachinko machine 10 viewed from the front side (player side) as shown in FIG. 1 unless otherwise specified. Named by state.

(About pachinko machine 10)
As shown in FIG. 1, the pachinko machine 10 according to the embodiment is formed in a rectangular frame shape that opens forward and backward, and an opening front side of an outer frame 11 as a fixed frame that is fixed to an installation frame base (not shown) of a game shop. Further, a middle frame 12 as a main body frame for detachably holding a game board 20 (see FIG. 2), which will be described later, is assembled so as to be openable and detachable, and various symbols can be variably displayed on the back of the game board 20 A symbol display device 18 is detachably disposed. Further, on the front side of the middle frame 12, a front frame 13 as a decorative frame provided with a see-through protector (not shown) such as a glass plate for see-through protecting the game board 20 is assembled to be openable and closable. A lower ball tray 15 for storing pachinko balls is assembled below the front frame 13 so as to be openable and closable. In the embodiment, an upper ball tray 14 for storing pachinko balls is integrally assembled at a lower position of the front frame 13, and the upper ball tray 14 is also opened and closed integrally with the opening and closing of the front frame 13. Configured to do. An operation handle 16 for operating a ball hitting device (not shown) disposed on the middle frame 12 is provided at a lower right position of the middle frame 12. By operating the launching device, the pachinko balls stored in the upper ball tray 14 are launched toward the game board 20. In the embodiment, a liquid crystal display device in which a liquid crystal panel capable of displaying various symbols is housed in a housing case is adopted as the symbol display device 18, but the present invention is not limited to this. A dot matrix type display device, a 7-segment display, and other display devices capable of stopping and displaying various symbols can be adopted. Further, the upper ball tray 14 may be formed separately from the front frame 13 and assembled to the middle frame 12 so as to be openable and closable. The structure which provides only a saucer may be sufficient.

(About game board 20)
As shown in FIG. 2, the game board 20 is a transparent board formed of a transparent synthetic resin material such as acrylic or polycarbonate formed in a substantially rectangular shape with a predetermined board thickness, and the surface of the game board 20 In addition, a rail 21 curved in a substantially circular shape is provided, and a game area 20a in which a pachinko ball can flow down is defined by the rail 21, and the pachinko ball launched from the hitting ball launcher is launched into the game area 20a. It is supposed to be. The game board 20 has a plurality of mounting holes (not shown) penetrating in the front-rear direction in the game area 20a, and various components are attached to the respective mounting holes from the front side. In the lower position, an out port 22 for discharging a pachinko ball launched into the game area 20a is provided. The game board 20 has a large number of game nails planted in the game area 20a, and the pachinko balls flowing down the game area 20a come into contact with the game nails so that the flow direction of the pachinko balls is irregular. The pachinko sphere is guided in a certain direction. It should be noted that the number and size of the mounting openings are appropriately determined according to the number of various components attached to the game board 20 and the arrangement positions.

  Here, the game board 20 is provided with a frame-shaped decorative body 25 (see FIG. 2) in which a display window 25a opening in the front and rear is formed in the approximate center of the game area 20a. The display surface of the symbol display device 18 faces the front side of the game board 20 through the display window 25a of the body 25. As shown in FIG. 2, the frame-shaped decorative body 25 is formed in an annular shape extending along the mounting opening, and extends forward from the front surface of the game board 20 from the upper edge portion to the left and right side edge portions. Projecting bowl-shaped parts 26 are provided continuously, and the pachinko balls launched into the game area 20a are guided along the bowl-shaped parts 26 to the left and right sides of the frame-shaped decorative body 25, thereby The ball is restricted from flowing down across the display window 25a. The frame-shaped decorative body 25 is provided with a stage 27 on the lower opening edge side of the display window 25a, and on the left side of the display window 25a, the game area 20a is opened to flow down the game area 20a. A ball introducing portion 27 a is provided for taking in a pachinko ball to be guided to the stage 27.

  Further, as shown in FIG. 2, a start winning device 23 and a special winning device 24 capable of winning a pachinko ball flowing down the game area 20a are attached below the frame-shaped decorative body 25. Then, when a pachinko ball wins a winning opening of the start winning device 23, a symbol variation effect for displaying the symbols in a variable manner on the symbol display device 18 is developed. As a result of the symbol variation effect, a predetermined symbol is displayed on the symbol display device 18. When a symbol is definitely stopped and displayed in a combination of symbols (for example, a set of three identical symbols), a so-called big hit occurs, the special winning device 24 is opened, and a player can acquire a large number of prize balls. Opportunities have been given.

(About the installation member 28)
Further, an installation member 28 (see FIG. 3) to which the symbol display device 18 is attached is provided on the back surface of the game board 20. The installation member 28 is formed in a substantially rectangular shape and forward from a back plate 28a facing the game board 20, and upper and lower and left and right wall portions 28b extending forward from the outer peripheral edge of the back plate 28a. It is formed in the shape of a substantially rectangular box that opens to the front, and is fixed in a state in which the front end portion of the drawing wall portion 28 b is in contact with the back side of the game board 20. The symbol display device 18 is detachably attached to the back side of the back plate 28a of the installation member 28, and opens back and forth at a position corresponding to the display surface of the symbol display device 18 on the back plate 28a. An opening 28c (see FIG. 3) is established, and the display surface of the symbol display device 18 facing the opening 28c of the installation member 28 is connected to the game board 20 via the display window 25a of the frame-shaped decorative body 25. It can be visually recognized from the front side. Further, on the front side of the back plate 28a in the installation member 28 (that is, in the space defined by the game board 20 and the installation member 28), various decorative members 29 and light emitting devices are provided so as to surround the opening 26c. A device 30 and a movable effect device 31 are provided, and are configured to be seen through the board surface of the game board 20 from the front. That is, the installation member 28 functions as an installation means for the symbol display device 18 and various effect devices related to the game effect of the pachinko machine 10.

  As shown in FIG. 3, an accommodation recess 28 d that opens forward is formed below the opening 28 c formed in the installation member 28, and the game board 20 and the installation member 28 are assembled together. In addition, the start winning device 23 and the special winning device 24 attached to the game board 20 are accommodated in the accommodating recess 28d. And the movable production | presentation apparatus 31 which concerns on an Example is arrange | positioned in the front surface of the said back surface board 28a so that it may be located in the left-right side part on the lower side of the opening part 28c of the said installation member 28, and the said accommodation recessed part 28d. ing. The installation member 28 is provided with a decorative covering member 120 (described later) at a position in front of the movable effect device 31, and the decorative effect member 31 partially covers the movable effect device 31. Has been.

(About movable effect device 31)
Next, the movable effect device 31 of the pachinko machine 10 according to the embodiment will be described. In the pachinko machine 10 according to the embodiment, as described above, the pair of movable effect devices 31 and 31 are disposed on the left and right side portions sandwiching the housing recess 28d. The following description will be made with reference to the movable effect device 31 located on the left side, and the detailed description of the movable effect device 31 located on the right side will be omitted.

  As shown in FIGS. 7 and 8, the movable effect device 31 is a box in which a first mechanism housing space 42 (housing space) is internally defined and a first drive motor 45 (driving means) is installed outside. Device main body 33, first drive transmission means 47, 48, 50 housed in the first mechanism housing space 42 of the device main body 33 and connected to the first drive motor 45, and outside the device main body 33 And a movable base body 60 (first movable body) connected to and connected to the first drive transmission means 47, 48, 50, and based on a control signal from the control device. By driving 45, the movable base body 60 is configured to operate outside the apparatus main body 33. Here, the control device is a control device that controls the symbol display device 18 and can move the movable base body 60 in conjunction with a symbol variation effect performed by the symbol display device 18. . In the movable effect device 31 of the embodiment, the movable base body 60 is configured to rotate outside the device main body 33.

(About the device body 33)
As shown in FIGS. 9 and 10, the apparatus main body 33 includes a first case body 34 having an outer peripheral wall 35a extending rearward from an outer peripheral edge of a flat plate portion 35 formed in an appropriately shaped flat plate shape, It is comprised from the 2nd case body 39 which the outer peripheral wall part 40a extended ahead from the outer periphery of the flat plate part 40 formed in the flat form matched with the flat plate part 35 of the 1st case body 34. As shown in FIG. And by screwing both case bodies 34 and 39 in a state where the rear end of the outer peripheral wall portion 35a of the first case body 34 is aligned with the front end portion of the outer peripheral wall portion 40a of the second case body 39, The first mechanism housing space 42 is formed in a box shape defined inside. The apparatus main body 33 is screwed to the installation member 28 in a posture in which the flat plate portion 40 of the second case body 39 is opposed to the back plate 28a of the installation member 28. That is, the flat plate portion 35 of the first case body 34 forms the front surface of the device main body 33, and the flat plate portion 40 of the second case body 39 forms the rear surface of the device main body 33. In the following description, in the apparatus main body 33, the flat plate portion of the first case body 34 is referred to as a front flat plate portion 35, and the flat plate portion of the second case body 39 is referred to as a rear flat plate portion 40. To do. Here, the movable base body 60 is rotatably disposed on the front side of the front flat plate portion 35 of the apparatus main body 33.

  Further, as shown in FIGS. 4, 7, and 9, the front plate portion 35 of the apparatus main body 33 is formed with a first motor attachment portion 36 to which the first drive motor 45 is attached at the lower right position. In addition, a first shaft insertion hole 36 a that penetrates the first mechanism housing space 42 is formed in the first motor mounting portion 36. The first drive motor 45 is inserted into the first motor mounting portion 36 (that is, the front flat plate portion 35) in a posture in which the drive shaft is inserted into the first mechanism housing space 42 through the first shaft insertion hole 36a. is set up. That is, with respect to the apparatus main body 33, the first drive motor 45 is installed so as to be positioned on the outer surface on the side where the movable base body 60 is disposed (the front surface of the front flat plate portion 35). Accordingly, the movable rendering device 31 (device main body 33) is attached in a state where the rear surface (rear flat plate portion 40) is in contact with the back plate 28a of the installation member 28.

  As shown in FIGS. 7 and 8, a sliding support hole 37 (mounting hole) that opens into the first mechanism housing space 42 is formed in the upper left position of the front flat plate portion 35 of the apparatus main body 33. The movable base body 60 is connected to the first drive transmission means 47, 48, 50 (specifically, an annular member 50 described later) in the first mechanism accommodating space 42 through the sliding support hole 37. It is like that. Further, the rear flat plate portion 40 of the apparatus main body 33 is formed with a wiring lead-out hole 41 that opens to the first mechanism accommodating space 42 at a position aligned with the sliding support hole 37 in the front-rear direction. A wiring winding portion 112 provided in the movable base body 60 is configured to protrude rearward of the apparatus main body 33 via a wiring lead-out hole 41 (both described later). The opening center of the sliding support hole 37 and the opening center of the wiring lead-out hole 41 are formed so as to be aligned in the front-rear direction (the direction of the rotation axis L1 of the movable base body 60).

(About the first drive transmission means 47, 48, 50)
As shown in FIG. 9, the first drive transmission means 47, 48, 50 include a first drive gear (rotation drive unit) 47 attached to the drive shaft of the first drive motor 45, and a slide between the device main body 33. An annular member 50 rotatably supported in the dynamic support hole 37 and a first driven gear 48 including a spur gear connecting the first drive gear 47 and the annular member 50 are provided. The first driven gear 48 is supported so as to be freely rotatable with respect to a rotation support shaft 48 a supported by the front flat plate portion 35 and the rear flat plate portion 40 of the apparatus main body 33. Further, in the first drive transmission means 47, 48, 50 of the embodiment, a plurality (two in the embodiment) of the first driven gear 48 that mesh continuously are provided, and one first driven gear 48 is provided. The first drive gear 47 is meshed with the other first driven gear 48 and meshed with an outer peripheral gear portion 52 (described later) of the annular member 50. The annular member 50 is configured to rotate via the first drive gear 47 and the first driven gear 48.

(About the annular member 50)
As shown in FIGS. 8 to 11, the annular member 50 is formed in a ring shape in which a connecting hole 50 a penetrating in the front-rear direction at the opening position of the sliding support hole 37 is formed. In a state where the annular member 50 is installed in the single mechanism housing space 42, the front and rear end surfaces of the annular member 50 are configured to slidably contact the inner surfaces of the front flat plate portion 35 and the rear flat plate portion 40 of the apparatus main body 33. ing. The outer peripheral gear portion 52 is formed on the outer peripheral surface of the annular member 50, and the outer peripheral gear portion 52 meshes with the first driven gear 48. That is, when the first drive motor 45 is driven, with the front and rear end surfaces of the annular member 50 being in sliding contact with the inner surface of the apparatus main body 33, the annular member 50 is centered on the opening center of the connection hole 50a. Configured to rotate as a center. The outer peripheral gear portion 52 is formed over a range of approximately 2/3 (center angle approximately 240 degrees) of the outer peripheral surface of the annular member 50, and allows the reversing operation of the movable base body 60. It is configured as follows.

  As shown in FIGS. 10 and 11, a sliding contact piece 51 is formed on the outer peripheral surface of the annular member 50 so as to extend radially outward from a substantially center in the front-rear direction. The front portion of the sliding contact piece 51 at 50 is inserted into the sliding support hole 37 of the apparatus main body 33. That is, the front surface of the sliding contact piece 51 formed on the annular member 50 is in sliding contact with the inner surface of the front flat plate portion 35 in the apparatus main body 33. Here, the front flat plate portion 35 of the apparatus main body 33 is formed with a first annular rib 37a projecting into the first mechanism accommodating space 42 at the opening edge of the sliding support hole 37, and A second annular rib 50b that protrudes rearward along the outer peripheral edge is formed on the rear end surface of the annular member 50. The first annular rib 37a contacts the sliding contact piece 51, and the second annular rib 50b. Is in contact with the rear flat plate portion 40 of the apparatus main body 33. That is, by forming the first annular rib 37a and the second annular rib 50b, the sliding resistance when the annular member 50 rotates can be reduced, and the annular member 50 can be smoothly rotated. Yes. The outer peripheral gear portion 52 is formed on the outer peripheral surface located on the rear side of the sliding contact piece 51 (see FIGS. 8 and 10), and the outer peripheral gear portion 52 and the outer peripheral gear portion 52 in the first mechanism accommodating space 42. The first driven gear 48 is configured to be able to mesh.

  Further, a front portion of the sliding contact piece 51 (hereinafter referred to as a sliding cylinder portion 53) in the annular member 50 is formed in the sliding support hole 37 of the apparatus main body 33 as shown in FIGS. The outer peripheral surface is formed in sliding contact with the peripheral end surface. That is, when the sliding cylindrical portion 53 is in sliding contact with the inner peripheral end surface of the sliding support hole 37, when the annular member 50 is rotated, the opening center of the connection hole 50 a of the annular member 50 is at a fixed position. (The rotation axis L1 of the movable base body 60 is maintained). Further, a first position detecting piece 55 extending radially outward is formed on the outer peripheral surface of the annular member 50, and the first mechanism accommodating space 42 of the apparatus main body 33 is provided in the first mechanism receiving space 42. A first position detection sensor 56 (see FIG. 9) is disposed at a position spaced radially outward of the annular member 50, and the first position detection sensor 56 is changed to the first position as the annular member 50 rotates. The one-position detection piece 55 is configured to be detected. In the embodiment, the first effect body 90 (described later) provided on the movable base body 60 is in the first position (see FIG. 5) located on the opening 28c side of the installation member 28, and the first The first position detection sensor 56 is configured to detect the first position detection piece 55, and the movable base body 60 is inverted from the first position, whereby a second effect body 100 described later provided on the movable base body 60 is provided. The installation member 28 is displaced to a second position (see FIG. 6) located on the opening 28c side.

  As shown in FIGS. 10 and 11, a fixing piece 54 is formed at the rear end portion of the annular member 50 so as to extend around the inner side of the connection hole 50 a. Then, on the front surface of the fixing piece 54 (that is, inside the connecting hole 50a), fixing concave portions 54a (first engagement fixing portions) opening forward are formed at a plurality of locations (three locations in the embodiment) spaced apart in the circumferential direction. The fixed protrusion 111 (described later) formed on the movable base body 60 is screwed in a state of being fitted (engaged) with the fixed recess 54a. That is, when the fixed protrusion 111 is fitted into the fixed recess 54a, the movable base body 60 is positioned with respect to the circumferential direction of the annular member 50, and the movable base body 60 is circular when the annular member 50 rotates. The annular member 50 is configured not to be displaced in the circumferential direction.

(About movable base body 60)
Next, the movable base body 60 supported by the apparatus main body 33 will be described. As shown in FIGS. 7, 8, 10, and 13, the movable base body 60 includes a base body 61 disposed so as to face the front flat plate portion 35 of the apparatus body 33, and the base body 61. A cylindrical connecting part 110 connected to the annular member 50 provided in the apparatus main body 33, and the cylindrical connecting part 110 rotates as the first drive motor 45 is driven. The movable base body 60 (base body 61) is configured to rotate on the front side of the front flat plate portion 35 of the apparatus body 33. In other words, the cylindrical connecting portion 110 functions as a rotating shaft of the movable base body 60. The cylindrical connecting part 110 is provided on the rear end surface of the base main body 61, and the base main body 61 is formed in a flat box shape extending in the radial direction of the cylindrical connecting part 110. Yes. In the base main body 61, the first effect body 90 is disposed on one surface intersecting (orthogonal) with the direction of the axis L1 of the cylindrical connecting portion 110 and the longitudinal direction of the base main body 61, and the other The second effect body 100 is disposed on the surface. Here, the first effect body 90 and the second effect body 100 are located in a radial direction from the rotation axis L2 of the cylindrical connecting portion 110 and are spaced apart in the circumferential direction of the rotation axis L2. ing. That is, when the movable base body 60 is rotated with the driving of the first drive motor 45, the first effect body 90 and the second effect body 100 are rotated in the circumferential direction around the cylindrical connecting portion 110. It is configured to move.

(About the base body 61)
As shown in FIGS. 13 to 16, the base main body 61 includes a base portion 62 in which an outer peripheral wall portion 62 a extends from an outer peripheral edge of a flat plate portion 63 formed in a substantially rectangular shape, and an outer peripheral wall of the base portion 62. The second drive transmission means 83, 84, 85, 86, which will be described later, are configured by screwing the base body portion 62 and the lid body portion 75 with a lid portion 75 that closes the opening defined by the portion 62 a. The second mechanism accommodating space 80 (accommodating space) is accommodated and is formed in a substantially rectangular box shape. The movable base body 60 is arranged in such a posture that one (rear) outer peripheral wall portion 62a extending from the long side of the flat plate portion 63 in the base portion 62 faces the front flat plate portion 35 of the apparatus main body 33. ing. In the following description, in the movable base body 60 (base body 61), the flat plate portion of the base body portion 62 is referred to as a first flat plate portion 63, and the flat plate portion facing the first flat plate portion 63 in the lid body portion 75. The shaped portion is referred to as the second flat plate portion 76.

  Here, as shown in FIGS. 8, 10, 13, and 17, the first effect body 90 is disposed on the outer surface side of the first flat plate portion 63 in the base body 61 and the second effect body 90. The effect body 100 is disposed on the outer surface side of the second flat plate portion 76 in the base body 61. As the first drive motor 45 is driven, the first effector 90 is positioned on the opening 28c side of the installation member 28, and the second effector 100 is positioned below the base body 61. From the first position (see FIG. 5), the second effector 100 is inverted from the first position and is positioned on the opening 28c side of the installation member 28, and the first effector 90 is positioned downward with the base body 61 interposed therebetween. It is configured to reciprocate between a second position (see FIG. 6). And in the state which exists in the said 1st position, the said 1st production body 90 is exposed to the front side of the game board 20 via the display window 25a of the frame-shaped decoration body 25 provided in the said game board 20, and the said 2nd position In this state, the second effect body 100 is exposed to the front side of the game board 20 through the display window 25a of the frame-shaped decorative body 25.

  As shown in FIG. 13, a second drive motor 81 (second drive means) as an electrical component is disposed on the base body 61 of the movable base body 60, and is connected to the second drive motor 81. Second drive transmission means 83, 84, 85, 86 are arranged, and the first effect body 90 and the second effect body 100 are connected to the second drive transmission means 83, 84, 85, 86. . That is, in the movable effect device 31 according to the embodiment, the first effect body 90 and the second effect element 90 that operate by driving the second drive motor 81 with respect to the movable base body 60 that rotates by driving the first drive motor 45. A director 100 is provided.

  The first flat plate portion 63 of the base body 61 is formed with a second motor attachment portion 64 to which the second drive motor 81 is attached in the vicinity of the left end portion based on the state at the first position. A second shaft insertion hole 64 a that penetrates the second mechanism housing space 80 is formed in the second motor attachment portion 64. The second drive motor 81 is inserted into the second motor mounting portion 64 (that is, the first flat plate portion 63) in a posture in which the drive shaft is inserted into the second mechanism housing space 80 through the second shaft insertion hole 64a. is set up. That is, the second drive motor 81 is installed so as to be positioned side by side with the outer surface (the outer surface of the first flat plate portion 63) on the side where the first effector 90 is disposed with respect to the base body 61. The base body 61 is provided with a motor cover 65 that covers and decorates the second drive motor 81 so that the second drive motor 81 is not directly exposed to the front surface of the game board 20. Yes.

  Here, as shown in FIGS. 4 and 7, the motor cover 65 is formed so as to surround at least the front and left and right sides of the second drive motor 81 and has a light-transmitting first front side. A decorative lens 65a is provided. A light transmitting hole 63a is formed in the first flat plate portion 63 of the base main body 61 so as to open inside the motor cover 65, and as an electrical component installed in the second mechanism accommodating space 80. The light from the LED 66a provided on the first light emitting decoration LED substrate 66 (see FIGS. 13 and 15) is irradiated to the first decoration lens 65a through the light transmission hole 63a.

  Further, as shown in FIG. 4, a light emitting decoration cover 67 is disposed on the first flat plate portion 63 of the base main body 61 in the vicinity of the right end portion based on the state at the first position. That is, in the movable base body 60 of the embodiment, the first effect body 90 is disposed between the motor cover 65 and the light emitting decoration cover 67. The light emitting decorative cover 67 is formed in a substantially rectangular box shape, and a light transmissive second decorative lens 67a is provided on the front side thereof. Then, a second light emitting decoration LED board 68 (see FIG. 8) as an electrical component is installed inside the light emitting decoration cover 67, and an LED (not shown) provided on the second light emitting decoration LED board 68 is provided. ) Is transmitted forward through the second decorative lens 67a.

(About the second drive transmission means 83, 84, 85, 86)
Further, the second drive transmission means 83, 84, 85, 86 are, as shown in FIGS. 13 and 16, the second drive gear 83 attached to the drive shaft of the second drive motor 81, and the first effect. The rotation support gear 84 (rotation support plate) to which the movable shaft portion 85 (second rotation shaft) connected to the body 90 and the second effect body 100 is coupled, and the second drive gear 83 and the rotation support gear 84 are connected. A second driven gear 86 made of a spur gear, and each of the second drive gear 83, the rotation support gear 84, and the second driven gear 86 constituting the second drive transmission means 83, 84, 85, 86 is provided. The second mechanism accommodation space 80 is accommodated inside. The second driven gear 86 is supported so as to be freely rotatable with respect to the rotation support shaft 48 a supported by the first flat plate portion 63 and the second flat plate portion 76 of the base body 61. Further, in the second drive transmission means 83, 84, 85, 86 of the embodiment, a plurality (two in the embodiment) of the second driven gear 86 continuously meshing are provided, and one of the second driven gears is provided. 86 is meshed with the second drive gear 83 and the other second driven gear 86 is meshed with the rotation support gear 84, and the second drive gear 83 is driven by the rotation of the second drive motor 81. The rotation support gear 84 is configured to rotate via the second driven gear 86.

  Here, as shown in FIGS. 8, 10, and 13, the movable shaft portion 85 passes through the center of the rotation support gear 84, and the intermediate position of the movable shaft portion 85 becomes the rotation support gear 84. The movable shaft portion 85 is connected and rotated integrally with the rotation of the rotation support gear 84. The movable shaft portion 85 protruding from the surface side (one surface side) of the rotation support gear 84 facing the first flat plate portion 63 side of the base main body 61 is a shaft formed on the first flat plate portion 63. The first effect body 90 is connected to an end portion (one end portion) of the movable shaft portion 85 that is inserted through the through hole 69 a of the support portion 69 and protrudes from the first flat plate portion 63. Further, the movable shaft portion 85 protruding from the surface side (the other surface side) facing the second flat plate portion 76 of the base main body 61 in the rotation support gear 84 is inserted into the shaft formed in the second flat plate portion 76. The second effect body 100 is connected to an end portion (the other end portion) of the movable shaft portion 85 that is inserted through the hole 77 and protrudes from the second flat plate portion 76. That is, each of the first effect body 90 and the second effect body 100 supports the rotation around the movable shaft portion 85 as the second drive motor 81 is driven based on a control signal from a control device. The gear 84 (base body 61) is sandwiched and operated (rotated) in the same direction.

  Further, as shown in FIGS. 8, 10, and 23, the movable shaft portion 85 that protrudes from the rotation support gear 84 toward the first flat plate portion 63 has a bearing portion 70 with the shaft support portion 69 interposed therebetween. Each is interposed and rotatably supports the movable shaft portion 85. The bearing portion 70 includes a cylindrical portion 70a inserted into the through hole 69a of the shaft support portion 69, and a locking piece 70b extending radially outward from the end portion of the cylindrical portion 70a. When the cylindrical portion 70 a is inserted into the through hole 69 a of the shaft support portion 69, the locking piece 70 b is locked to the end portion of the bearing portion 70, so that it is held at a predetermined position. On the other hand, the shaft insertion hole 77 formed in the second flat plate portion 76 is a circular opening having a larger diameter than the movable shaft portion 85, and the shaft insertion hole 77 of the second flat plate portion 76 is formed in the movable shaft portion 85. It is configured not to touch.

  Further, as shown in FIGS. 8 and 10, the movable base that passes through the opening center of the coupling hole 50 a of the annular member 50 (center of the cylindrical coupling portion 110) on the axis L <b> 2 that passes through the movable shaft portion 85. The rotation axis L1 of the body 60 is located, and the rotation axis L1 of the movable base body 60 is set to be orthogonal at an intermediate position of the movable shaft portion 85. That is, as the movable base body 60 rotates as the first drive motor 45 is driven, the first rendering body 90 and the second rendering body 100 have the same locus around the rotation axis L1 of the movable base body 60. As the second drive motor 81 is driven simultaneously or separately with the driving of the first drive motor 45, the first effect body 90 and the second effect body 90 are centered on the movable shaft 85. The director 100 rotates in the same direction. Thus, by combining the driving of the first drive motor 45 and the second drive motor 81, the first effect body 90 and the second effect body 100 operate in a complex and three-dimensional manner.

(About the LED board 71 for the first effector)
Further, as shown in FIGS. 8, 10, 13, and 15, a first effector LED is provided between the first effector 90 and the outer surface of the first flat plate portion 63 of the base body 61. A substrate 71 (first light emitting means, electrical component) is provided. The first effector LED board 71 is formed with an insertion hole 71b at a position corresponding to the shaft support portion 69 (movable shaft portion 85) so as to penetrate the first effector LED substrate 71. The movable shaft portion 85 protrudes. A plurality (examples) of the first stage effector LED board 71 are spaced apart from each other in the circumferential direction around the movable shaft 85 on the outer surface (the surface opposite to the surface facing the first flat plate portion 63). The three LEDs (light emitting bodies) 71 a are mounted so as to irradiate light toward the first effect body 90 along the axial direction of the movable shaft portion 85. Here, each LED 71 a of the first effector LED board 71 is mounted on the first light emitting decoration LED board 66 so as to be located on the rear side (cylindrical connecting part 110 side) of the movable shaft part 85. Each LED 71a is placed on a first reflecting surface 99 (described later) of the first effector 90 in a state where the first effector 90 is held at a reference position described later (see FIGS. 5, 6, 8, etc.). Oppositely, the light from the LED 71a is reflected in the radial direction of the rotation support gear 84 (movable shaft portion 85) (see FIG. 8). Further, a second position detection sensor for detecting a reference position of the first effector 90 on the outer surface of the first effector LED substrate 71 at a radially outer position of the movable shaft 85 than the LED 71a. 72 is provided.

(About LED board 78 for second effector)
As shown in FIGS. 8, 10, 13, and 15, a second effector LED is provided between the second effector 100 and the outer surface of the second flat plate portion 76 of the base body 61. A substrate 78 (second light emitting means, electrical component) is disposed. The second effector LED board 78 is formed with an insertion hole 78b at a position corresponding to the shaft support portion 69 (movable shaft portion 85) so as to penetrate the second effector LED substrate 78. The movable shaft portion 85 protrudes. A plurality (examples) of the second effector LED substrate 78 are spaced apart from each other in the circumferential direction around the movable shaft 85 on the outer surface (the surface opposite to the surface facing the second flat plate portion 76). The three LEDs (light emitters) 78 a are mounted so as to irradiate light toward the second effect body 100 along the axial direction of the movable shaft portion 85. Here, each LED 78a of the second effector LED board 78 is mounted on the second light emitting decoration LED board 68 so as to be located on the rear side (cylindrical connecting part side) of the movable shaft part 85. Each LED 78a is opposed to a second reflecting surface 103 (described later) of the second effector 100 in a state where the second effector 100 is held at a reference position (see FIGS. 5, 6, 8, etc.) described later. And it is comprised so that the light from this LED78a may be reflected in the radial direction of the rotation support gear 84 (movable shaft part 85).

  Here, the first staging body LED board 71 includes the second drive motor 81, the first light emitting decoration LED board 66, the second light emitting decoration LED board 68, and the like disposed on the movable base body 60. Wiring derived from each of the second effector LED boards 78 is connected. That is, the first effector LED board 71 has a function as a relay connection board for various electric parts disposed on the movable base body 60. And the flat cable 130 which coat | covered the conducting wire with the film is connected to the connection connector 73 arrange | positioned by the surface opposite to the 1st flat plate part 63 in the said LED board 71 for 1st effect bodies, and this flat cable 130 is connected. It is connected to the control device provided outside the movable effect device 31. In addition, the connection connector 73 is disposed so as to be positioned between the movable shaft portion 85 and the cylindrical coupling portion 110, and the flat cable 130 connected to the connection connector 73 is an LED for the first effect body. It is led backward in parallel with the substrate 71 and is wound around a wiring winding portion 112 (described later) formed in the cylindrical connecting portion 110. In this way, by winding the flat cable 130 around the wiring winding portion 112, the load acting on the cable with the rotation operation of the movable base body 60 is reduced, and the occurrence of disconnection or the like is prevented.

  Further, the LED 66a of the first light emitting decoration LED board 66, the LED of the second light emitting decoration LED board 68, the LED 71a of the first effector LED board 71, and the LED 78a of the second effector LED board 78 are independent. Light emission is controlled so that light is emitted (turned on and blinking) and turned off, and the LEDs 66a, 71a, and 78a on each of the substrates are appropriately caused to emit light, so that various light emission effects can be performed.

(About the first director 90)
As shown in FIG. 17, the first effect body (second movable body) 90 is attached to the movable shaft portion 85, and is a disk-shaped first rotation that faces the first effect body LED substrate 71. A support base body 91 and a non-light-transmissive outer design body 94 that is provided on the first rotation support base body 91 and defines a space portion 90a through which light of the LED 71a of the first effector LED substrate 71 is transmitted. And a light transmission portion provided on the outer peripheral surface of the outer design body 94. The first rotation support base body 91 has the movable shaft portion 85 connected to a fixed hole 91a formed at the center position thereof, and the first rotation support base body 91 is integrated with the rotation of the movable shaft portion 85. It is designed to rotate. A second position detection piece 91b that protrudes toward the substrate is formed on a surface of the first rotation support base body 91 that faces the LED board 71 for the first effector, and the first rotation support base body 91 is formed. The second position detection sensor 72 provided on the substrate is configured to detect the second position detection piece 91b with the rotation of the second position detection piece.

  As shown in FIGS. 17 and 18, the second position detection sensor 72 places the second position detection piece 91 b at a position spaced apart from the movable shaft 85 in the first rotation support base body 91 in the radial direction. A first light transmission window 92 that opens in the axial direction of the movable shaft portion 85 is opened at the reference position to be detected. In a state where the first rotation support base body 91 (first effect body 90) is at the reference position, each LED 71a disposed on the first effect body LED substrate 71 is provided in the first light transmission window 92. The light from each LED 71a is irradiated to the space portion 90a between the outer design body 94. Here, as described above, the LEDs 71a disposed on the first effector LED board 71 are arranged to be biased toward the rear side (cylindrical connecting portion side) of the movable shaft portion 85. As the first rotation support base body 91 rotates, the number of LEDs 71a facing the first light transmission window 92 changes. Further, the movable shaft portion 85 is interposed on the arrangement surface side of the outer design body 94 in the first rotation support base body 91 (the surface opposite to the surface facing the first effector LED board 71). A pair of fixed protrusions 93 and 93 are formed so as to project apart from each other in the longitudinal direction of the movable base body 60, and the outer design body 94 is fixed to the pair of fixed protrusions 93 and 93. It is like that. In addition, fitting concave portions 93a and 93a into which fixed shaft portions 95b and 95b formed in the outer design body 94 are fitted are formed on the front surfaces of the fixed protrusions 93 and 93, respectively.

  As shown in FIG. 17, the outer design body 94 includes a front design body 95 positioned on the front surface side in a state where the first rotation support base body 91 (first effect body 90) is at a reference position, The outer design body 94 is composed of a rear design body 98 surrounding the rear side of the part design body 95 and an intermediate design body 97 disposed between the front design body 95 and the rear design body 98. It is formed so as to exhibit a spotlight-like design. The front design body 95 is formed with a light emitting portion 95a that opens into the space portion 90a, and a lens portion 96 is disposed inside the light emitting portion 95a (on the space portion 90a side). The part 96 is configured to be sandwiched between the front design body 95 and the intermediate design body 97. Here, the light emitting portion 95a is opened to open in the radial direction with respect to the first rotation support base body 91 (movable shaft portion 85), and the first effect body 90 is in a reference position. The light emitting part 95a faces the front of the game board 20. Further, a pair of fixed shaft portions 95b and 95b projecting toward the rear design body 98 so as to sandwich the movable shaft portion 85 at the end portion of the front design body 95 on the first rotation support base body 91 side. Is formed.

  As shown in FIG. 17, the intermediate design body 97 is provided with a partition hole 97a that opens in the front-rear direction in a state where the first effector 90 is at the reference position at a position corresponding to the light emitting portion 95a. The front through holes 97b and 97b through which the fixed shaft portions 95b and 95b of the front design body 95 can be inserted are respectively formed at the end portions on the first rotation support base body 91 side. Then, the lens portion 96 is sandwiched between the front design body 95 and the intermediate design body 97 by inserting the fixed shaft portions 95b, 95b so as to penetrate the front through holes 97b, 97b. It is assembled in the state. In a state where the front design body 95 and the intermediate design body 97 are assembled, the partition hole 97a of the intermediate design body 97 is substantially aligned with the contour portion of the light emitting portion 95a.

  Further, as shown in FIG. 17, the rear design body 98 opens to the front design body 95 side (forward in a state where the first effect body 90 is at the reference position) and the first rotation support base body 91 side. A light guide recess 98a is formed, and each fixed shaft of the front design body 95 inserted into the front through holes 97b, 97b of the intermediate design body 97 at the end on the first rotation support base body 91 side is formed. Rear through holes 98b and 98b that can be inserted through the portions 95b and 95b are formed correspondingly. And in the state which assembled | attached the said front design body 95 and the intermediate design body 97, by inserting each said fixed shaft part 95b and 95b so that it may penetrate to the corresponding rear side through-holes 98b and 98b, the said front part The outer design body 94 is formed by assembling the intermediate design body 97 between the design body 95 and the rear design body 98. Here, in a state where the outer design body 94 is assembled, the front end portion of the rear design body 98 is configured to contact the rear end portion of the intermediate design body 97 over the entire circumference. That is, the outer design body 94 extends in the axial direction of the movable shaft portion 85 and extends to the light emitting portion 95a by a partition hole 97a of the intermediate design body 97 and a light guide recess 98a of the rear design body 98. A substantially L-shaped space portion 90a bent in the radial direction of the movable shaft portion 85 toward the (lens portion 96) is formed in a state opened to the first rotation support base body 91 side. Then, the fixed shaft portions 95b and 95b inserted into the rear through holes 98b are fitted into the fitting recesses 93a and 93a of the fixed protrusions 93 and 93 formed in the first rotation support base body 91, respectively. The first rotation support base body 91 and the outer design body 94 are fixed by screwing in the fitted state.

  Here, as shown in FIGS. 8, 10, and 23, the first rotation support base body 91 and the outer design body 94 are fixed to the first rotation support base body 91. One light transmission window 92 is configured to open into a space 90 a formed in the outer design body 94. Therefore, the light of the LED 71 a of the first effector LED substrate 71 is irradiated into the space portion 90 a through the first light transmission window 92. Further, inside the space portion 90a, light emitted into the space portion 90a through the first light transmission window 92 at the bent position bent in the substantially L shape is emitted from the light emitting portion 95a (lens portion). 96) is provided which reflects toward 96). Here, the first reflecting surface 99 is formed in a flat mirror shape, and the light irradiated into the space portion 90a is uniformly applied to the light emitting portion 95a (lens portion 96) by the first reflecting surface 99. It is comprised so that it can reflect toward. Further, the lens unit 96 is subjected to light diffusion processing such as diamond cutting and embossing so that the light reflected by the first reflecting surface 99 can be diffused to cause the light emitting unit 95a to emit light as a whole. It has become. The first reflecting surface 99 is formed integrally with the intermediate design body 97.

  That is, the light from the LED 71 a of the first effector LED board 71 irradiated into the space 90 a through the first light transmission window 92 is reflected by the first reflecting surface 99 and is reflected on the lens unit 96. The light emitting part 95a emits light as it is irradiated, and the irradiation direction of the light transmitted through the lens part 96 (that is, the light from the light emitting part 95a) rotates as the first effector 90 rotates. At the reference position, the light emitting unit 95a is directed forward of the game board 20, and the reflected light of the first reflecting surface 99 is irradiated forward of the game board 20. Further, as the first effector 90 rotates from the reference position, the number of LEDs 71a of the first effector LED board 71 facing the inside of the first light transmission window 92 changes, whereby the first effector 90 changes. As the effector 90 rotates, the intensity of light reflected by the first reflecting surface 99 changes. That is, as the first effector 90 rotates, the irradiation direction of the light transmitted through the lens unit 96 not only rotates, but also the light transmitted through the lens unit 96 (that is, light from the light emitting unit 95a). By changing the intensity, the effect of lighting effect is enhanced.

(About the 2nd production 100)
As shown in FIGS. 8, 10, 13, and 21, the second rendering body (second movable body) 100 is attached to the movable shaft portion 85, and is mounted on the second rendering body LED substrate 78. The disk-shaped second rotation support base body 101 and the second reflection surface 103 provided on the second rotation support base body 101 are provided. The second rotation support base body 101 has the movable shaft portion 85 connected to a fixed hole 101a formed at the center thereof, and the second rotation support base body 101 is integrated with the rotation of the movable shaft portion 85. It is designed to rotate. Here, as described above, since the first effect body 90 and the second effect body 100 are attached to the movable shaft portion 85, the second position detection piece provided in the first effect body 90. When the second position detection sensor 72 detects 91b, the reference position of the second effector 100 is determined together with the first effector 90.

  As shown in FIGS. 13 and 19, the second position detection sensor 72 places the second position detection piece 91b at a position spaced apart from the movable shaft 85 in the second rotation support base body 101 in the radial direction. A second light transmission window 102 opening in the axial direction of the movable shaft portion 85 is opened at the reference position to be detected. When the second rotation support base body 101 (second effect body 100) is in the reference position (the second position detection sensor 72 detects the second position detection piece 91b), the second effect body is used. Each LED 78 a disposed on the LED substrate 78 faces the second light transmission window 102, and the light from each LED 78 a is irradiated onto the second reflecting surface 103. Note that, at the reference position, the second reflection surface 103 is directed forward of the game board 20, and the reflected light of the second reflection surface 103 is irradiated forward of the game board 20. Here, as described above, the LEDs 78a disposed on the second effector LED substrate 78 are arranged to be biased toward the rear side (tubular connecting portion side) of the movable shaft portion 85. As the second rotation support base body 101 rotates, the number of LEDs 78a facing the second light transmission window 102 changes.

  As shown in FIGS. 8 and 10, the second reflection surface 103 is formed on the second rotation support base body 101 in a state where the second rotation support base body 101 (second effect body 100) is at the reference position. It extends from the outer peripheral edge of the substantially half circumference on the rear side (cylindrical connecting portion side) in a direction away from the second effector LED board 78 and along the movable shaft portion 85 toward the extending end portion. It is formed in a concave shape curved so as to be close to the axis L2. The second reflecting surface 103 is configured to face the front side in the light irradiation direction of the LEDs 78a facing the second light transmission window 102 of the second rotation support base body 101. Accordingly, the light of the LED 78 a of the second effector LED board 78 is irradiated to the second reflecting surface 103 through the second light transmitting window 102 and reflected by the second reflecting surface 103. It has become. Note that the second reflecting surface 103 is provided. Light diffusion processing such as diamond cutting and embossing is performed, and the light applied to the second reflecting surface 103 is reflected while being diffused over a wide range.

  Here, as shown in FIGS. 8, 10, and 13, the second rendering body 100 is surrounded by a cylindrical cover body 104 disposed on the second flat plate portion 76 of the base body 61. Has been. That is, the second effect body 100 is located inside the cover body 104 disposed on the second flat plate portion 76 of the base body 61. For this reason, with the rotation of the second effector 100, the irradiation position where the light reflected by the second reflecting surface 103 is irradiated onto the cover body 104 rotates. Further, as the second effector 100 rotates from the reference position, the number of LEDs 78a of the second effector LED board 78 facing the inside of the second light transmission window 102 changes, whereby the second effector 100 changes. As the effector 100 rotates, the intensity of light reflected by the second reflecting surface 103 changes. That is, with the rotation of the second effect body 100, not only the irradiation position of the light irradiated to the cover body 104 rotates, but also the intensity of the light irradiated to the cover body 104 changes. By doing so, the light emission effect is enhanced.

  Thus, in the movable effect device 31 according to the embodiment, effect parts (motor cover 65, light emitting decoration cover 67, first effect body 90) disposed on the first flat plate portion 63 side of the base body 61, and Not only the appearance of the stage parts (cover body 104, second stage body 100) arranged on the first flat plate part 63 side of the base body 61 is different, but also the light emission stage is different. The rotation operation of the movable base body 60 by driving the first drive motor 45, the rotation operation of the first rendering body 90 and the second rendering body 100 by driving the second drive motor 81, and the LEDs 71a of the LED boards 71 and 78. , 78a are combined to produce a variety of effects.

(About the cylindrical connecting part 110)
Next, the cylindrical connecting part 110 provided on the movable base body 60 will be described.
As shown in FIGS. 7, 8, and 14, the cylindrical connecting portion 110 is formed in a cylindrical shape that can be inserted into a connecting hole 50 a of the annular member 50 provided in the apparatus main body 33 and is rearward. And is provided on the rear end face side of the base body 61. More specifically, a cylindrical connecting portion 110 is formed integrally with the base portion 62 of the base body 61. Here, the outer diameter size of the cylindrical connecting portion 110 is set so as to substantially match the inner diameter size of the connecting hole 50a defined by the fixing piece 54 formed in the annular member 50, and the cylinder. A fixed protrusion 111 (second engagement fixing portion) is formed on the outer periphery of the ring-shaped connecting portion 110 so as to correspond to the fixing recess 54 a provided in the annular member 50. That is, the cylindrical connecting portion 110 is fitted inside the opening of the fixed piece 54 (connecting hole 50a) of the annular member 50, and each fixed protrusion 111 is fitted into the fixed recess 54a from the rear side. The annular member 50 (fixed piece 54) and the cylindrical connecting portion 110 (fixed protrusion 111) are screwed. As a result, the rotation support base body integrally rotates about the cylindrical connecting portion 110 as the annular member 50 rotates. Here, in a state where the annular member 50 and the cylindrical connecting portion 110 are connected, the rear end portion of the cylindrical connecting portion 110 is set to be substantially the same position as the rear end surface of the annular member 50, A cylindrical connecting part 110 is opened behind the annular member 50.

  Further, as shown in FIGS. 8, 10, 14, 22, and 23, a wiring wrapping portion 112 concentric with the cylindrical connecting portion 110 is formed inside the cylindrical connecting portion 110. Yes. A flat cable connected to the first effect body LED board 71 provided on the movable base body 60 in an annular space 113 defined between the cylindrical connecting portion 110 and the wire winding portion 112. 130 is wound. In other words, the flat cable 130 is wound around the wiring winding portion 112 around the rotation axis L1 of the movable base body 60 (center line of the cylindrical connecting portion 110) in a fixed direction. When the flat cable 130 wound around the wiring winding portion 112 is loosened (relaxed) or wound (contracted) along with the rotation of 60, the reciprocating rotational motion of the movable base body 60 is allowed. As described above, the cylindrical connecting portion 110 has a function as an annular guide extending concentrically with the wiring winding portion 112 on the outer side in the radial direction of the wiring winding portion 112. The flat cable 130 relaxed with the rotation is prevented from protruding outside the annular space 113.

  Here, as shown in FIGS. 8, 10, 13, 15, and 23, the cylindrical connecting part 110 has a front side corresponding to the outer surface side of the first flat plate part 63 of the base body 61. A wiring notch 114 is formed that opens outward in the radial direction of the first effect body LED board 71 side and the cylindrical connecting portion 110. That is, the flat cable 130 led backward from the connection connector 73 in parallel with the first effector LED board 71 is inserted into the annular space 113 via the wiring cutout 114, and the By being bent so as to be bent by 90 ° in the annular space 113, the wire is wound around the wiring winding portion 112 in the annular space 113.

  Also, as shown in FIGS. 8, 10, 15, 16, and 23, the wire winding portion 112 is formed to extend rearward from the rear end portion of the cylindrical connecting portion 110, and The device main body 33 (second case body 39) protrudes rearward from the device main body 33 through a wiring lead-out hole 41. In addition, a disc-shaped cover member 115 formed in a disc shape having a size extending radially outward from the wiring winding portion 112 is provided at the rear end portion (extending end portion) of the wiring winding portion 112. Is attached. That is, a rear opening of the annular space 113 defined between the cylindrical connecting portion 110 and the wiring winding portion 112 is partially blocked by the disk-shaped cover member 115, so that the apparatus main body 33 is closed. It is comprised so that it may open to the radial direction outward of the cylindrical connection part 110 in the back side. Thereby, the cable portion wound around the wiring winding portion 112 in the flat cable 130 is prevented from dropping off from the annular space 113. The disk-shaped cover member 115 is formed of a transparent synthetic resin plate, and the flat cable 130 wound around the wiring winding portion 112 through the disk-shaped cover member 115 can be visually observed from the back side. It is like that.

  Then, the flat cable 130 wound around the wire winding portion 112 is led out to the rear side of the apparatus main body 33 through a gap between the rear end portion of the cylindrical connecting portion 110 and the disc-like cover member 115. And connected to the control device. A wiring recess 117 is formed on the rear surface of the device main body 33 (second case body 39) on the rear side plate portion 40 (the surface facing the back plate 28a of the installation member 28) (see FIG. 12). By guiding the flat cable 130 so as to pass through the wiring recess 117, the cable is prevented from being caught between the apparatus main body 33 and the installation member 28. Further, the flat cable 130 is sandwiched and fixed between the apparatus main body 33 and the rear flat plate portion 40 by a wiring pressing member 118 in the vicinity of the wiring lead-out hole 41. That is, the flat cable 130 is fixed to the device main body 33 (wiring pressing member 118) and the movable base body 60 (connecting connector 73) in the vicinity of the outside of the annular space 113, so that the wire winding portion 112 is fixed. Only the wound cable portion is allowed to relax and contract in the annular space 113 as the movable base body 60 rotates.

(About the decorative covering member 120 of the installation member 28)
Next, the decoration covering member 120 disposed on the installation member 28 will be described. As shown in FIGS. 8 and 23, the decorative covering member (covering member) 120 covers the front side of the second effect body 100 in a state where the movable base body 60 is rotationally displaced to the first position. The movable base body 60 is configured to cover the front side of the first effect body 90 in a state where the movable base body 60 is rotationally displaced to the second position. That is, when the movable base body 60 is rotationally displaced to the first position and the second position, the first effect body 90 is independently provided on the front side of the game board 20 via the display window 25a of the frame-shaped decorative body 25. The first effect body 90 is switched to the state exposed to the front side of the game board 20 through the display window 25a. Thus, the impression (image) of the pachinko machine 10 can be greatly changed by switching the production bodies 90 and 100 facing the display window 25a of the frame-shaped decorative body 25. When the movable base body 60 is in the first position, the motor cover 65 and the light emitting decorative cover 67 provided on the movable base body 60 are also located inside the display window 25a of the frame-shaped decorative body 25. The front side of the motor cover 65 and the light emitting decorative cover 67 is covered with the decorative covering member 120 when the movable base body 60 faces the upper side of the stage 27 and is in the second position. The first effect body 90, the second effect body 100, the motor cover 65, and the light emitting decoration cover 67 that face the display window 25a of the frame-shaped decorative body 25 are transparent regulating walls that form the rear wall of the stage 27. It partially overlaps with the member 27b (see FIG. 2).

  Further, the decorative covering member 120 is formed of a light-transmitting synthetic resin material, and a non-light transmitting portion 121 such as painting or plating is partially formed on the surface of the decorative covering member 120 ( (See FIGS. 5 and 6). Further, the decorative covering member 120 is disposed behind the game area 20a where the pachinko balls flow down on the game board 20. Therefore, the back side of the decorative covering member 120 can be visually recognized from the front side of the game board 20 through the region excluding the non-light transmitting portion 121 (that is, the visible portion 122) in the decorative covering member 120. That is, in the state where the movable base body 60 is rotationally displaced to the first position, the first effect body 90 is directly visually recognized via the display window 25a of the frame-shaped decorative body 25, while the decorative covering member The second effect body 100 is visually recognized through 120 visible portions 122. Then, in the state where the movable base body 60 is rotationally displaced to the second position, the second effect body 100 is directly visually recognized via the display window 25a of the frame-shaped decorative body 25, while the decorative covering member 120 is visible. The first effect body 90 is visually recognized through the part 122. Here, in the embodiment, on the surface of the decorative covering member 120 formed of a colored transparent resin plate, a fine grid-like non-light transmitting portion 121 is formed by painting, and the frame-shaped decorative body 25 Compared with the stage body directly seen through the display window 25a, the stage body covered with the decorative covering member 120 is inferior in visibility, and the hidden stage bodies 90 and 100 are partially visible. As a result, the unexpectedness and expectation for the development of the game production are enhanced.

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

  The pachinko balls launched into the game area 20a along the rails 21 provided on the game board 20 come into contact with the game nails provided on the game board 20 while changing the flow direction. Then, when the pachinko ball flowing down the game area 20a wins the start winning device 23, the symbol change effect on the symbol display device 18 is started based on the control of the control device. As a result of the symbol change effect, A big hit occurs when a predetermined symbol combination is displayed on the display device 18. When a big hit occurs, the special winning device 24 provided below the game board 20 is opened according to the symbol combination displayed on the symbol display device 18, and the symbol display device is controlled based on the control of the control device. A big hit game effect is performed at 18.

  The movable effect device 31 is operated based on a control signal from the control device in accordance with a symbol variation effect, a big hit game effect, or the like developed by the symbol display device 18, and the movable base body 60 or the second An operation effect is performed by rotating the first effect body 90 and the second effect body 100. In the movable effect device 31, the LEDs 66a, 71a, 78a of the LED boards 66, 68, 71, 78 are controlled in accordance with the symbol variation effect, the big hit game effect, and the like developed by the symbol display device 18. Light is emitted based on a control signal from the apparatus, and a light emission effect is performed.

  Here, the operation and light emission of the movable effect device 31 will be described. In the movable effect device 31, an annular member is slidably in contact with the inner surfaces of the front flat plate portion 35 and the rear flat plate portion 40 of the device main body 33 as the first drive motor 45 disposed in the device main body 33 is driven. 50 rotates. Therefore, since the annular member 50 to which the movable base body 60 is connected and fixed is restricted from being displaced forward and backward with rotation, the annular member 50 can be stably rotated on a certain plane. Thereby, the blurring of the movable base body 60 that rotates with the annular member 50 is suppressed, and the operational stability of the movable base body 60 is improved. Further, by improving the stability of the movable base body 60, the load applied to the connecting portion (specifically, the fixed recess 54a and the fixed protrusion 111) between the movable base body 60 and the annular member 50 is reduced. And damage to the connecting portion can be prevented. Further, by connecting the cylindrical connecting portion 110 of the movable base body 60 to the connecting hole 50a formed in the annular member 50, the movable member is connected to the end of the rod-shaped rotating shaft. The operational stability of the movable base body 60 can be improved as compared with the configuration in which the rotational operation is performed.

  Further, by adopting the first drive gear 47 and the second driven gear 86 made of spur gears as the drive transmission means for rotating the movable base body 60, it is not necessary to make the drive transmission means complicated. Here, when a gear is employed as the drive transmission means, it is difficult to avoid “play” in the drive transmission means due to the meshing relationship of the gears, and vibration is likely to occur during operation due to this “play”. . On the other hand, in the embodiment, the annular member 50 is slidably contacted with the inner surfaces of the front flat plate portion 35 and the rear flat plate portion 40 of the apparatus main body 33, so that the annular member 50 is stabilized on a certain plane. Therefore, it is possible to improve the operational stability by suppressing the shake and vibration of the movable base body 60. Further, in the annular member 50, a sliding cylinder part 53 is housed in a sliding support hole 37 formed in the front side flat plate part 35 of the apparatus main body 33, and the sliding cylinder part 53 is formed in the sliding support hole 37. By being configured so as to slide on the inner peripheral end surface, the annular member 50 can be restricted from moving in the radial direction when the first drive motor 45 is driven, and can be rotated at a fixed position. As described above, since the rotation center of the movable base body 60 is stabilized at a fixed position, the operational stability of the movable base body 60 can be further improved.

  Further, the cylindrical connecting portion 110 of the movable base body 60 is fitted into the connecting hole 50a of the annular member 50, and the cylindrical connecting portion 110 is formed with respect to the fixed recess 54a formed inside the connecting hole 50a. Since the annular member 50 and the movable base body 60 are connected and fixed in a state where the fixed protrusion 111 is fitted, the connection strength between the annular member 50 and the movable base body 60 is improved. Further, since the cylindrical connecting portion 110 of the movable base body 60 can be positioned in the circumferential direction with respect to the annular member 50, the unity between the annular member 50 and the movable base body 60 is improved, and the movable base The operational stability of the body 60 can be improved.

  Further, a first drive gear 47 and a first driven gear 48 made of spur gears are adopted as the drive transmission means, and a first position detection piece 55 formed to extend radially outward from the annular member 50. If the front-rear width of the first mechanism accommodating space 42 of the apparatus main body 33 is secured to a size corresponding to the thickness of the annular member 50, the first position detection sensor 56 detects the circle. The annular member 50 can be installed. That is, the apparatus main body 33 can be thinned, and the movable rendering device 31 (device main body 33) can be made compact. In the movable effect device 31 of the embodiment, the first drive motor 45 is also installed on the outer surface of the device main body 33 on the arrangement side of the movable base body 60 (the front surface of the front flat plate portion 35). The whole can be made more compact.

  Further, the movable base body 60 is provided so as to penetrate the movable shaft 85 at the center of the rotation support gear 84 in accordance with the driving of the second drive motor 81 disposed on the base body 61 of the movable base body 60. Since the first effect body 90 and the second effect body 100 are arranged at both projecting end portions of the movable shaft portion 85, the first effect body 90 and the first effect body 90 are driven by the driving of the second drive motor 81. Each of the two performance bodies 100 can be operated in an integrated manner. That is, since the first effect body 90 and the second effect body 100 can be rotated at a time as compared with the case where one movable member is attached to one rotation axis, It is possible to diversify the production mode and enhance the interest of the game production. In addition, since the first effect body 90 and the second effect body 100 are attached to one movable shaft portion 85, the mechanism necessary for operating the two effect bodies 90, 100 can be minimized. Further, it is possible to prevent the installation space of other game parts disposed on the movable base body 60 (base body 61) from being pressed.

  Further, the first effect body 90 and the second effect body 100 are connected to the second drive motor 81 by attaching each of the first effect body 90 and the second effect body 100 to both ends of the movable shaft portion 85 penetrating the center of the rotation support gear 84. The 1st effect body 90 and the 2nd effect body 100 can be arrange | positioned on both sides of the base main body 61 which accommodates 2 drive transmission means 83,84,85,86. That is, since the first effect body 90 and the second effect body 100 rotate with the base main body 61 (second drive transmission means 83, 84, 85, 86) interposed therebetween, it is possible to realize an unprecedented new operation mode. The decorativeness is improved by the device 31 and the production mode is diversified.

  Here, when the first drive motor 45 is driven, the movable base body 60 that rotates around the cylindrical connecting portion 110 (annular member 50) rotates the cylindrical connecting portion 110 (annular member 50). A first effect body 90 and a second effect body 100 that rotate about a movable shaft portion 85 extending in a direction intersecting the axis L1 are arranged, and the first effect body is driven by the drive of the second drive motor 81. 90 and the second effect body 100 are configured to rotate. That is, each of the first effect body 90 and the second effect body 100 is configured by appropriately combining the driving of the first drive motor 45 and the second drive motor 81 so that the cylindrical connecting portion 110 (the annular member 50). A combined and three-dimensional operation that combines the rotational operation of the movable base body 60 centered on the center and the rotational operation centered on the movable shaft portion 85 is realized. Can be diversified. The cylindrical connecting portion 110 (annular member 50) and the movable shaft portion 85 are connected to each other while the rotation axis L1 of the cylindrical connecting portion 110 (annular member 50) is orthogonal to the movable shaft portion 85. Since it is configured to pass through an intermediate position of the movable shaft portion 85, when the movable base body 60 rotates, the first effect body 90 and the second effect body 100 are positioned with the rotation center of the movable base body 60 in between. It is possible to realize complex and three-dimensional movement that rotates in a state where

  In the movable effect device 31, the front surface side of the second effect body 100 is covered with the decorative covering member 120 in a state where the movable base body 60 is in the first position, and the movable base body 60 is in the second position. The front surface side of the first effect body 90 is covered with the decorative covering member 120. That is, when the movable base body 60 is rotated to the first position and the second position in accordance with the driving of the first drive motor 45, the effect body exposed on the front side of the pachinko machine 10 is the first effect body 90 and It switches to the 2nd production body 100. Thus, the operation of the movable base body 60 accompanying the driving of the first drive motor 45 and the operations of the first rendering body 90 and the second rendering body 100 accompanying the driving of the second drive motor 81 are combined. In addition to the combined and three-dimensional operation, the effect body exposed on the front side of the game board 20 is switched, so that not only the decorativeness by the movable effect device 31 is further improved, but also the effect modes are diversified. It is done. In the embodiment, the design (first effect body 90, motor cover 65 and light emitting decoration cover 67) on the first flat plate portion 63 side of the movable base body 60 (base body 61), and the movable base body 60 (base body). 61) the design on the second flat plate portion 76 side (second effector 100 and cover member 104) has a completely different appearance, so that the effector exposed on the front side of the game board 20 is the first effector 90 and By switching to the second effect body 100, a completely different impression can be given to the player.

  Further, the first effect body 90 and the second effect body 100 covered with the decoration covering member 120 can be seen through from the front side of the game board 20 through the visible portion 122 provided on the decoration covering member 120. Therefore, the game board 20 can be decorated also by the first effect body 90 and the second effect body 100 covered with the decoration covering member 120. At this time, since the non-light transmitting portion 121 is formed on the decorative covering member 120, the decorative covering member 120 is compared with the first effect body 90 (second effect body 100) exposed directly on the front side of the game board 20. By reducing the visibility of the second effect body 100 (the first effect body 90) covered with the second effect body 100 (the first effect body 100 (the first effect body 90) covered with the decorative covering member 120 as the movable base body 60 rotates). It is possible to enhance the unexpectedness when the director 90) is directly exposed to the front side of the game board 20. In addition, since the decoration covering member 120 is positioned behind the game area 20a of the game board 20 formed in a transparent plate shape, an effect of improving the decoration of the game area 20a of the game board 20 can be expected.

  Further, the movable effect device 31 is provided with a first effector LED board 71 and a second effector LED board 78 corresponding to the first effector 90 and the second effector 100, respectively. Moreover, not only the first effect body 90 and the second effect body 100 rotate, but also a composite effect by light emission is possible, and the decoration effect / effect effect by the movable effect device 31 is further improved. In addition, the first reflecting surface 99 and the second reflecting surface 103 are provided corresponding to the first effect body 90 and the second effect body 100, respectively, and the first effect body 90 and the second effect body 100 are rotated. By configuring the irradiation direction of the reflected light to change rotationally, it is possible to further enhance the decoration effect / production effect by light emission. Further, in the first effect body 90, the irradiation direction of the light transmitted through the lens unit 96 (the light emitting part 95a) rotates and moves with the rotation of the first effect body 90, while in the second effect body 100, As the second effector 100 rotates, the irradiation position of the light reflected by the second reflecting surface 103 on the cover body 104 rotates. That is, by making the light emission effect modes different between the first effect body 90 and the second effect body 100, the effect modes using light emission can be diversified.

  In addition, when the first effect body 90 and the second effect body 100 are covered with the decorative covering member 120, the game area 20a of the game board 20 is illuminated and illuminated via the visible portion 122 of the decorative covering member 120. The movable effect device 31 can be used as illumination means for illuminating the game area 20a. That is, in the state where the movable base body 60 is in the first position, the front surface side of the second effect body 100 is covered with the decorative covering member 120, so that the LED for the second effect body corresponding to the second effect body 100 is provided. By turning on / flashing the LED 78a of the board 78, the game area 20a can be illuminated and illuminated by the reflected light from the second reflecting surface 103, and the first effect is produced when the movable base body 60 is in the second position. Since the front side of the body 90 is covered with the decorative covering member 120, the LED 71 a of the first effector LED substrate 71 corresponding to the first effector 90 is turned on / flashed, etc. The game area 20a can be illuminated with the reflected light. In addition, as described above, the light emitting effect modes of the first effect body 90 and the second effect body 100 are different, so that the game area 20a depends on whether the movable base body 60 is in the first position or the second position. It is possible to change the decorativeness of the (game board 20) by the light emitting illumination. Further, since the LED 71a of the first effector LED board 71 and the LED 78a of the second effector LED board 78 are configured to be able to emit and extinguish independently, the first effector 90 and the second effector It is possible to further diversify the production mode using 100 light emission. As described above, the rotation of the movable base body 60 and the rotation of the first effect body 90 and the second effect body 100 are appropriately combined, and the light emission of the first effect body 90 and the light emission of the second effect body 100 are further performed. By combining them, the variation of the effect by the operation using the movable effect device 31 and the light emission can be increased, and the effect of the effect can be remarkably improved.

  Further, a flat cable connected to the second drive motor 81, the first light emitting decoration LED board 66, the second light emitting decoration LED board 68, and the second effector LED board 78 disposed on the movable base body 60. 130 is wound around the wiring winding portion 112 of the cylindrical connecting portion 110 at a position of the rotation axis L1 of the movable base body 60 in a certain direction. Therefore, as the movable base body 60 rotates and moves to the first position and the second position, the winding portion of the flat cable 130 with respect to the wiring winding portion 112 is bent so as to contract and relax. Therefore, no load is applied to the flat cable 130 as the movable base body 60 rotates, so that the conductor inside the cable can be prevented from being disconnected, and the movable base body 60 can be repeatedly reciprocally rotated. In addition, since the flat cable 130 is fixed to each of the apparatus main body 33 (wiring pressing member 118) and the movable base body 60 (connecting connector 73) in the vicinity of the outside of the annular space 113, the rotation of the movable base body 60 is performed. Since the deformation of the cable accompanying this is limited to the inside of the annular space 113 (that is, the portion wound around the wiring winding portion 112), it is possible to prevent the load from being applied to an unexpected part of the flat cable 130, and to break the flat cable 130. It can be effectively prevented.

  Further, the flat cable 130 is wound in an annular space 113 defined between the wiring winding portion 112 and a cylindrical connecting portion 110 extending annularly outside the wiring winding portion 112. Therefore, the winding portion of the flat cable 130 that has been relaxed during the rotating operation of the movable base body 60 can always be accommodated in the annular space 113, and problems such as disconnection due to cable biting can be prevented. Further, a flat cable 130 wound around the wiring winding portion 112 is obtained by partially closing the rear opening of the annular space 113 with a disc-like cover member 115 provided at the extended end portion of the wiring winding portion 112. It can prevent falling off from the annular space 113. Here, since the wire winding portion 112 is configured to protrude rearward from the rear end portion of the cylindrical connecting portion 110, the flat cable 130 wound around the wire winding portion 112 is connected to the disk-shaped cover member 115. Can be led out of the annular space 113 through a gap between the cylindrical connecting portion 110 and the rear end portion of the cylindrical connecting portion 110. The disc-shaped cover member 115 is formed of a transparent synthetic resin plate, and the inside of the annular space 113 is visually observed without removing the disc-shaped cover member 115, so that the movable base body 60 can be rotated. The movement of the flat cable 130 accompanying the operation (contracting / relaxing) can be confirmed. Thereby, it is possible to improve the work efficiency of the check operation and the maintenance work of the rotation operation of the movable base body 60 in the movable effect device 31.

(Example of change)
Note that the configuration of the gaming machine according to the present invention is not limited to that shown in the above-described embodiments, and various modifications can be made.

(1) In the embodiment, two relative to the first movable body (movable base body) supported so as to be rotatable about the first rotation axis (rotation axis of the cylindrical connecting portion) with respect to the apparatus main body. The second movable body (the first effect body and the second effect body) is provided so as to be rotatable around the second rotation shaft (movable shaft portion). However, as long as at least one second movable body is provided. Good.
(2) In the embodiment, the axis along the first rotation axis and the axis along the second rotation axis are orthogonal to each other. However, the first rotation axis and the second rotation axis are inclined at a constant inclination. If configured to intersect, the rotation direction of the first movable body and the rotation direction of the second movable body can be made different, and an effect can be produced with a complicated operation.
(3) In the embodiment, the axis line along the first rotation axis is configured to be orthogonal at the intermediate position of the second rotation axis. However, the first axis is at a position that is radially deviated from the axis line along the first rotation axis. You may comprise so that 2 rotation shafts may be located. In this case, when the second rotation shaft rotates around the first rotation shaft, the second rotation shaft rotates around the axis along the first rotation shaft, so that it is possible to produce a complicated operation.
(4) The configuration of the drive transmission means connected to the first movable body and the second movable body is not limited to the configuration shown in the embodiment, and each of the first movable body and the second movable body is A link mechanism, a belt mechanism, and other conventionally known drive transmission means can be adopted as long as the structure rotates around the first rotation shaft and the second rotation shaft.
(5) In the embodiment, the front side of either one of the first effect body and the second effect is covered with the covering member (decoration covering member). You may make it visible from the player side (front side). Further, in the embodiment, the visible portion is formed on the decorative covering member so that the effect body covered with the decorative covering member can be partially visually recognized from the front side. May be.

(6) In the embodiment, the description has been given by taking as an example the configuration in which the movable effect device is disposed on the installation member installed on the back side of the game board. However, the movable effect device is attached to the frame-shaped decorative body disposed on the game board. The game board itself may be provided with a movable effect device. It is also possible to arrange a movable effect device on the front frame. In other words, the movable effect device can be installed at an appropriate position as long as the position is visible from the player side (front side) in the gaming machine.
(7) In the embodiment, the installation member is provided on the back side of the game board, but a configuration in which the installation member is installed in the middle frame as the main body frame can also be adopted.
(8) In the embodiment, the game board is made of a transparent plate, but the game board is not limited to this, and the game board may be formed opaque with plywood or a synthetic resin material.
(9) In the embodiment, a pachinko machine has been described as an example of the gaming machine. However, the present invention is not limited to this, and various gaming machines such as an arrangement ball machine, a pinball machine, and a slot machine machine can be adopted.

31 Movable rendering device 33 Device body 45 First drive motor (first drive means)
60 Movable base body (first movable body)
85 Movable shaft (second rotary shaft)
90 1st production (2nd movable body)
110 Cylindrical connecting part (first rotating shaft)

Claims (1)

In a gaming machine equipped with a movable production device that produces production by movement,
The movable effect device is:
An apparatus main body on which the first driving means is disposed;
A first movable body disposed in the apparatus main body and connected to the first driving means, and supported to be rotatable about the first rotation axis with respect to the apparatus main body;
The first movable body is connected to and connected to a second driving means provided on the first movable body, and is orthogonal to the axis along the first rotation axis with respect to the first movable body. and a second movable member which is rotatably supported about a second rotational axis of which the axis line extends in a direction,
An axis line along the first rotation shaft passes through an intermediate position of the second rotation shaft, and a first effect body as the second movable body is attached to one end of the second rotation shaft. And a second effect body as a second movable body is attached to the other end of the second rotation shaft,
The first movable body is configured to be capable of rotational displacement to a first position and a second position where the second effector is located at a stop position of the first effector at the first position;
The first effector on the front side of the second effector of the first movable body at the first position and on the front side of the first effector of the first movable body at the second position. And a covering member for covering the second effect body is provided,
The first effect body and the second effect body are configured to be exposed to the front side of the gaming machine by rotating and displacing the first movable body to the first position and the second position. A gaming machine characterized by

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