JP5384458B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine including 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 member (a so-called center accessory) arranged at a substantially central position of a gaming area defined on a board surface of a gaming board set in the machine. A symbol display device such as a liquid crystal type or a drum type is exposed from the opening of the member, and the symbol display device is configured to perform a game effect such as a symbol combination game or a reach effect. In addition, in the pachinko machine, a movable effect device provided with a movable body that performs a required operation is arranged on the decorative member, and the movable body is operated in accordance with a game effect performed by the symbol display device. The effect of the game is enhanced by improving the production effect (see, for example, Patent Document 1).

  In the movable effect device disclosed in Patent Document 1, the movable body is swingably disposed on the game board via a link mechanism, and the movable body swings on the front side of the symbol display device by driving a motor connected to the link mechanism. Configured to move.

JP 2003-190401 A

  In order to increase the impact of the production due to the operation of the movable body, a plurality of movable bodies are arranged on the game board. However, it is pointed out that the configuration in which a plurality of movable bodies are operated by dedicated link mechanisms or motors increases the number of parts and requires a large installation space. Further, in the pachinko machine, in the configuration in which each movable body is driven by an independent motor, it is necessary to control each motor with high precision in order to operate each movable body synchronously, and there is a drawback that the control burden increases. .

  That is, the present invention has been proposed to solve these problems in view of the problems inherent in the gaming machine according to the prior art, and a plurality of movable bodies can be provided without increasing the number of parts and the control burden. It is an object of the present invention to provide a gaming machine including a movable effect device that can operate.

In order to overcome the above-mentioned problems and achieve the intended purpose, the invention according to claim 1 of the present application provides:
In a gaming machine equipped with a movable production device (38) that produces production by movement,
The movable effect device (38)
A first actuating mechanism (91) connected to the driving means (120) and moving between the first position and the second position by the driving of the driving means (120);
A first movable body (88) connected to the first operating mechanism (91) and moving in accordance with the movement of the first operating mechanism (91);
As the first operating mechanism (91) moves between the first position and the second position, the first operating mechanism (91) comes into contact with and separates from the first position, and the first operating mechanism (91) is in contact with the first operating mechanism (91). A second actuating mechanism (93) that moves between the original position and the movable position;
A second movable body (89) connected to the second operating mechanism (93) and moving in accordance with the movement of the second operating mechanism (93);
Return means (152) for urging the second operating mechanism (93) toward the original position before the first operating mechanism (91) contacts;
The first actuating mechanism (91) is separated from the second actuating mechanism (93) in the first position, and the first actuating mechanism (91) has a contact position between the first position and the second position and a first position. The first operating mechanism (91) is configured to contact the second operating mechanism (93) while moving between the two positions.

  According to the first aspect of the present invention, it is possible to produce an effect with only one movable body or an effect with two movable bodies by one driving means within the range in which the first operating mechanism is moved. Can be implemented with fewer parts. In addition, since the two movable bodies can be operated by one driving means while the first operating mechanism and the second operating mechanism are in contact with each other, the number of parts can be reduced, the installation space can be reduced, and the control burden can be reduced. Can be reduced.

In the invention according to claim 2, the tracks of the first movable body (88) and the second movable body (89) are configured to partially overlap, and the first operating mechanism (91) When moving between two positions, the gist is that the first movable body (88) is configured to move at a position off the orbit of the second movable body (89).
According to the second aspect of the present invention, the first movable body and the second movable body can be operated without interference in a limited space.

In the invention according to claim 3, the second movable body (89) is located below the first movable body (88) positioned at the standby position at the first position of the first operating mechanism (91). ,
The first actuating mechanism (91) includes a pressing member (106) that linearly moves in the vertical direction by driving of the driving means (120), an apparatus main body (96) of the movable effect device (38), and a first A parallel link mechanism (108) linked to the first movable body (88) and supporting the first movable body (88) to translate, the pressing member (106) and the first movable body (88). ) And the first movable body (88) supported by the parallel link mechanism (108) with the linear movement of the pressing member (106) is moved to the standby position and the operation position obliquely downward from the standby position. An operating rod (107) that moves between
The second actuating mechanism (93) is arranged on the first member (149) that can move the pressing member (106) linearly in the vertical direction and the second movable body (89). And a second member (150) connected to the first member (149) via a connecting body (148) and linearly moving in the reverse direction with the movement of the first member (149). Have
When the first actuating mechanism (91) moves from the first position to the second position, the pressing member (106) contacts the first member (149) at the contact position and presses downward. The second movable body is moved up to a position aligned with the side of the first movable body (88) that has arrived at the operating position by moving the second member (150) upward via the connecting body (148). The gist is that (89) is configured to move.
According to the invention of claim 3, since the two movable bodies can be changed between a position where they are aligned vertically and a position where they are aligned horizontally, an interesting effect can be achieved.

  According to the gaming machine according to the present invention, a plurality of movable bodies can be operated without increasing the number of parts and the control burden.

1 is a front view showing a pachinko machine according to a preferred embodiment of the present invention. It is a front view which shows the game board which concerns on an Example. It is a vertical side view shown in the state which decomposed | disassembled the game board and back member which concern on an Example. It is a cross-sectional top view shown in the state which decomposed | disassembled the game board and back member which concern on an Example. It is a front view which shows the back member which concerns on an Example in the state which has each movable body of each movable production | presentation apparatus in a standby position. It is a front view which shows the back member which concerns on an Example in the state which has each movable body of each movable production | presentation apparatus in an operating position. It is the disassembled perspective view which looked at the 1st movable production device concerning an example from the front side. It is the disassembled perspective view which looked at the 1st movable production device concerning an example from the back side. It is the expansion exploded perspective view which looked at the movable member and the 1st linkage mechanism of the 1st movable production device concerning an example from the front side. It is the expansion exploded perspective view which looked at the movable member and the 1st linkage mechanism of the 1st movable production device concerning an example from the back side. It is the expansion disassembled perspective view which looked at the rolling bearing of the 1st movable production | presentation apparatus which concerns on an Example from the front side. It is a rear view which shows the 1st movable production | presentation apparatus which concerns on an Example in the state in which a 1st movable body is a standby position. It is AA sectional view taken on the line of FIG. 12, Comprising: A part of rolling bearing is abbreviate | omitted and shown. It is the BB sectional view taken on the line of FIG. It is CC sectional view taken on the line of FIG. It is the DD sectional view taken on the line of FIG. It is a principal part enlarged view which shows the arrangement | positioning site | part of the rolling bearing in FIG. It is a schematic front view which shows the 1st movable production | presentation apparatus which concerns on an Example in the state which removed the 1st cover member and the 1st movable body is a standby position. It is a schematic back view which shows the 1st movable production | presentation apparatus which concerns on an Example in the state which removed the 1st base member and the 1st movable body is a standby position. It is a rear view which shows the 1st movable production | presentation apparatus which concerns on an Example in the state in which a 1st movable body is an operation position. It is a schematic front view which shows the 1st movable production | presentation apparatus which concerns on an Example in the state which removed the 1st cover member and the 1st movable body is an operation position. It is a schematic back view which shows the 1st movable production | presentation apparatus which concerns on an Example in the state which removed the 1st base member and the 1st movable body is an operation position. It is the disassembled perspective view which looked at the 2nd movable production device concerning an example from the front side. It is the disassembled perspective view which looked at the 2nd movable production device concerning an example from the back side. It is the expansion exploded perspective view which looked at the 2nd drive part and the 2nd linkage mechanism of the 2nd movable production device concerning an example from the front side. It is the expansion exploded perspective view which looked at the 3rd drive part and the 3rd linkage mechanism of the 2nd movable production device concerning an example from the front side. It is the expansion disassembled perspective view which looked at the tilting 2nd movable body which concerns on an Example from the rear side. It is the expansion exploded perspective view which looked at the direct-acting 2nd movable object concerning an example from the back side. It is the expansion exploded perspective view which looked at the 2nd drive part and the 2nd linkage mechanism of the 2nd movable production device concerning an example from the back side. It is a schematic front view which shows the 2nd movable production device which concerns on an Example in the state in which a 2nd movable body is a standby position. It is the EE sectional view taken on the line of FIG. FIG. 6 is a schematic front view of the second movable effect device according to the embodiment, in which the first and second cover parts are removed, both the second movable bodies are indicated by imaginary lines, and both the second movable bodies are in the standby position. It is a schematic front view which removes a 2nd cover member and shows both 2nd movable bodies with an imaginary line, and shows both 2nd movable bodies in the state of a standby position about the 2nd movable production apparatus which concerns on an Example. It is a schematic front view which shows the 2nd movable production | presentation apparatus which concerns on an Example, removes a 2nd cover member, shows both 2nd movable bodies with an imaginary line, and the rack member contact | abutted to the 1st member. It is a schematic rear view which shows the relationship between a 2nd connection mechanism and a 3rd connection mechanism in the state which the rack member contact | abutted the 1st member for the 2nd movable production | presentation apparatus which concerns on an Example. FIG. 5 is a schematic front view of the second movable effect device according to the embodiment, in which the first and second cover parts are removed, both the second movable bodies are indicated by imaginary lines, and both the second movable bodies are in the operating position. It is a schematic front view which removes a 2nd cover member and shows both 2nd movable bodies with an imaginary line, and shows both the 2nd movable bodies in the state of an operation position about the 2nd movable production apparatus which concerns on an Example. It is a schematic back view which shows the relationship of a 2nd connection mechanism and a 3rd connection mechanism in the state which both 2nd movable bodies act | operate to the 2nd movable production apparatus which concerns on an Example. It is a schematic front view which shows the state which operated only the direct-acting 2nd movable body with the 3rd drive part in the state which removed the 1st and 2nd cover components about the 2nd movable production device which concerns on an Example.

  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 the embodiment, a pachinko machine that plays a game using a pachinko ball as a game ball will be described as an example. Further, in the following description, “front”, “rear”, “left”, and “right” are states when the pachinko machine is viewed from the front side (player side) as shown in FIG. 1 unless otherwise specified. It points at.

(About pachinko machines)
As shown in FIG. 1, the pachinko machine 10 according to the embodiment will be described later on the front side of the opening of the outer frame 11 as a fixed frame that is formed in a rectangular frame shape and fixed to an installation frame base (not shown) of the amusement store. A middle frame 12 as a body frame on which a game board 18 (see FIG. 2) is detachably held is assembled so as to be openable and detachable, and various symbols can be variably displayed on the back side of the game board 18. The symbol display device 13 is arranged to be detachable (see FIGS. 3 and 4). Further, a front frame 14 as a decorative frame provided with a glass plate that protects the game board 18 from seeing through is assembled on the front side of the middle frame 12 so as to be openable and closable, and a pachinko ball is stored below the front frame 14. The lower ball tray 15 is assembled so as to be openable and closable. In the embodiment, an upper ball tray 16 for storing pachinko balls is integrally assembled at a lower position of the front frame 14, and the upper ball tray 16 is also opened and closed integrally with the opening and closing of the front frame 14. Configured to do. Further, on the back side of the middle frame 12, a ball collection unit (not shown) is provided for discharging pachinko balls used for games to a ball collection facility provided on the game store side.

(About game board)
As shown in FIG. 2, the game board 18 disposed in the inner frame 12 has a game area 18a in which a pachinko ball can flow down on the front surface (board surface), and is made of a flat plate made of wood such as plywood. It consists of a plate member. A guide rail 20 formed in an arc shape is disposed on the front surface of the game board 18, and a first board surface decoration member formed in an arc shape whose left edge is recessed rightward at a right position of the guide rail 20. 21 is disposed. Then, a game area 18a is defined in a substantially circular shape by the guide rail 20 and the first board surface decoration member 21, and a pachinko ball launched from a not-shown hitting ball launcher disposed in the middle frame 12 in the game area 18a. Is launched into the game area 18a, and a pachinko ball flows down in the game area 18a to play a game. The pachinko ball launched from the ball striking device is guided by the guide rail 20 from the lower side to the left side of the game board 18 and is launched to the upper left part of the game area 18a. In addition, a large number of game nails are planted in the game area 18a of the game board 18, and the flow direction of the pachinko balls flowing down the game area 18a is irregularly changed by contact with the game nails. It is. In addition, on the board surface of the game board 18, second board surface decoration members 22 are respectively disposed at the upper and lower positions on the left side of the guide rail 20 (outside the game area 18 a).

  As shown in FIG. 1 or FIG. 2, the game board 18 has a first start winning device 23 and a first start winning device 23 that can win a pachinko ball flowing down the game area 18a below the lower edge of a decorative member 28 described later. 2. A start winning device 24, a special winning device 25, a gate 26 through which a pachinko ball can pass, and the like are arranged. The first and second start winning devices 23 and 24 are provided with a start winning opening through which a pachinko ball flowing down the game area 18a can win. Then, the pachinko ball that has won the start winning opening of the start winning devices 23 and 24 is detected by the start winning sensor (not shown), whereby the symbol variation is started on the display unit 13a of the symbol display device 13, and A predetermined number (for example, five) of pachinko balls are paid out to the upper and lower ball trays 15 and 16 as prize balls.

  In the special winning device 25, the winning opening is always closed by an open / close door, and as a result of the symbol variation in the symbol display device 13, a predetermined symbol combination (for example, the same symbol of the same symbol) is displayed on the display unit 13a of the symbol display device 13. When a symbol is stopped and displayed in a three-piece set, etc., a so-called `` big hit '' occurs, so that the door is opened and controlled so that a large number of prize balls can be obtained by winning a prize opening It has become. The second start winning device 24 includes an opening / closing member that closes the start winning port, and a control device (not shown) is triggered by the fact that the gate sensor provided in the gate 26 detects the passage of the pachinko ball. The lottery of whether to open the opening / closing member is performed. Note that reference numeral 27 in FIG. 2 indicates a normal winning device that is disposed on the game board 18 and that always opens the winning opening.

(About decorative members)
As shown in FIG. 3 or FIG. 4, a large through hole 18b penetrating in the front-rear direction is formed in the center of the game board 18, and a frame-shaped decorative member (opening in the front-rear direction with respect to the through-hole 18b) A so-called center accessory) 28 is detachably disposed so as to be fitted therein. And the display part 13a of the said symbol display apparatus 13 which faces from the opening part 32a of the back member 32 mentioned later is exposed to the front side of the game board 18 via the window (visible part) 28a opened to the front and back in the decoration member 28. The symbol variation effect developed on the display unit 13a of the symbol display device 13 can be viewed from the front side.

  As shown in FIGS. 2 to 4, the decorative member 28 is provided with an arc-shaped bowl-shaped portion 28 b that protrudes forward from the front surface of the game board 18 from the upper edge portion to the left and right edge portions. The pachinko ball launched into the game area 18a can be guided by the bowl-shaped portion 28b on the outer peripheral portion, and the pachinko ball 28b is restricted from flowing down across the window 28a of the decorative member 28 by the bowl-shaped portion 28b. Yes. The decoration member 28 is provided with a stage 29 below the window 28a, and a pachinko ball that opens to the game area 18a and flows down the game area 18a on the left side of the window 28a. A ball introducing portion 30 for guiding to 29 is provided, and the pachinko balls passed from the ball introducing portion 30 to the stage 29 roll left and right on the stage 29, and then each of the winning devices 23, 24, 25, 27 is discharged to the game area 18a in which 27 is disposed.

  A transparent wall 31 rising at a predetermined height is provided on the rear end edge of the stage 29 over the entire length in the left-right direction, and pachinko balls that roll on the stage 29 are displayed on the symbol display device 13. The transparent wall 31 prevents movement toward the portion 13a. In addition, an overhanging portion 31a is formed on the upper end edge of the transparent wall 31 so as to project forward, so that the pachinko ball can be reliably prevented from moving toward the display portion 13a by the overhanging portion 31a. It has become.

(Back material)
As shown in FIGS. 3 to 6, the symbol display device 13 is detachably disposed on the back surface of the game board 18, and movable presentation devices 37, 38, 39, which will be described later, a plurality of light emitting substrates, A back member 32 made of a synthetic resin material on which game parts are placed is provided, and the display unit 13a of the symbol display device 13 is played through the opening 32a that is formed in the back member 32 and opens in the front-rear direction. It is configured to be visible from the front side of the panel 18. In the embodiment, the opening 32a of the back member 32 is opened in a substantially square shape defined by the upper side, the lower side, the left side, and the right side, and the display unit 13a of the symbol display device 13 is visible from the opening 32a. Therefore, the edge of the opening 32a is the outer edge of the display unit 13a.

  As shown in FIGS. 3 to 6, the back member 32 is formed at a box-like main body 33 formed in a rectangular box shape opening forward, and an opening front end portion of the box-like main body 33, and the box-like main body is formed. 33 is formed of an attachment portion 34 that extends to the outside of the opening 33 and contacts the back surface of the game board 18. The box-shaped main body 33 opens forward from a facing surface portion 35 formed in a rectangular plate shape facing the game board 18 and an image wall portion 36 extending forward from each of the upper, lower, left and right edges of the facing surface portion 35. The attachment portion 34 is formed so as to extend from the front end portion of each wall portion 36 toward the outside of the opening of the box-shaped main body 33. Then, the back member 32 is fixed to the game board 18 by screwing the attachment part 34 to the game board 18 with the front surface of the attachment part 34 being in contact with the back surface of the game board 18.

  As shown in FIGS. 3 and 4, the opposed surface portion 35 is formed with the large opening portion 32 a that opens most of the vertical and horizontal widths. In the following description, the portions of the facing surface portion 35 that are located on the top, bottom, left, and right of the opening 32a are referred to as an upper facing surface portion 35a, a lower facing surface portion 35b, a left facing surface portion 35c, and a right facing surface portion 35d, respectively.

  With the back member 32 attached to the back side of the game board 18, a required space is defined between the facing surface portion 35 of the back member 32 and the game board 18. As shown in FIGS. 5 and 6, the first movable effect device 37 is disposed on the left facing surface portion 35 c and the second movable effect device 38 is disposed on the right facing surface portion 35 d of the facing surface portion 35 of the back member 32. The third movable effect device 39 is disposed on the lower facing surface portion 35b. These three movable effect devices 37, 38, 39 are accommodated in the spaces defined between the back member 32 and the game board 18, respectively.

(About the first movable effect device)
As shown in FIGS. 5 and 6, the first movable effect device (movable effect device) 37 is installed on the left facing surface portion 35 c of the back member 32. As shown in FIGS. 7, 8, 13, and 14, the first movable effect device 37 includes a first base member 40 that serves as an installation base of members constituting the first movable effect device 37, and a predetermined effect. A movable member 41 that performs an operation, a first drive unit (drive unit) 42 that reciprocates the movable member 41, a first movable body (movable body) 43 that performs a predetermined rendering operation, and a reciprocating motion of the movable member 41 The first connecting mechanism (linking mechanism) 44 that reciprocates the first movable body 43 in conjunction with the first movable member 43 and the first cover member 45 that covers the front side of the first base member 40 are basically configured. The first movable effect device 37 is a case-shaped first device main body that houses the first transmission unit 46 of the first drive unit 42 and the support mechanism of the movable member 41 from the first base member 40 and the first cover member 45. 47 is configured, and can be attached to and detached from the back member 32 including the movable member 41, the first movable body 43, the first linkage mechanism 44, and the first drive unit 42 in units of the first device main body 47. It has a simple unit structure. Further, as shown in FIG. 5, the first movable effect device 37 includes a first device main body 47 arranged outside the left side (third side) of the display unit 13a of the symbol display device 13, and the first device. From the right side of the main body 47, an arm 53 (described later) on which the first movable body 43 of the movable member 41 is disposed faces the outside of the first device main body 47. And in the 1st movable production | presentation apparatus 37, the arm part 53 is located in the front side of the upper opposing surface part 35a of the back member 32, and retracted to the outer side of the upper side (1st side) in the display part 13a (refer FIG. 5). ) And the operating position (refer to FIG. 6) that is displaced downward from the standby position and faces the front side of the display portion 13a (substantially the middle in the vertical direction of the display portion 13a). ing.

  As shown in FIGS. 7, 8, 9 and 10, the first base member 40 opens forward from the peripheral edge of the plate-like portion that contacts the left facing surface portion 35c of the back member 32. It is a box-shaped body and is formed from a transparent synthetic resin material. As shown in FIGS. 7 and 8, the first cover member 45 is a box-like body that opens to the rear from the peripheral edge of the plate-like portion that can cover the front opening of the first base member 40 and rises backward. It is made of a transparent synthetic resin material. Then, the wall of the first cover member 45 is brought into contact with the wall of the first base member 40 and both the members 40, 45 are screwed and fixed, thereby defining a space for accommodating the first transmission portion 46, the support mechanism, and the like. The formed first device main body 47 is configured (see FIG. 13).

  As shown in FIG. 14, the arm portion of the movable member 41 is provided between the first base member 40 and the first cover member 45 on the right side (the side on the display unit 13 a side) of the first device main body 47. A movable body insertion port 47a through which 53 is inserted is defined. The movable body insertion port 47a has a longitudinal dimension set slightly larger than the longitudinal dimension of the arm portion 53, and the vertical dimension is set to a width that allows the vertical displacement of the arm portion 53, and is inserted into the movable body insertion port 47a. It is possible to suppress the shaking in the front-rear direction while allowing the vertical displacement of the arm portion 53. The left side of the first apparatus main body 47 is disposed at the left end opposite to the extending side of the arm 53 in the movable base 52 between the first base member 40 and the first cover member 45. A guide port 47b for inserting and guiding the guide member 52a is defined with a predetermined length in the vertical direction (see FIGS. 16 and 17), and the front and rear movement of the movable member 41 is caused on both the left and right sides of the first device main body 47. Configured to suppress. Furthermore, as shown in FIG. 14 or FIG. 18, the first base member 40 has a movable member 41 facing the standby position on the front side of the upper end of the extending portion 40a extending to the right side from the right end edge of the first cover member 45. A restricting member 48 for restricting the forward movement of the arm portion 53 is disposed on the front side of the arm portion 53. The restricting member 48 has a parallel portion 48a facing in parallel with the front and rear dimensions of the arm portion 53 in front of the extending portion 40a, and is inclined so as to be separated from the extending portion 40a as it goes downward from the parallel portion 48a. And an inclined portion 48b. When the movable member 41 moves from the operating position to the standby position, the inclined portion 48b can smoothly guide the arm portion 53 between the parallel portion 48a and the extending portion 40a. Is done.

  The first apparatus main body 47 includes a magnet 49 as a magnetic attraction member that assists in stopping the movable member 41 at the standby position (see FIG. 13). In the embodiment, a permanent magnet is employed as the magnet 49. The magnet 49 is installed on the upper side of the first apparatus main body 47 and is positioned above the movable base 52 described later of the movable member 41. That is, as shown in FIG. 13, a magnet accommodating portion 40b that opens forward is formed on the upper wall of the first base member 40, and the magnet 49 accommodated in the magnet accommodating portion 40b is located in front of the magnet accommodating portion 40b. The lid member 50 that closes the opening is held in the magnet housing portion 40b. In addition, an opening is provided in the lower part of the magnet housing part 40b, and the lower surface of the magnet 49 housed in the magnet housing part 40b is configured to be exposed in the first device main body part 47 through the lower opening. .

  The movable member 41 extends from the movable base 52 in a lateral direction that intersects the movement allowable direction of the rolling bearing 51 on the movable base 52 and a movable base 52 serving as a mounting portion for the rolling bearing 51 as a support mechanism. And an arm portion 53 formed so as to do so (see FIGS. 18 and 19). The movable member 41 has a movable base 52 disposed inside the first device main body 47, and the arm portion 53 extends from the first device main body 47 located on the left side of the display unit 13a of the symbol display device 13. The first movable body 43 can be reciprocated in the left-right direction (the direction along the upper side of the display portion 13a) on the arm portion 53 through the movable body insertion port 47a. It is arranged. In the movable member 41, the arm portion 53 extends in the horizontal direction from the left side of the upper end of the movable base 52, and as a whole, has a bowl shape along the upper side and the left side of the display unit 13a (see FIG. 5). . The movable member 41 of the embodiment is formed by integrating a movable base 52 and a front support portion 55 (described later) of the arm portion 53 (see FIGS. 9 and 10). In the embodiment, the movable base 52 is provided. A portion extending rightward from the right edge extending in the vertical direction is referred to as an arm portion.

  A metal piece 54 is attached to the upper end of the movable base 52 as a member to be magnetized (see FIGS. 13 and 19). The metal piece 54 is installed facing the magnet 49 provided in the first apparatus main body 47 in an up-and-down relationship. The metal piece 54 faces the magnet 49 at the standby position of the movable member 41, and the magnet 49 It is configured to assist holding the movable member 41 at the standby position by magnetically attracting the metal piece 54. The metal piece 54 has a plate-like attachment portion screwed to the movable base 52 and a piece portion protruding upward from the attachment portion, as shown in FIG. 13, of the magnet accommodating portion 40b in the magnet 49. It is configured to face the lower surface exposed from the lower opening, and the one part is magnetically attracted to the magnet 49.

(About the arm)
The arm portion 53 includes a front support portion 55 formed integrally with the movable base portion 52, and a rear support portion 56 fixed to the back side of the front support portion 55 with screws. A storage space S extending in the left-right direction is defined therebetween (see FIGS. 15 and 16). Note that the left end portions of the front support portion 55 and the rear support portion 56 constitute the upper portion of the movable base portion 52, and the accommodation space S is also formed across the arm portion 53 and the movable base portion 52. The accommodation space S opens at the right end portion of the arm portion 53 and the left end portion of the movable base portion 52, and the lower portion of the accommodation space S opens between the movable base portion 52 and the arm portion 53. The first operating rod 79, which will be described later, is allowed to pass through the housing space S (see FIG. 13).

  In the housing space S, a movable connecting member 78 (to be described later) constituting the first linkage mechanism 44 is disposed so as to be movable in the left-right direction. Further, between the front and rear support portions 55 and 56 (within the accommodation space S), a guide roller 57 that can roll while contacting the upper surface or the lower surface of the movable connecting member 78 at a vertical position sandwiching the movable connecting member 78. , 57 are disposed at two positions separated in the left-right direction, and the movable connecting member 78 smoothly moves between the standby position and the operating position along the left-right direction with respect to the arm portion 53 by the plurality of guide rollers 57. It is configured to be movable (see FIGS. 7, 9, and 10).

  As shown in FIGS. 9 and 10, a long hole 55a penetrating in the front-rear direction is formed in the front support portion 55 so as to extend in the left-right direction, and the first movable body 43 is movable in the long hole 55a. A protrusion 75 (described later) that connects the connecting member 78 is inserted. The rear support 56 is formed with a plurality of holes 56a penetrating in the front-rear direction so as to be spaced apart in the left-right direction at a position facing the rear of the long hole 55a. The positions where the holes 56a are formed in the rear support portion 56 are such that when the first movable body 43 (movable connecting member 78) is positioned at a predetermined position in the left-right direction (hereinafter referred to as an attaching / detaching position), It is set to align to the side (see FIG. 12). In the embodiment, the attachment / detachment position and the standby position of the first movable body 43 are set to be the same, but may be set to different positions.

(About rolling bearings)
As shown in FIG. 17, the rolling bearing 51 includes an outer receiving portion 58 fixed to the first cover member 45, an inner receiving portion 59 fixed to the movable base portion 52 of the movable member 41, A middle receiving portion that is positioned between the outer receiving portion 58 and the inner receiving portion 59 and holds the plurality of rolling elements 60 that are in contact with the outer receiving portion 58 and the inner receiving portion 59 so as to roll apart from each other in the vertical direction. 61. The intermediate receiving part 61 is supported by the rolling element 60 so as to be reciprocable in the vertical direction with respect to the outer receiving part 58, and the inner receiving part 59 is reciprocated in the vertical direction by the rolling element 60 with respect to the intermediate receiving part 61. The movable member 41 which is supported so as to be movable and is fixed to the inner receiving portion 59 with respect to the outer receiving portion 58 is supported so as to be capable of reciprocating in the vertical direction. In the embodiment, the outer receiving portion 58, the inner receiving portion 59 and the inner receiving portion 61 are all formed of a metal material, and a metal ball is used as the rolling element 60, and a so-called ball bearing structure is adopted as the rolling bearing. Has been.

  As shown in FIG. 19, the outer receiving portion 58 is disposed so as to be biased toward the right end edge of the first cover member 45 on the display portion 13 a side and extend in the vertical direction. As shown in FIG. 11, the outer receiving portion 58 functions as a rail for guiding the intermediate receiving portion 61, and the outer receiving portion 58 is on both the left and right sides of the outer plate-like body 58 a that is a contact portion with the first cover member 45. The outer holding pieces 58b are formed in a substantially U-shape that opens rearward on a flat cross section that extends toward the rear side at the edge (see FIG. 17). Each outer holding piece 58b is formed in a curved shape having a convex outer side, and the surface facing the other outer holding piece 58b has a concave shape matching the outer shape of the rolling element 60.

  Further, as shown in FIG. 11, the outer plate-like body 58a of the outer receiving portion 58 is provided with a plurality of positioning holes 58c that are spaced apart in the vertical direction and penetrate in the front-rear direction, and the outer plate-like body 58a. The upper and lower end portions are respectively formed with regulating pieces 58d bent rearward. The outer receiving portion 58 is vertically and horizontally restricted with respect to the first cover member 45 by inserting each positioning pin 45a provided on the first cover member 45 into the corresponding positioning hole 58c. It is attached in a state (see FIG. 13). Further, as shown in FIG. 13, the upper cover provided on the first cover member 45 is disposed at the protruding end (rear end) of the upper (one end) regulating piece 58 d of the outer receiving portion 58 attached to the first cover member 45. The joint portion (engagement portion) 45b is engaged, and movement of the upper end portion of the outer receiving portion 58 to the rear is restricted. Furthermore, a fixing member 62 that is detachably screwed to the first cover member 45 is engaged and held from the rear side with respect to a lower (other end) regulating piece 58d in the outer receiving portion 58. The positioning pin 45 a protruding from the first cover member 45 is inserted into the positioning hole 58 c of the outer receiving portion 58, and the rearward projecting dimension of the outer receiving portion 58 is moved to the outer receiving portion 58. It is set so as not to interfere with the intermediate receiving portion 61 that is supported. The upper and lower restricting pieces 58d, 58d are capable of restricting the upward movement beyond the restricting piece 58d on the upper side of the inner receiving portion 61 and the inner receiving portion 59 disposed between the outer holding pieces 58b, 58b. Also, it has a function of regulating the downward movement beyond the regulating piece 58d on the lower side of the inner receiving portion 61 and the inner receiving portion 59.

  As shown in FIG. 11, the intermediate receiving portion 61 functions as a rail for guiding the inner receiving portion 59, and is arranged on the opposite side edge of the intermediate plate-like body 61 a facing the outer plate-like body 58 a of the outer receiving portion 58. A plurality of middle holding pieces 61b extended to the side are provided, and the plurality of middle holding pieces 61b are arranged apart from each other in the extending direction of the side edges. In the intermediate receiving portion 61, each intermediate holding piece 61b is provided along the longitudinal side of the plate-like body, and the longitudinal side extends vertically between the left and right outer holding pieces 58b, 58b in the outer receiving portion 58. Each middle holding piece 61b is disposed in a state of facing the corresponding outer holding piece 58b. Moreover, the center part 61 of the center receiving part 61 protrudes in the convex shape to the rear side, and this protruding part 61c is formed over the up-down direction.

  As shown in FIG. 11, each of the middle holding pieces 61b is provided with a circular middle holding hole 61d having a diameter smaller than the diameter of the rolling element 60, and the middle holding piece 61b and the outer holding piece opposed thereto. A part of the rolling element 60 disposed between the intermediate holding hole 58b and the intermediate holding hole 61d is rotatably accommodated in the middle holding hole 61d (see FIG. 17). That is, the rolling element 60 is restricted from moving in the left-right direction by the outer holding piece 58b and the middle holding piece 61b, and is rotatable while being restricted from moving in the vertical direction from the middle holding piece 61b by the middle holding hole 61d. It has become. Note that a part of the rolling element 60 rotatably accommodated in the middle holding hole 61d with respect to the middle holding piece 61b protrudes inside the middle holding piece 61b. The intermediate receiving portion 61 is set so that its vertical dimension is shorter than the vertical dimension of the outer receiving portion 58 and is supported between the left and right outer holding pieces 58b, 58b via the left and right rolling elements 60. 58 is configured to be reciprocally movable in the vertical direction between the upper and lower restricting pieces 58d, 58d. The intermediate receiving portion 61 has stop protrusions 61e projecting on the rear side at the upper end portion and the lower end portion of the raised portion 61c, and is disposed between the intermediate holding pieces 61b and 61b. The vertical movement of the receiving part 59 beyond a predetermined width is restricted by the stop protrusions 61e and 61e.

  In the inner receiving portion 59, inner holding pieces 59b are formed on both side edges of the inner plate-like body 59a opposite to the intermediate plate-like body 61a facing the inner receiving portion 61 so as to extend forward, respectively. It is formed in a substantially U shape that opens forward (see FIG. 17). As shown in FIG. 11, each inner holding piece 59 b is provided across the longitudinal side of the inner plate-like body 59 a, and the inner receiving part 59 has a longitudinal length between the left and right middle holding pieces 61 b and 61 b. The inner holding pieces 59b are arranged in such a manner that the sides extend vertically and the inner holding pieces 59b face the corresponding inner holding pieces 61b. The inner receiving portion 59 is set so that its vertical dimension is shorter than the vertical dimension of the middle receiving portion 61. The inner receiving portion 59 is formed in a curved shape in which each inner holding piece 59b is convex toward the other inner holding piece 59b, and the outer surface facing the inner holding piece 59b is matched to the outer shape of the rolling element 60. It is concave. The inner receiving part 59 has a portion facing the inner side of the inner holding piece 61b through the inner holding hole 61d of the rolling element 60 within the outer surface of the inner holding piece 59b, and the rolling part 60 and the raised part 61c of the inner receiving part 61 The inner holding piece 59b is sandwiched between the two. That is, the inner receiving portion 59 is supported by the rolling element 60 and the raised portion 61 c of the intermediate receiving portion 61 so as to be movable in the vertical direction while being restricted from moving in the left-right direction, and moves up and down with respect to the outer receiving portion 58. The inner receiving portion 59 is configured to be vertically movable with respect to the intermediate receiving portion 61 independently of the possible intermediate receiving portion 61. Note that the end of the screw portion of the screw that fixes the inner receiving portion 59 to the movable base portion 52 projects forward at the upper end portion and the lower end portion of the inner plate-like body 59a, and this screw portion is the stop of the intermediate receiving portion 61. The contact of the protrusions 61e and 61e restricts the upward or downward movement.

  9 and 10, the first base member 40 of the first device main body 47 is formed with a wiring opening 40c penetrating in the front-rear direction so as to extend in the vertical direction. A wiring connected to a first light emitting substrate 73 (described later) provided in the arranged first movable body 43 is configured to be drawn out to the rear side through the wiring opening 40c. The wiring opening 40c is set to be wide on the upper side and narrow on the lower side. Further, on the back surface of the first base member 40, a wiring holder 63 for holding the wiring is rotatably disposed at a position corresponding to the narrow portion of the wiring opening 40c (see FIG. 12).

(About the first drive unit)
The first drive unit 42 connects a first motor (motor) 64 serving as a drive unit with the first motor 64 and the movable base 52 of the movable member 41 to rotate the first motor 64. It is comprised from the 1st transmission part 46 converted into operation | movement. In the embodiment, a stepping motor that is driven or stopped under the control of the control device is used as the first motor 64. The first motor 64 is attached to the rear surface of the first base member 40 (see FIG. 12) and faces a left-side recess (not shown) that is recessed in the left facing surface portion 35c of the back member 32. The first motor 64 is biased and arranged on the left end edge side of the first base member 40 that is spaced from the display portion 13a, and is biased and arranged on the right end edge side of the first device main body 47. It is located on the opposite side of the display part 13a with the outer receiving part 58) in between. The rear surface of the first base member 40 is formed with a motor mounting recess 40d that opens to the rear side, and the first motor 64 is in a state where the front portion of the first motor 64 is accommodated in the motor mounting recess 40d. Attached to the base member 40, the output shaft of the first motor 64 protrudes into the first device main body 47 through a through hole formed in the first base member 40.

  The first transmission unit 46 includes a drive gear 65 fixed to the output shaft of the first motor 64, a driven gear 66 that meshes with the drive gear 65, a pinion 67 that meshes with the driven gear 66, and a movable base 52. A rack and pinion structure that is provided on the left edge (side edge of the first motor side) and meshes with the pinion 67 and converts the forward / reverse rotation of the pinion 67 into a linear motion of the movable base 52. (See FIG. 11). The drive gear 65, the driven gear 66, and the pinion 67 are provided on the arm portion 53 with the rolling bearing 51 disposed in the first apparatus main body 47 as shown in FIGS. It is provided on the side opposite to the extending side. That is, the first drive unit 42 is provided with the first motor 64 and the first transmission unit 46 on the opposite side of the extending side of the arm 53 and the rolling bearing 51 in the movable member 41, so The drive part 42 can operate the movable member 41 stably without interfering with the operation of the arm part 53.

  The first movable effect device 37 includes the movable member 41 (including the weight of the first movable body 43) by the mechanical holding torque of the first motor 64 itself when the first motor 64 is stopped (when no power is supplied). ) Is supported via the first transmission portion 46, and the movable member 41 can be stopped at the standby position. That is, in the first movable effect device 37, the movable member 41 can be held at the standby position only by the holding torque when the first motor 64 is stopped, and is movable by the magnetic force adsorption between the magnet 49 and the metal piece 54. The structure of holding the member 41 at the standby position is an auxiliary means. In this way, the first movable effect device 37 is provided with auxiliary holding means by the magnet 49 and the metal piece 54 even when vibration of the game board 18 or other unscheduled force is applied to the movable member 41. Therefore, the movable member 41 can be prevented from descending from the standby position.

  The first movable effect device 37 includes first detection means 69 that is installed at an upper end portion of the first cover member 45 and includes a photosensor that determines the position of the movable member 41, and the first detection means 69 includes The detection signal is input to the control device by being electrically connected to the control device. The first detection means 69 determines the position of the movable member 41 (movable base 52) depending on the presence or absence of the first detection piece 70 of the movable member 41 arranged so as to pass between the opposing detection parts in the first detection means 69. It comes to judge. The first detection piece 70 is provided at the upper end of the movable base 52 in the movable member 41, and is set so that the first detection piece 70 is positioned between the detection parts of the first detection means 69 at the standby position of the movable member 41 ( 18), the movable member 41 in the standby position can be confirmed by the detection of the first detection piece 70 by the first detection means 69.

(About the first movable body)
The first movable body 43 movably disposed on the arm portion 53 of the movable member 41 is a right end portion of the arm portion 53 at the standby position of the movable member 41, and is substantially in the horizontal direction on the upper side of the display portion 13a. It is held at the standby position outside the upper side at the center, and extends in the left-right direction along the upper side (see FIG. 5). As will be described later, the first movable body 43 translates toward the left end portion of the arm portion 53 in conjunction with the movement of the movable member 41 from the standby position to the operating position (see FIGS. 6 and 21). The display unit 13a is configured to reach the operating position biased to the left side at the approximate center in the vertical direction. The first movable body 43 is located in the window 28a of the decorative member 28 at the standby position and the operating position, and is configured to be visible from the front side (see FIGS. 2 and 3).

  As shown in FIGS. 7 and 8, the first movable body 43 includes a decorative cover body 71 located on the forefront, and a synthetic resin not disposed on the back side of the decorative cover body 71. It is basically composed of a reflecting plate 72 made of a material and a first light emitting substrate 73 disposed on the back side of the reflecting plate 72. The decorative cover body 71 is formed with a first pattern 43 a such as characters and figures that match the motif of the pachinko machine 10. In the embodiment, the decorative cover body 71 is formed of a light-transmitting synthetic resin material, and the surface of the portion excluding the first pattern 43a is subjected to plating or the like, so that only the portion of the first pattern 43a is present. It is configured to have optical transparency. On the front surface of the first light emitting substrate 73, a plurality of LEDs 73a as light emitters are disposed corresponding to the first pattern 43a, and the reflector 72 is passed through in the front-rear direction corresponding to each LED 73a. A hole 72a is formed. And in the state which screwed the 1st light emission board | substrate 73 to the back surface of the reflecting plate 72, LED73a corresponding to each through-hole 72a faces, and it is comprised so that the 1st design 43a may be brightened by light emission of this LED73a. In addition, the first symbol 43a of the embodiment forms a meaningful series of symbols with the symbols 88a and 89a formed on the second movable members 88 and 89 described later, and is further formed on the third movable member 154. The symbols 154a are combined to form a meaningful series of symbols. A light diffusion sheet 74 that diffuses the light from the LED 73a is interposed between the decorative cover body 71 and the reflection plate 72 at a position corresponding to the first pattern 43a.

  As shown in FIG. 8, a plurality of protrusions 75 are formed on the back surface of the reflecting plate 72 so as to be spaced apart in the left-right direction (the moving direction of the first movable body 43). Are provided so as to protrude rearward of the first light emitting substrate 73, and screw holes 75a are formed in the respective protrusions 75 so as to open rearward. In the embodiment, three protrusions 75 are provided apart from each other in the left-right direction, and two of the protrusions 75 and 75 located on the first device main body 47 side of the front support portion 55 in the arm portion 53 are provided. The long hole 55a is movably inserted. A plurality of sliding members 76 are disposed in the lower part of the back surface of the reflecting plate 72 so as to be spaced apart in the left-right direction, and each sliding member 76 is configured to slidably contact the front surface of the arm portion 53. . The sliding member 76 has an end that contacts the arm portion 53 protruding rearward from the first light emitting substrate 73 and is formed in an arc shape to prevent the arm portion 53 from contacting the first light emitting substrate 73. The contact area is minimized. The sliding member 76 is made of a resin material having a small friction coefficient so that the sliding resistance with the arm portion 53 is further reduced. In addition, a movement restricting member that prevents the wiring from extending above the first movable body 43 in cooperation with a wiring cover 86 (described later) disposed on the arm portion 53 is provided on the upper surface of the back surface of the reflecting plate 72 (FIG. (Not shown) extends in the left-right direction.

(About the first linkage mechanism)
The first linkage mechanism 44 includes a movable connecting member 78 fixed to the first movable body 43, a first operating rod 79 that connects the movable connecting member 78 and the movable member 41, and the first operating rod 79. Is basically composed of a cam groove 84 that swings in conjunction with the operation of the movable member 41. As shown in FIGS. 15, 19, and 22, the movable connecting member 78 is supported in the housing space S of the arm portion 53 so as to be movable in the left-right direction via the plurality of guide rollers 57. The movable connecting member 78 is formed with through holes 78a penetrating in the front-rear direction at positions corresponding to the three protrusions 75 provided on the reflection plate 72 of the first movable body 43. The screw 80 inserted from the rear side is screwed into the screw hole 75a of the corresponding protrusion 75, so that the movable connecting member 78 and the first movable body 43 are detachably fixed and can be moved integrally. The In the embodiment, as shown in FIGS. 19 and 22, one through-hole is formed at the right end portion extending rightward from the accommodation space S in both the standby position and the operating position of the first movable body 43 in the movable connecting member 78. 78a is drilled, and two through holes 78a and 78a are drilled at a portion facing the accommodation space S in both the standby position and the operating position of the first movable body 43. And when the 1st movable body 43 is located in an attachment or detachment position, each of the two through-holes 78a and 78a which faces in the accommodation space S is on the front side of the corresponding hole 56a of the rear support part 56 in the arm part 53. The screw 80 can be attached and detached from the rear side through the hole 56a (see FIG. 12).

  As shown in FIG. 10, a boss portion 78b protruding rearward is provided at the left end portion of the movable connecting member 78, and the first roller body 81 is rotatably disposed on the boss portion 78b. The first roller body 81 includes a bearing portion 81a through which the boss portion 78b is rotatably inserted, and a flange 81b formed at the rear end of the bearing portion 81a and extending in the radial direction. The first operating rod 79 has a lower end (one longitudinal end) pivotally supported by the movable base 52 of the movable member 41 via a holding member 82 and an upper end side (longitudinal) of the first operating rod 79. On the other end side in the direction, an engagement hole 79a penetrating in the front-rear direction extends a predetermined length in the longitudinal direction. The first operating rod 79 is connected to the movable connecting member 78 in a state where the bearing portion 81a of the first roller body 81 is rotatably inserted into the engagement hole 79a. Note that the upper end portion of the first operating rod 79 is located between the movable connecting member 78 and the flange 81b of the first roller body 81, and displacement in the front-rear direction is restricted. Further, a boss portion 79b protruding rearward is provided at an intermediate position in the longitudinal direction of the first operating rod 79, and a second roller body 83 is rotatably disposed on the boss portion 79b. The second roller body 83 includes a bearing portion 83a through which the boss portion 79b is rotatably inserted, and a flange 83b formed at the front end of the bearing portion 83a and extending in the radial direction.

  As shown in FIG. 9, the cam groove 84 extending in the vertical direction is formed on the front surface (the surface facing the first cover member 45) of the first base member 40 in the first apparatus body 47. A bearing portion 83a of a second roller body 83 disposed on the first operating rod 79 is movably inserted into the cam groove 84. The cam groove 84 is connected to the lower end of the linear portion 84a extending in parallel with the moving direction of the movable member 41, and protrudes to the left (side away from the display portion 13a) as it goes downward. And a curved portion 84b that is curved. As the movable member 41 reciprocates, the second roller body 83 of the first operating rod 79 is guided along the curved portion 84b of the cam groove 84, so that the first operating rod 79 swings with the lower end as a fulcrum. The movable connecting member 78 is configured to reciprocate in the left-right direction. That is, the first movable body 43 fixed to the movable connecting member 78 is configured to translate in the left-right direction along the arm portion 53 as the movable member 41 reciprocates. Here, the first movable body 43 that moves in conjunction with the operation of the movable member 41 is combined with the vertical movement and the horizontal movement to obtain a standby position in the horizontal center on the upper side of the display unit 13a. Then, it translates diagonally between the vertical operating center biased to the left side of the display unit 13a. Note that the curvature on the lower side of the curved portion 84b of the cam groove 84 of the embodiment is set smaller than the curvature on the upper side of the curved portion 84b, and the second roller body 83 is guided through the curved portion 84b having a small curvature. The first movable body 43 is configured to move substantially linearly in the vertical direction together with the movable member 41 with almost no displacement in the horizontal direction.

(About wiring holding structure)
The wiring holding structure of the first movable effect device 37 will be described. In the first movable effect device 37, the wiring connected to the first light emitting substrate 73 provided on the first movable body 43 is on the back side of the back member 32 via the wiring opening 40 c provided on the first base member 40. To be circulated. The front support portion 55 of the arm portion 53 on which the first movable body 43 is disposed is formed with a wiring housing portion 55b that opens to the rear side above the housing space S and extends a predetermined length in the left-right direction. Has been. As shown in FIG. 16, the wiring housing portion 55b is formed with a predetermined length to the right from the left end portion of the front support portion 55 (portion constituting the movable base 52), and the rear opening of the wiring housing portion 55b is The wiring cover body 85 is detachably screwed to the rear surface of the front support portion 55 to prevent the wiring accommodated in the wiring accommodation portion 55b from coming out vertically and backwards. The wiring lid body 85 is set to be shorter than the length dimension in the left-right direction of the wiring housing portion 55b (see FIG. 19), and is located at a position facing the front side of the wiring opening 40c inside the first apparatus main body portion 47. The rear opening of the wiring accommodating portion 55b is kept open, and the wiring drawn out from the rear opening is drawn out to the back side through the wiring opening 40c.

  On the back surface of the wiring lid 85, a protruding portion 85 a extending from the inside of the first device main body portion 47 to the arm portion 53 is projected. The protrusion 85a protrudes rearward from the rear support portion 56 and is formed in an arc shape to prevent the first base member 40 and the rear support portion 56 from contacting each other. When the 1 base member 40 and the protrusion 85a contact, it is comprised so that contact resistance can be made as small as possible and contact resistance can be suppressed (refer FIG. 14). Further, the protrusion 85a is formed of a resin material having a small friction coefficient so that the sliding resistance when contacting the first base member 40 is further reduced. The two screws for fixing the wiring lid 85 to the arm portion 53 are in a state where the movable member 41 is positioned at the standby position with respect to the first device main body 47, and one of the two screws is outside the first device main body 47. The other of the two faces the wiring passage 40c and is configured to be accessible from the rear (see FIG. 12).

  A wiring cover 86 is disposed on the upper end of the rear support 56 on the right side of the position where the wiring cover 85 is disposed. As shown in FIG. 15, the wiring cover 86 includes a rear wall portion 86a facing the back surface of the first light emitting substrate 73 of the first movable body 43, and an upper wall portion extending forward from the upper end edge of the rear wall portion 86a. 86b and a right wall portion 86c extending forward from the right edge of the rear wall portion 86a and opening forward and leftward. The protruding dimension of the right wall portion 86 c in the wiring cover 86 is set to a dimension that does not contact the first light emitting substrate 73 and does not form a gap through which the wiring can pass between the first light emitting substrate 73. The extension end of the upper wall portion 86b of the wiring cover 86 overlaps the movement restricting member disposed on the reflection plate 72 on the upper side, and the wiring does not extend upward beyond the upper wall portion 86b. It is configured as follows. Corresponding to the arrangement position of the wiring cover 86 in the rear support portion 56, a bundling portion 56b is provided for bundling the wiring led out from the right end portion of the wiring accommodating portion 55b with a bundling tool (not shown), By binding the wiring to the binding portion 56b, the movement of the wiring on the left side of the binding portion 56b is restricted. A portion connected to the socket 73b disposed at a position facing the rear wall portion 86a on the back surface of the first light emitting substrate 73 from the portion of the wiring bundled to the binding portion 56b is curved in a lateral U-shape. In this state, the wiring cover 86 and the first light emitting substrate 73 are supported. As a result, the wiring bends only in the area covered with the wiring cover 86 when moving between the standby position and the operating position of the first movable body 43, and the wiring is exposed to the outside of the first movable body 43. It is prevented from becoming visible to the person. The screw for fixing the wiring cover 86 to the arm portion 53 is configured to be exposed on the rear side and accessible from the rear (see FIG. 12).

(About the second movable effect device)
As shown in FIG. 5, the second movable effect device (movable effect device) 38 is installed on the right facing surface portion 35 d of the back member 32. As shown in FIGS. 23 and 24, the second movable effect device 38 includes a second base member 87 serving as an installation base of members constituting the second movable effect device 38 and a plurality of second effect members that perform predetermined effect operations. 2 movable bodies 88, 89, a second drive unit 90 and a second linkage mechanism (first operating mechanism) 91 that reciprocate a plurality of second movable bodies 88, 89, and only one second movable body 89. It basically includes a third driving unit 92 and a third linkage mechanism (second operating mechanism) 93 that move, and a second cover member 94 that covers the front side of the second base member 87. As shown in FIG. 31, the second movable effect device 38 has a case-like shape that houses the second transmission portion 95 and the second linkage mechanism 91 of the second drive portion 90 from the second base member 87 and the second cover member 94. A second device main body (device main body) 96 is configured, and a third drive unit 92 and a third linkage mechanism 93 are disposed via cover parts 97 and 98 disposed on the second cover member 94. The second device body 96 includes the second movable body 88, 89, the second drive unit 90, the second linkage mechanism 91, the third drive portion 92, and the third linkage mechanism 93 with respect to the back member 32. The unit structure is detachable as a unit. Further, in the second movable effect device 38, the second device main body 96 is disposed outside the right side (second side) of the display unit 13a of the symbol display device 13 (see FIG. 4), and the second movable device 38 is provided. The bodies 88 and 89 face the window 28a of the decorative member 28, and the second movable bodies 88 and 89 are configured to be visible from the front side (see FIG. 2).

  In the embodiment, the second movable effect device 38 includes two second movable bodies 88 and 89, and in the following description, one second movable body (second movable body) 89 is directly moved to the second movable body 89. The movable body 89 is designated and the other second movable body (first movable body) 88 is designated as the tilted second movable body 88. In the second movable effect device 38, the first movable body 43 that has reached the operating position is located at the position where the two second movable bodies 88 and 89 overlap the front side of the right side of the display unit 13a of the symbol display device 13. It waits at a standby position that is lined up and down (in the extending direction of the right side) across a straight line L parallel to the upper side of the display unit 13a (the first side at which the first movable body 43 faces at the standby position) (FIG. 5). reference). Then, with respect to the linearly movable second movable body 89 positioned on the lower side in the standby position, the distance between the standby position and the operating position displaced upward along the right side from the standby position with respect to the front surface of the display unit 13a. The tilting second movable body 88 that reciprocates while maintaining a parallel posture and is located on the upper side at the standby position is located at the standby position and the diagonally lower left toward the center of the display unit 13a from the standby position. It is configured to reciprocate between the operating position displaced to the front side of the display unit 13a while maintaining a posture parallel to the front surface of the display unit 13a (see FIGS. 32 to 38). Further, in a state where the two second movable bodies 88 and 89 reach the operating position, as shown in FIG. 6, the first movable body 43 in the operating position is arranged in a straight line parallel to the upper side.

  25, 29, etc., the second base member 87 is a box-like body that opens to the front from which the wall rises forward from the peripheral edge of the plate-like portion that contacts the right facing surface portion 35d of the back member 32. And made of a transparent synthetic resin material. Further, as shown in FIGS. 25, 29, etc., the second cover member 94 is a box-like body that opens to the rear from which the wall rises rearward from the peripheral edge of the plate-like portion that can cover the front opening of the second base member 87. And it is formed from a transparent synthetic resin material. Then, in a state where the wall of the second cover member 94 is in contact with the wall of the second base member 87, both the members 87, 94 are fixed by screwing, whereby the second transmission portion 95 and the second linkage mechanism 91 are fixed. The second apparatus main body 96 that defines a space for accommodating etc. is configured (see FIG. 34).

  On the left side (the side on the display unit 13a side) of the second apparatus main body 96, the link rods 109, 110 (second linkage mechanism 91) are provided between the second base member 87 and the second cover member 94. A link insertion port 96a through which (described later) is inserted is defined. The link insertion port 96a is set to have a longitudinal dimension slightly larger than the longitudinal dimension of the link rods 109 and 110, and the vertical dimension is set to a width that allows the vertical displacement of the link rods 109 and 110. It is possible to suppress the shake in the front-rear direction while allowing the displacement of the inserted link rods 109, 110 in the vertical direction.

(About tilting second movable body)
As shown in FIGS. 23 and 27, the tilting second movable body 88 held above the linear motion second movable body 89 in the standby position includes a tilting decorative cover body 99 positioned on the forefront, and The tilting reflecting plate 100 made of a synthetic resin material having no light transmission disposed on the back side of the tilting decorative cover body 99 and the tilting tilting plate disposed on the back side of the tilting reflecting plate 100. The second light emitting substrate 101 is basically configured. On the tilting decorative cover body 99, a second pattern 88a for tilting such as characters and figures matching the motif of the pachinko machine 10 is formed. In the embodiment, the tilting decorative cover body 99 is formed of a light-transmitting synthetic resin material, and the surface of the portion excluding the second tilting pattern 88a is subjected to plating or the like, thereby providing the second tilting cover. Only the portion of the pattern 88a is configured to have light transmittance. On the front surface of the second light emitting substrate 101 for tilting, a plurality of LEDs 101a as light emitters are disposed corresponding to the second pattern 88a for tilting, and the reflecting plate 100 for tilting corresponds to each LED 101a. A through hole 100a penetrating in the front-rear direction is formed. Then, in a state where the second light emitting substrate 101 for tilting is screwed to the back surface of the reflecting plate 100 for tilting, the LED 101a corresponding to each through hole 100a faces, and the second pattern 88a for tilting is brightened by the light emission of the LED 101a. Configured to be In addition, the second design 88a for tilting of the embodiment is meaningful by the second design 89a for linear motion described later formed on the linear motion second movable body 89 and the first design 43a formed on the first movable body 43. A series of symbols is formed, and a third series of symbols 154a formed on the third movable body 154 is combined to form a meaningful series of symbols. A tilting light diffusion sheet 102 that diffuses the light from the LED 101a is interposed between the tilting decorative cover body 99 and the tilting reflector 100 at a position corresponding to the second tilting pattern 88a. Yes.

  As shown in FIG. 27, a plurality of support protrusions 103 are spaced apart from each other in the vertical direction (the direction along the right side) on the back surface of the tilting reflection plate 100. Each of the support protrusions 103 is formed with a fitting hole 103a that is open to the rear. In the embodiment, three support protrusions 103 are provided apart from each other in the vertical direction, and a shaft component 104 having a front end portion inserted into each fitting hole 103a protrudes rearward in these three support protrusions 103. A second operating rod 107 and link rods 109 and 110, which will be described later, constituting the second linkage mechanism 91 are rotatably connected to the shaft components 104, respectively. Note that a socket 101b is disposed on the back surface of the second light emitting substrate 101 for tilting so as to be biased to the right between the two support protrusions 103, 103 of the lowermost part and the middle part, and wiring is connected to the socket 101b. Is done.

(About the second linkage mechanism)
As shown in FIGS. 23, 24, 25, 29, etc., the second linkage mechanism 91 includes an operating member 105 disposed in the second device main body 96 so as to be movable up and down, and the operating member 105. A rack member (pressing member) 106, a second operating rod (operating rod) 107 linking the operating member 105 and the tilting second movable body 88, a second device main body portion 96, and a tilting second movable member. The parallel link mechanism 108 connected to the body 88 and cam holes 94c and 105c for moving the second operating rod 107 in conjunction with the operation of the operating member 105 are basically configured. Then, the second linkage mechanism 91 has a first position (FIGS. 32 and 33) in which the tilting second movable body 88 is moved to the standby position by driving a second motor 120 described later of the second drive unit 90, and The tilting second movable body 88 is configured to move between the second position (FIGS. 36, 37, and 38) where the second movable body 88 is moved to the operating position.

(About parallel link mechanism)
The parallel link mechanism 108 is composed of a pair of link rods 109 and 110, and both link rods 109 and 110 are linked so that one end portion (lower end portion) in the longitudinal direction is rotatable inside the second device main body portion 96. In addition, the other end portions (upper end portions) in the longitudinal direction of the link rods 109 and 110 extending outward from the second device main body portion 96 through the link insertion port 96a are tilted second movable. The body 88 is rotatably connected (see FIGS. 33 to 38). That is, the lower end portion of the first link rod 109 constituting the parallel link mechanism 108 is disposed below the straight line L between the second base member 87 and the second cover member 94. A through hole is inserted through the shaft 111 and is rotatably supported. Further, the upper end portion of the first link rod 109 is rotatably supported by a shaft component 104 fitted and inserted into an intermediate support protrusion 103 provided on the tilting second movable body 88.

  One end portion (lower end portion) of the other second link rod 110 constituting the parallel link mechanism 108 with the first link rod 109 is between the second base member 87 and the second cover member 94. The second rotation shaft 112 disposed below the position where the first rotation shaft 111 is disposed is inserted into a through hole so as to be rotatably supported. The other end portion (upper end portion) of the second link rod 110 in the longitudinal direction is rotatably supported by a shaft component 104 fitted in the lowermost support projection 103 provided on the tilting second movable body 88. Is done. That is, the tilting second movable body 88 connected to the second apparatus main body 96 by the parallel link mechanism 108 including the pair of link rods 109 and 110 is configured to be able to move in parallel without changing the posture. . In the second cover member 94, two upwardly projecting arcuate guide holes 94a and 94a are vertically arranged at positions overlapping the moving paths of the two link rods 109 and 110 in the front and rear directions, as shown in FIGS. They are spaced apart. A first roller member 113 pivotally supported at an intermediate position in the longitudinal direction of the first link rod 109 is rotatable in the upper arcuate guide hole 94a and is movable along the guide hole 94a. The second roller member 114 pivotally supported at an intermediate position in the longitudinal direction of the two link rod 110 faces the other arcuate guide hole 94a so as to be movable along the guide hole 94a (FIG. 32). (See FIG. 36). Accordingly, the pair of link rods 109 and 110 are configured to stably swing around the corresponding rotation shafts 111 and 112. The roller members 113 and 114 are configured by connecting a pair of halves having a flange extending in the radial direction from the shaft portion so that the flanges face both sides of the arcuate guide hole 94a. The roller members 113, 114 are restricted from moving in the front-rear direction with respect to the corresponding arc-shaped guide holes 94a, 94a, and the link rods 109, 110 are restrained from shaking in the front-rear direction at the middle part in the longitudinal direction. It has become so.

  Here, the shaft component 104 of the tilting second movable body 88 is provided with a spacer 115 at a protruding portion rearward from the support protrusion 103, and the rear of the shaft component 104 protruding rearward from the spacer 115. The link rods 109 and 110 are pivotally supported at the end portions, and the second cover is provided between the link rods 109 and 110 and the back surface of the tilting second movable body 88 (the tilting second light emitting substrate 101). The member 94 is configured to ensure a gap that allows insertion of an upper extension portion 94d described later. A guide projection 109a protruding outward is provided at the upper edge of the first link rod 109 facing the upper side (upper extension 94d side) at a position corresponding to the upper extension 94d. A slope is formed on the front surface of the protrusion 109a so as to retreat to the rear side toward the protruding end. That is, when the first link rod 109 moves from the first position to the second position (from the operation position of the tilting second movable body 88 to the standby position), it moves to a position overlapping the rear side of the upper extension portion 94d. Sometimes, the guide protrusion 109a is configured to reliably guide the first link rod 109 to the rear side of the upper extension 94d.

  The first rotating shaft 111 is provided with a torsion coil spring 116 as return assisting means, and the torsion coil spring 116 moves the tilting second movable body 88 toward the standby position on the first link rod 109. The urging force that rotates in the direction to be applied is always applied. The torsion coil spring 116 includes a coil portion 116a and two elastic arm portions 116b and 116c. When the first rotating shaft 111 is inserted through the coil portion 116a, one elastic arm portion 116b is connected to the first link arm. 109, and the other elastic arm portion 116c is locked to the spring locking portion 94b provided on the second cover member 94. In the embodiment, the torsion coil spring is used. 116 urges the first link rod 109 to rotate upward.

  As shown in FIGS. 29, 35, and 38, a plurality of wiring hooks 110a are provided apart from each other in the longitudinal direction on the back surface of the second link rod 110 and connected to the socket 101b of the second light emitting board 101 for tilting. The routed wiring is configured to be drawn into the second device main body 96 from the link insertion port 96a after being routed with the back side of the second link rod 110 locked to the wiring hook 110a. The Further, on the back surface of the second link rod 110, bundling portions 110b for bundling the wires with a bundling tool (not shown) are provided on both sides in the longitudinal direction across the plurality of wiring hooks 110a, and the back side of the second link rod 110 is pulled. The wiring to be rotated is configured to be prevented from greatly extending backward. In addition, a decorative plate 117 is disposed on the front surface of the link rods 109 and 110 at portions visible from the front side of the link rods 109 and 110, respectively, to prevent the appearance from being deteriorated (FIG. 30). reference).

(About actuating members)
The operating member 105 is a plate-like member located on the front side of the second cover member 94 as shown in FIGS. 25, 29, and 30, and extends in the left-right direction (direction perpendicular to the second side). The rack member 106 is provided with a horizontal portion 105a and a vertical portion 105b extending downward from the right end portion of the horizontal portion 105a, and the vertical portion 105b is disposed inside the second device main body 96. The rack member 106 is configured to move integrally with the rack member 106. Further, a first cam hole 105c penetrating in the front-rear direction is formed in the lateral portion 105a of the operation member 105 so as to extend in the left-right direction. One end of the second operation rod 107 in the longitudinal direction is formed in the first cam hole 105c. The portions (upper end portions) are connected so as to be rotatable and movable in the left-right direction.

  The upper end of the second actuating rod 107 faces between the second cover member 94 and the actuating member 105, and the upper end of the shaft pin 118 fitted in the through hole projects in the front-rear direction. Established. A roller member 119 is pivotally supported at a portion of the shaft pin 118 protruding forward, and the roller member 119 faces the first cam hole 105c of the operating member 105 so as to be movable in the left-right direction. Yes. The lower end of the second operating rod 107 is rotatable to the end protruding backward from the spacer 115 of the shaft part 104 fitted into the uppermost support protrusion 103 provided on the tilting second movable body 88. It is connected. Further, the second cover member 94 is formed with a second cam hole 94c extending in the vertical direction, and projects to the rear side of the shaft pin 118 disposed on the second operating rod 107 in the second cam hole 94c. The part to be inserted is movably inserted. The second cam hole 94c is formed in a curved shape that protrudes downward so as to deviate to the left as it goes from the upper side to the lower side. The shaft pin 118 is guided along the second cam hole 94c as the operating member 105 reciprocates in the vertical direction, so that the second operating rod 107 moves up and down and moves into the first cam hole 105c. It is comprised so that it may move to the left-right direction along (refer FIG. 32, FIG. 36). As a result, the tilting second movable body 88 supported by the parallel link mechanism 108 translates between the standby position and the operating position along the front surface of the display unit 13a. Here, the tilting second movable body 88 is obtained by combining the vertical movement and the horizontal movement of the second operating rod 107, and the standby position on the right side of the display unit 13a and the front center of the display unit 13a. It moves in a slanting manner between the working position on the side and the center in the vertical direction.

  The second cover member 94 is provided with an upper extension portion 94d that extends outward from the left end edge (end edge on the display portion 13a side) of the second base member 87 at a position above the straight line L. The second cam hole 94c is formed from the position biased to the right side at the upper end portion of the second cover member 94 to the extending end of the upper extending portion 94d (see FIG. 29). Then, when the shaft pin 118 of the second operating rod 107 reaches the end of the upper extension portion 94d of the second cam hole 94c on the extension end side, as shown in FIG. Is configured to reach the left operating position where it does not interfere with the linearly movable second movable body 89.

(About the second drive unit)
23, 24, 25, and 29, the second driving unit 90 connects the second motor (driving means, first driving means) 120, the second motor 120, and the operating member 105. The second transmission unit 95 converts the rotation of the second motor 120 into the operation of the operation member 105. In the embodiment, a stepping motor that is driven or stopped under the control of the control device is used as the second motor 120. The second motor 120 is attached to the rear surface of the upper end portion of the second base member 87 (see FIG. 31), faces the right-side recess (not shown) formed in the right facing surface portion 35d of the back member 32, and the second motor 120 2 The output shaft of the motor 120 protrudes into the second device main body 96 through a through hole formed in the second base member 87.

  The second transmission unit 95 includes a drive gear 121 fixed to the output shaft of the second motor 120, a plurality of driven gears 122 that mesh with the drive gear 121, and a pinion 123 that meshes with the last-stage driven gear 122. The rack member 106 is screwed to the vertical portion 105b of the operating member 105 and meshes with the pinion 123, and has a so-called rack and pinion structure that converts the forward / reverse rotation of the pinion 123 into the linear motion of the operating member 105. (See FIGS. 33, 34, 35, 37, and 38). The drive gear 121, the plurality of driven gears 122, and the pinion 123 are disposed inside the second device main body 96, and the rack member 106 is positioned at the right end (from the display unit 13a) inside the second device main body 96. It is arranged so as to be movable in the vertical direction at the end portion that is separated. Note that the rack member 106 also serves as a member constituting the second linkage mechanism 91 as described above.

  As shown in FIG. 29, a front protrusion 106a extending in the vertical direction protrudes from the upper front end portion of the rack member 106, and the rear upper end portion of the rack member 106 extends in the vertical direction. A protrusion 106b is provided to protrude. As shown in FIG. 31, the rack member 106 accommodated in the second device main body 96 has a front protrusion in a front elongated hole 94e formed so as to penetrate the second cover member 94 in the front-rear direction and extend in the vertical direction. 106 a is slidably inserted, and a rear protrusion 106 b is slidably inserted into a rear elongated hole 87 a formed so as to penetrate the second base member 87 in the front-rear direction and extend in the vertical direction. The rack member 106 is configured to reciprocate linearly in the vertical direction along the front and rear elongated holes 94e and 87a. The vertical member 105b of the operating member 105 is screwed to the front projecting portion 106a, so that the operating member 105 reciprocates in the vertical direction integrally with the rack member 106.

  The second movable effect device 38 includes second detection means 134 that is installed at the upper end portion of the second base member 87 and includes a photosensor that determines the position of the tilting second movable body 88 (FIG. 34 or FIG. The second detection means 134 is electrically connected to the control device so that a detection signal is input to the control device. The second detection means 134 is a tilting second movable body 88 (operating member) depending on the presence or absence of the second detection piece 135 of the rack member 106 disposed so as to pass between the opposing detection portions in the second detection means 134. 105) is determined. The second detection piece 135 is screwed to the rear protrusion 106 b of the rack member 106 on the rear side of the second base member 87, and the second detection piece 135 performs the second detection at the standby position of the tilting second movable body 88. The second movable body 88 is set so as to be positioned between the detection portions of the means 134 and the second movable body 88 in the standby position can be confirmed by the detection of the second detection piece 135 by the second detection means 134.

(Regarding the second movable body that moves directly)
As shown in FIGS. 23, 24, and 28, the linearly movable second movable body 89 includes a linear motion decorative cover body 136 positioned at the forefront and a light disposed on the back side of the linear motion decorative cover body 136. It is basically composed of a linear motion reflecting plate 137 formed of a synthetic resin material that does not have transparency, and a linear motion second light emitting substrate 138 disposed on the back side of the linear motion reflecting plate 137. The linear motion decorative cover body 136 is formed with a second linear motion pattern 89a for characters or the like that matches the motif of the pachinko machine. In the embodiment, the linear motion decorative cover body 136 is formed of a light-transmitting synthetic resin material, and the surface of the portion excluding the second linear motion pattern 89a is subjected to plating, etc. Only the portion of the pattern 89a is configured to have light transmittance. A plurality of LEDs 138a as light emitters are disposed on the front surface of the second linear light emitting substrate 138 corresponding to the second linear pattern 89a for linear motion, and the reflective plate 137 for direct motion corresponds to each LED 138a. A through hole 137a penetrating in the front-rear direction is formed. Then, the LED 138a corresponding to each through-hole 137a faces in a state where the second light emitting substrate 138 for linear movement is screwed to the back surface of the reflecting plate 137 for linear motion, and the second pattern 89a for linear motion is brightened by the light emission of the LED 138a. Configured to be In addition, the second design 89a for linear motion of the embodiment is meaningful by the second design 88a for tilting formed on the tilting second movable body 88 and the first design 43a formed on the first movable body 43. A series of symbols is formed, and a third series of symbols 154a formed on the third movable body 154 is combined to form a meaningful series of symbols. A linear motion light diffusion sheet 139 that diffuses light from the LED 138a is interposed between the linear motion decorative cover body 136 and the linear motion reflector 137 at a position corresponding to the second linear motion pattern 89a. Yes.

  Here, in the embodiment, as shown in FIG. 6, the first movable body 43 and the two second movable bodies 88 and 89 are arranged from the left side to the right side in the operating position which is the front side of the display unit 13a of the symbol display device 13. The first movable body 43, the tilted second movable body 88, and the linearly movable second movable body 89 are arranged in a straight line in this order. In this state, the first symbol 43a, the second symbol for tilting 88a, and the second symbol for linear motion are arranged. A series of meaningful symbols is formed by 89a. Further, as shown in FIG. 5, the first movable body 43 is positioned along the upper side of the display unit 13 a at the standby position, and is tilted from the upper side to the lower side along the right side of the display unit 13 a at the standby position. When the movable body 88 and the linearly movable second movable body 89 are arranged in this order, the first pattern 43a, the second pattern 88a for tilting and the second pattern 89a for linear motion are arranged in a straight line at the operating position. A common series of meaningful symbols is formed.

  As shown in FIG. 23, the direct acting reflector 137 is provided with an attaching portion 137 b extending rightward from the second light emitting substrate 138 for direct acting, and the attaching portion 137 b is connected to the third connecting mechanism 93. Has been. A through-hole 137c penetrating in the front-rear direction is formed on the left end side of the mounting portion 137b, and a socket 138b provided on the front surface of the second light emitting substrate for linear movement 138 is configured to face the through-hole 137c. Then, the wiring connected to the socket 138b is pulled out to the right side through a gap provided between the right end portion of the linear motion decorative cover body 136 and the mounting portion 137b. Note that a regulating body 140 including a regulating projection 140a projecting rearward is disposed at the left end of the linear motion decorative cover body 136 (the end opposite to the side where the mounting portion 137b is provided) (FIG. 28). reference). The restricting protrusion 140a is configured to be able to slide and abut on the front surface of the decorative component 141 disposed on the front surface of the second cover member 94, and the third linkage mechanism 93 when the linearly movable second movable body 89 moves up and down. It functions to suppress the left end portion, which is separated from the connecting portion, from being displaced rearward.

  As shown in FIGS. 23 and 30, the decorative part 141 is disposed at three positions on the front surface of the second cover member 94 in the embodiment, and the regulating protrusion 140 a is in sliding contact with the lowermost decorative part 141. It is possible. The lowermost decorative part 141 is formed with relief portions 141a corresponding to the arc-shaped guide holes 94a and 94a, respectively, and the roller members 113 and 114 guided by the arc-shaped guide holes 94a and 94a. To prevent interference.

(About the third drive unit)
As shown in FIGS. 23, 24, and 26, the third driving unit 92 includes a solenoid (second driving means) 142 and a third transmission unit 143 operated by the solenoid 142. A solenoid installation recess 94f is formed in the lower end portion of the front surface of the second cover member 94 (see FIGS. 25 and 31), and the sonolide 142 is installed in the solenoid installation recess 94f with the plunger 142a facing upward. The second cover member 94 is provided with a third transmission portion installation portion 144 above the solenoid installation recess 94f, and the third transmission portion 143 is installed in the third transmission portion installation portion 144 (FIG. 32). , See FIG. 36). The third transmission unit 143 includes a first operating body 145 connected to the plunger 142a and a third transmission unit installation unit 144 pivotally supported in the middle in the longitudinal direction, and one end in the longitudinal direction is a first operating body. A seesaw member 146 that is pivotally supported by 145 and a second operating body 147 that is pivotally supported at the other end in the longitudinal direction of the seesaw member 146. As shown in FIGS. 32 and 36, the first operating body 145 and the second operating body 147 are spaced apart from each other in the left-right direction and are disposed on the third transmission portion installation portion 144 so as to be movable up and down. An intermediate portion in the longitudinal direction of the seesaw member 146 is rotatably supported on a shaft provided in the third transmission portion installation portion 144 between the two. An end portion of the seesaw member 146 that extends to the right with the shaft support portion interposed therebetween is rotatably supported by the first operating body 145 via the shaft and extends to the left with the shaft support portion interposed therebetween. The end is pivotally supported by the second operating body 147 via a shaft so as to be rotatable. That is, as the first operating body 145 moves up and down due to excitation and demagnetization of the solenoid 142, the second operating body 147 moves up and down in the reverse direction via the seesaw member 146. The solenoid 142 and the third transmission part 143 are positioned so as not to fall off with respect to the third transmission part installation part 144 by the first cover part 97 screwed to the front surface of the second cover member 94.

  As shown in FIG. 25, the installation portion for supporting the second operating body 147 in the third transmission portion installation portion 144 so as to move up and down is a pair of restriction walls 144a and 144a that are separated from each other left and right, and the upper ends of the restriction walls 144a. And an upper wall 144b extending toward the other restriction wall 144a. The second actuating body 147 is formed in a convex shape in a front view, and as shown in FIGS. 32, 36 and 39, it moves up and down while being guided by both regulating walls 144a and 144a, and protrudes upward when moving up. Since the portion protrudes upward from the gap between the upper walls 144b and 144b, the second member 150 (described later) of the third linkage mechanism 93 can be pushed up.

(About the third linkage mechanism)
As shown in FIGS. 23, 24, and 26, the third linkage mechanism 93 includes an operation pinion (linkage body) 148 rotatably disposed on the front surface of the second cover member 94, and a right side of the operation pinion 148. Located on the left side of the first member 149 and the actuating pinion 148 that can be brought into and out of contact with the rack member 106 of the second linkage mechanism 91 and disposed on the linearly movable second movable body 89 and the third member The second actuating body 147 of the transmission unit 143 and the second member 150 that can contact and separate are provided. The first member 149 has rack teeth 149a formed on the side edge on the operating pinion 148 side, the rack teeth 149a mesh with the operating pinion 148, and the second member 150 is racked on the side edge on the operating pinion 148 side. The teeth 150a are formed, the rack teeth 150a mesh with the operating pinion 148, and the first member 149 and the second member 150 move up and down in opposite directions by the normal rotation and reverse rotation of the operating pinion 148. It is configured as follows. The second cover member 94 is screwed to the front surface of the second cover member 94 to cover the third linkage mechanism 93 and to have a positioning and guiding function for the third linkage mechanism 93.

  The operation pinion 148 is rotatably supported on a shaft disposed between the second cover member 94 and the second cover component 98. A guide slit 94g penetrating in the front-rear direction and extending in the up-down direction is formed on the right side of the second cover member 94 from the position where the operation pinion 148 is disposed (see FIG. 25), and the second cover part 98 In the position facing the front side of the guide slit 94g, a guide groove 98a (see FIG. 26) recessed in the front side is formed to extend in the vertical direction substantially in the same length as the guide slit 94g. . A guide plate 149b protruding rearward is formed on the back surface of the first member 149 over the entire length in the vertical direction, and a pair of guide protrusions are spaced apart in the vertical direction on the front surface of the first member 149. 149c and 149c are projected forward. The first member 149 is slidably inserted into the guide slit 94g through the guide plate 149b, and the guide protrusions 149c and 149c are slidably inserted into the guide groove 98a. It is supported so as to move linearly in the vertical direction along the guide slit 94g and the guide groove 98a (see FIG. 31). The guide plate 149b protrudes from the guide slit 94g into the second device main body 96, and the upper end of the protruding portion is positioned so as to face the lower side of the rack member 106 in the second linkage mechanism 91. The lower end of the member 106 is configured to be able to contact the upper end of the guide plate 149b (see FIGS. 35 and 38).

  As shown in FIG. 26, a guide hole 98b penetrating in the front-rear direction and extending in the up-down direction is formed in parallel with the guide groove 98a on the left side of the second cover part 98 from the position where the operation pinion 148 is disposed. Is done. On the other hand, a pair of mounting projections 150b and 150b are provided on the front surface of the second member 150 so as to be separated from each other in the vertical direction and project forward. The mounting projections 150b and 150b are guided through the guide hole 98b. The second member 150 is supported so that it can move linearly in the vertical direction along the guide hole 98b. Each mounting projection 150b is formed with a screw hole that opens to the front side, and the front end of the mounting projection 150b protruding to the front side of the second cover part 98 is attached to the linearly movable second movable body 89. By screwing the portion 137b, the linearly movable second movable body 89 is configured to move integrally with the second member 150.

  Note that the front surface of the second member 150 has a projecting dimension smaller than the mounting projections 150b and 150b between the mounting projections 150b and 150b, and the front surface of the second cover component 98 through the guide hole 98b. A regulating rib 150c is formed so as to protrude from the surface. The mounting protrusions 150b and 150b projecting forward from the guide hole 98b are provided with plate bodies 151 having through holes formed in the upper and lower ends thereof, and the mounting protrusions 150b and 150b are inserted into the through holes and the front ends of the regulation ribs 150c The mounting portion 137b of the linearly movable second movable body 89 is screwed to the mounting projections 150b and 150b with the plate body 151 interposed therebetween. That is, the plate 151 is brought into contact with the front end of the regulating rib 150 c, so that a gap is generated between the plate 151 and the second cover part 98, and the mounting portion between the second member 150 and the linearly movable second movable body 89 is formed. The second cover part 98 is prevented from being sandwiched between the first cover member 137b and the smooth movement of the linearly movable second movable body 89 (second member 150) is ensured.

  As shown in FIG. 25, the front surface of the second cover member 94 is provided with a stopper 94h corresponding to the lower end of the guide slit 94g, and the lower end of the first member 149 contacts the stopper 94h. Thus, the lowering of the first member 149 is restricted. The rear surface of the second cover member 94 is formed with a stepped portion protruding rearward by forming the solenoid installation concave portion 94f, and a compression coil spring serving as a return means whose lower end is locked to the stepped portion. A push component 153 is attached to the upper end of 152 (the end of the first member 149 facing the end of the guide plate 149b). The pushing component 153 is always urged by the elasticity of the compression coil spring 152 so as to abut on the lower end of the guide plate 149b in the first member 149. That is, the first member 149 is always urged toward the upper position by the elasticity of the compression coil spring 152, and the second member 150 meshing with the operating pinion 148 is urged toward the lower position. Accordingly, in the state where the external force other than the compression coil spring 152 is not applied to the first member 149 and the second member 150, the lower end of the second member 150 has the upper walls 144b and 144b that constitute the installation portion of the second operating body 147. The linearly movable second movable body 89 disposed on the second member 150 is held at the standby position at this position (see FIG. 32).

  As shown in FIG. 33, the second linkage mechanism 91 is located in the first position (the tilted second movable body 88 is in the standby position) and the third linkage mechanism 93 is in the original position. The rack member 106 of 91 and the first member 149 of the third linkage mechanism 93 are spaced apart in the vertical direction. Then, as shown in FIG. 34, the rack member 106 contacts the first member 149 at the contact position where the second linkage mechanism 91 moves from the first position to the second position, and the second linkage mechanism is in this contact state. As 91 moves toward the second position, the first member 149 is pushed by the rack member 106 and moves downward, whereby the second member 150 moves upward via the operating pinion 148. (See FIG. 37). When the second linkage mechanism 91 arrives at the second position, as shown in FIG. 37, the second member 150 reaches the uppermost movable position, and at this time, the linear second movable body 89 arrives at the operating position. It is like that. Further, while the second linkage mechanism 91 moves from the second position to the contact position, the first member 149 is urged to contact the rack member 106 by the elasticity of the compression coil spring 152, and thus the rack member 106 and the When the first member 149 is integrally moved upward, the second member 150 is moved downward via the operation pinion 148. That is, while the rack member 106 moves between the contact position and the second position, the contact state between the rack member 106 and the first member 149 is maintained, and the third connection mechanism 91 moves along with the third connection mechanism 91. The linkage mechanism 93 moves integrally between the original position and the movable position.

  The trajectory of the tilting second movable body 88 that reciprocates between the standby position and the operating position by the second linkage mechanism 91 is a straight line that reciprocates between the standby position and the operating position by the third linkage mechanism 93. The trajectory of the second movable body 89 is set so as to partially overlap. In other words, in the embodiment, the linearly movable second movable body 89 that is positioned below the tilting second movable body 88 in the standby position moves between the interference position and the operating position between the standby position and the operating position. In the region to be contacted, the relationship is set such that the second movable body 88 that contacts between the interference position between the standby position and the operation position and the standby position moves in contact with each other. However, in the embodiment, while the rack member 106 of the second linkage mechanism 91 moves to the contact position where the rack member 106 contacts the first member 149 of the third linkage mechanism 93, the second linkage mechanism 91 tilts the second movable body. 88 is moved from the interference position to the operating position side, and the linearly movable second movable body 89 moved by the third linkage mechanism 93 interlocked with the second linkage mechanism 91 in a state where the rack member 106 is in contact with the first member 149 is inclined. The movable second movable body 88 is configured not to contact. That is, when the second linkage mechanism 91 moves between the contact position and the second position, the tilting second movable body 88 moves so as to move away from the trajectory of the linear second movable body 89. It has become.

  Here, the movement range of the third linkage mechanism 93 by the third drive unit 92 (solenoid 142) is such that the second operating body 147 of the third drive unit 92 is in contact with the second member 150 of the third linkage mechanism 93. Is set so that the first member 149 that moves up and down in the opposite direction to the second member 150 via the operating pinion 148 does not come into contact with the rack member 106 of the second linkage mechanism 91 in the standby position. Is done. Further, the movement range of the linearly movable second movable body 89 when the third drive unit 92 is operated is set to the standby position side from the interference position, and is tilted with the linearly movable second movable body 89 when the solenoid 142 is driven. It is comprised so that the 2nd movable body 88 may not contact (refer FIG. 39).

(About the third movable effect device)
As shown in FIG. 5, a third movable effect device 39 including a third movable body 154 is disposed on the lower facing surface portion 35 b of the back member 32. The third movable effect device 39 faces the third movable body 154 at the standby position (FIG. 5) outside the lower side (side parallel to the first side) of the display unit 13a and the front side of the display unit 13a. A space between the first movable body 43 and the second movable bodies 88 and 89 arranged under the first movable body 43 and the second movable bodies 88 and 89 arranged in a straight line in the left-right direction up to the operation position is parallel to the front surface of the display unit 13a. It is configured to reciprocate up and down while maintaining the posture. The third movable body 154 is provided with a third pattern 154a such as characters and figures that match the motif of the pachinko machine, as in the first movable body 43 and the second movable bodies 88 and 89. The three symbols 154a are configured to be bright by emitting light from an LED of a third light emitting substrate (not shown) built in the third movable effect device 39. Further, the third symbol 154a is a lower side of the symbol row of the first symbol 43a of the first movable body 43 and the second symbols 88a and 89a of the second movable members 88 and 89 arranged in a straight line on the front side of the display portion 13a. A series of symbols can be formed side by side.

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

  The pachinko balls launched into the game area 18a flow down around the outer periphery of the decorative member 28, and when the pachinko balls enter the ball introduction part 30, the pachinko balls are passed out to the stage 29, and After rolling the stage 29 left and right, it is discharged to the game area 18a, and this pachinko ball can be awarded to the first start winning device 23, the normal winning device 27, and the like. When a pachinko ball wins the first start winning device 23, the symbols on the symbol display device 13 start to fluctuate, and a required symbol combination game is developed. As a result of the symbol variation game developed on the symbol display device 13, a big hit occurs when symbols are stopped and displayed on the symbol display device 13 in a predetermined symbol combination. When a big hit occurs, according to the symbol combination displayed on the symbol display device 13, the winning opening of the special winning device 25 provided below the game board 18 is opened, and a large number of winning balls can be obtained. It becomes.

  When the pachinko ball flowing down the game area 18a passes through the gate 26, the control device opens and closes the opening / closing member of the second start winning device 24 on condition that a ball detection signal is input from the gate sensor. A lottery to determine whether or not to release. If the winning is determined as a result of the lottery, the opening / closing member of the second start winning device 24 is operated to open the start winning port, and the probability of winning the start winning port is increased. Further, when the pachinko ball wins the start winning opening of the second start winning device 24, the symbols of the symbol display device 13 start to fluctuate in the same manner as when the pachinko ball wins the first start winning device 23. After the required symbol combination game is developed, the result of either big hit or miss is displayed on the display unit 13a.

  In accordance with the effect of the symbol variation game developed on the symbol display device 13, the movable effect devices 37, 38, 39 are controlled to operate, and the movable bodies 43, 88, 89, 154 are activated to be dynamic. The entertainment enhances the fun of the game. In addition, the LEDs 73a, 101a, and 138a of the light-emitting substrates 73, 101, and 138 disposed on the movable bodies 43, 88, 89, and 154 are controlled to emit light according to the effects of the symbol variation game, so that each movable body 43 is controlled. , 88, 89, 154, the entertainment of the game is improved by the effect that the symbols 43a, 88a, 89a, 154a are bright.

(About the single action of the first movable effect device)
When the first motor 64 is stopped (non-energized), the first movable effect device 37 uses the mechanical holding torque of the first motor 64 itself to weight the movable member 41 and the first movable body 43. The movable member 41 is supported at the standby position by being supported via the first transmission portion 46 (see FIGS. 5, 12, 20, and 19). Further, at the standby position of the movable member 41, the movable member 41 is supplementarily held at the standby position by the magnetic force adsorption between the magnet 49 and the metal piece 54. Therefore, even when the vibration of the game board 18 and other unscheduled forces are applied to the movable member 41 and the first movable body 43, the first movable effect device 37 has the movable member 41 and the first movable body 43 connected to each other. Lowering from the standby position can be suitably prevented.

  In the first movable effect device 37, the first movable body 43 is in the standby position in the normal state, and the first movable effect device 37 is linked with or independently of the symbol variation game performed on the display unit 13a of the symbol display device 13. The movable body 43 is reciprocated between the standby position and the operating position. Specifically, in the first movable effect device 37, the first motor 64 is driven and the movable member 41 is displaced downward via the first transmission unit 46. As a result, the movable member 41 is lowered while being supported by the rolling bearing 51, and the first movable body 43 is moved to the left along the arm portion 53 by the first linkage mechanism 44 as the movable member 41 is lowered. Move (see FIGS. 21 and 22). That is, as shown in FIG. 5, the first movable body 43 located at the standby position at the center of the upper side of the display unit 13a moves to the left as the movable member 41 descends, thereby moving the front of the display unit 13a. 6 is moved in a diagonally downward direction to the left and arrives at the operating position shown in FIG. The first motor 64 stops when the movable member 41 and the first movable body 43 arrive at the operating position, and the movable member 41 and the first movable body 43 are held at the operating position.

  When the first motor 64 is driven in reverse, the movable member 41 is displaced upward via the first transmission unit 46. As a result, the movable member 41 rises while being supported by the rolling bearing 51, and the first movable body 43 moves to the right along the arm portion 53 by the first linkage mechanism 44 as the movable member 41 rises. Moving. That is, the first movable body 43 located at the operation position biased to the left side at the center in the vertical direction of the display unit 13a moves to the right as the movable member 41 rises, so that the display unit 13a The front is moved in a diagonally upward right direction to return to the standby position at the center of the upper side of the display unit 13a. Then, by stopping the first motor 64 at a predetermined timing after the first detection means 69 detects the first detection piece 70, the first movable body 43 is in a standby position where it is retracted to the upper side of the display unit 13a. Holds stopped. The movable member 41 that moves in the vertical direction with respect to the first device main body 47 has an arm portion 53 that extends to the right of the movable base 52 at a movable insertion port 47 a of the first device main body 47. While being guided (see FIG. 17), the guide member 52 a disposed on the left side of the movable base 52 is guided back and forth by the guide port 47 b of the first apparatus main body 47. That is, the movable member 41 is guided forward and backward on both the left and right sides of the movable base 52, so that the movable member 41 is preferably prevented from shaking in the front-rear direction.

  Here, when the movable member 41 arrives at the standby position, as shown in FIGS. 14 and 18, the restricting member 48 faces the front side of the arm portion 53 and the forward movement of the arm portion 53 is restricted. The That is, since the first movable body 43 is disposed on the front side of the arm portion 53, a force that tilts forward due to the weight of the first movable body 43 is applied to the arm portion 53. Is reliably prevented. Therefore, the forward displacement of the first movable body 43 disposed on the arm portion 53 is also prevented, and the first movable body 43 can be prevented from interfering with a member positioned on the front side such as the decorative member 28. Moreover, since the regulating member 48 includes an inclined portion 48b at the lower end portion that increases in distance from the extending portion 40a of the first base member 40 from the upper side to the lower side, the regulating member 48 moves from the operating position to the standby position. The arm portion 53 of the movable member 41 can be reliably guided between the extending portion 40 a of the first base member 40 and the parallel portion 48 a of the regulating member 48.

  In the first movable effect device 37, as shown in FIGS. 16, 18, 19, 21, and 22, etc., a rolling bearing 51 that movably supports the movable member 41 with respect to the first device body 47 is provided. A first drive unit 42 including a first transmission unit 46 and a first motor 64 is disposed on the opposite side of the arm unit 53 from the extending side. Therefore, the first drive part 42 does not interfere with the operation of the arm part 53 and can move the movable member 41 stably. Moreover, since the 1st connection mechanism 44 which connects the movable member 41 and the 1st movable body 43 is substantially arrange | positioned on the extension side of the arm part 53 in the movable member 41 (refer FIG. 19, FIG. 22), this 1st It can suppress that the freedom degree of design of the 1 linkage mechanism 44 becomes low for the 1st drive part 42. FIG.

  In the first movable effect device 37, the movable base 52 of the movable member 41 is supported by the fixed first cover member 45 via the rolling bearing 51 having a lower sliding load than the sliding bearing structure. Therefore, the movable member 41 can be operated smoothly, and the load on the first drive unit 42 (first motor 64) can be reduced. In the first movable effect device 37, the first movable body 43 that is provided with the first light emitting substrate 73 and is provided with the first light emitting substrate 73 on the arm portion 53 extending in the lateral direction from the movable base 52 is provided obliquely with respect to the movable base 52. The weights of the first movable body 43 and the arm portion 53 are applied downward. However, in the rolling bearing 51, as shown in FIG. 17, the inner receiving portion 59 and the inner receiving portion 61 are supported by being sandwiched from the left and right by the rolling elements 60, and even if a load is applied in a direction crossing the displacement direction. Since it is difficult to tilt, the movable member 41 can be smoothly moved up and down by the rolling bearing 51 even when the weight of the first movable body 43 is obliquely applied. Further, the rolling bearing 51 is supported movably by a plurality of rolling elements 60 spaced in the vertical direction on both the left and right sides of the inner receiving portion 59 disposed on the movable base 52, so that the movable member 41 is stably supported. It can be supported and operated more smoothly.

  The outer receiving portion 58 constituting the rolling bearing 51 is engaged with the upper engaging portion 45 b provided on the first cover member 45 at the upper end portion, and the lower end portion of the outer receiving portion 58 is the first cover. It is held by a fixing member 62 that is detachably fixed to the member 45 (see FIG. 19). That is, the outer receiving portion 58 that movably supports the intermediate receiving portion 61 and the inner receiving portion 59 of the rolling bearing 51 is held with respect to the first cover member 45 at the upper end portion and the lower end portion. In the intermediate region in which the inner receiving portion 59 moves, there is no means such as a screw for fixing the outer receiving portion 58 to the first cover member 45. Therefore, it is not necessary to provide a fixing portion for fixing means such as screws in the outer receiving portion 58, or to adopt a configuration that does not interfere with the fixing means in the intermediate receiving portion 61 or the inner receiving portion 59, and the configuration of each part is simplified. Manufacturing cost can be reduced. Further, the outer receiving portion 58 can be easily removed from the first cover member 45 simply by removing the fixing member 62, and the maintainability is improved.

  The movable connecting member 78 that displaces the first movable body 43 with respect to the arm portion 53 is supported by a plurality of guide rollers 57 and 57 with respect to the arm portion 53 as shown in FIGS. Thus, the resistance during movement of the first movable body 43 is small, and a smooth operation of the first movable body 43 can be achieved. Further, the first operating rod 79 constituting the first linkage mechanism 44 together with the movable connecting member 78 rotates and moves via the roller bodies 81 and 83 with respect to the movable connecting member 78 and the cam groove 84 of the first base member 40. It is connected so that the resistance which generate | occur | produces in each connection part at the time of the action | operation of the 1st connection mechanism 44 is restrained small. That is, it is configured such that the resistance at each support portion and the connecting portion of the first connecting mechanism 44 that operates the first movable body 43 in conjunction with the operation of the movable member 41 reciprocated by the first motor 64 is reduced. Therefore, the load applied to the first motor 64 can be further reduced, a motor with a small driving force can be used, the size can be reduced, and an increase in cost can be suppressed.

  The wiring connected to the socket 73 b of the first light emitting substrate 73 in the first movable body 43 is in a space defined between the wiring cover 86 disposed on the arm portion 53 and the first light emitting substrate 73. After being bent into a U-shape, it is drawn into the first device main body 47 while being housed in the wiring housing portion 55b defined in the arm portion 53, and the wiring of the first base member 40 is passed through. It is pulled out to the back side through the opening 40c. That is, the wiring facing the back side of the first movable body 43 is prevented from bending so as to protrude rearward or upward when the first movable body 43 moves, and the first movable body is caught by the wiring being caught by another member. It is prevented that 43 and the movement of the movable member 41 are inhibited. Further, as shown in FIG. 12, the wiring lid body 85 that closes the rear opening of the wiring housing portion 55 b extends over the outer side and the inner side of the first device main body portion 47, and the wiring lid body 85 is connected to the arm portion 53. It functions to regulate the rearward displacement of the. Moreover, the protrusion 85a protruding rearward of the wiring lid 85 is formed in an arc shape (see FIG. 14), and the contact area of the first device main body 47 with the first base member 40 is kept small. Therefore, the contact resistance with the first base member 40 during the reciprocating motion of the movable member 41 is small, which contributes to the smooth operation of the movable member 41 and the load applied to the first motor 64.

  The first movable effect device 37 can be attached to and detached from the back member 32 in units of the first device main body 47, and maintenance such as failure and component replacement is easy. Further, by positioning the first movable body 43 in the attaching / detaching position with respect to the arm portion 53, as shown in FIGS. 12 and 16, the right end screw for fixing the first movable body 43 and the movable connecting member 78 is secured. 80 is exposed to the rear side outside the accommodation space S of the arm portion 53, and each of the left end and the middle two screws 80 is aligned with a corresponding hole 56a formed in the rear support portion 56 in the front-rear direction. That is, the two screws 80 facing the accommodation space S can be loosened and tightened with a tool inserted through the hole 56a of the rear support portion 56, so that the first movable body 43 can be removed without disassembling the arm portion 53. It is possible to attach and detach, and maintenance becomes easy.

  Furthermore, the two screws for fixing the wiring lid 85 to the arm portion 53 are in a state where the movable member 41 is positioned at the standby position with respect to the first device main body portion 47, and one of the screws of the first device main body portion 47. Since the outer side is exposed and positioned on the rear side, and the other side is exposed to the rear side facing the wiring passage 40c (see FIG. 12), the first device main body 47 of the wiring lid 85 is provided. Can be removed and installed without disassembling. Further, since the screw for fixing the wiring cover 86 to the arm portion 53 is exposed to the rear side, the wiring cover 86 can be attached and detached without disassembling the arm portion 53. That is, the wiring cover 86 and the wiring cover body 85 covering the wiring connected to the first light emitting substrate 73 from the rear side can be operated from the rear side of the first apparatus main body 47 without removing other components. Therefore, maintenance such as replacement of the wiring can be easily performed.

(About the action of the second movable effect device only)
In the standby position where the second motor 120 is stopped (not energized), the second movable effect device 38 has the tilting second movable body 88 and the linearly movable second movable body 89, as shown in FIG. On the right side of the display unit 13 a of the symbol display device 13, they are lined up and down with the straight line L in between. When the second motor 120 is driven and the operation member 105 of the second linkage mechanism 91 is displaced downward via the second transmission unit 95, the second movable effect device 38 is moved to the first cam hole of the operation member 105. The second operating rod 107 having one end connected to the second cam hole 94c of the 105c and the second cover member 94 via the roller member 119 and the other end connected to the tilted second movable body 88 is pushed down. As shown in FIG. 34, the tilting second movable body 88 supported by the parallel link mechanism 108 moves in a diagonally downward left direction from the standby position. When the rack member 106 of the second linkage mechanism 91 is lowered to the contact position, the rack member 106 comes into contact with the upper end of the first member 149 located at the original position in the third linkage mechanism 93, and the rack member As 106 is lowered, the first member 149 is pushed down against the elasticity of the compression coil spring 152.

  As the first member 149 is lowered, the operating pinion 148 engaged with the first member 149 rotates, and the second member 150 engaged with the operating pinion 148 on the side opposite to the first member 149 has a lower end. Ascending from the original position in contact with the upper walls 144b, 144b of the third transmission portion installation portion 144. As a result, the linearly movable second movable body 89 disposed on the second member 150 rises from the standby position toward the operating position. With the rack member 106 in contact with the first member 149, the second linkage mechanism 91 moves toward the second position, so that the tilting second movable body 88 moves linearly while moving diagonally downward to the left. 2 The movable body 89 moves vertically upward. At this time, before the linearly movable second movable body 89 reaches the interference position, the tilting second movable body 88 moves from the interference position to the operating position side, so that both the movable bodies 88 and 89 come into contact with each other and the operation is hindered. It will never be done.

  When the second linkage mechanism 91 arrives at the second position, as shown in FIG. 6, the tilted second movable body 88 is on the front side of the display unit 13a of the symbol display device 13, and is substantially Arrives at the central operating position. Further, the third linkage mechanism 93 reaches the movable position in a state where the rack member 106 and the first member 149 are in contact with each other, whereby the linearly movable second movable body 89 is arranged on the right side of the tilted second movable body 88. The operating position is reached (see FIGS. 36 to 38). The second motor 120 stops when the tilting second movable body 88 arrives at the operating position (the second linkage mechanism 91 is in the second position), and the tilting second movable body 88 and the linearly movable second movable body. 89 is held in the operating position.

  When the second motor 120 is driven in reverse, the actuating member 105 rises toward the first position, and the tilting second movable body 88 at the actuating position is directed diagonally upward to the right via the second linkage mechanism 91. Move in parallel. Further, as the rack member 106 of the second linkage mechanism 91 rises toward the first position, the first member 149 of the third linkage mechanism 93 biased by the compression coil spring 152 contacts the rack member 106. In this state, the rack member 106 rises as the rack member 106 rises. As a result, the second member 150 that meshes with the first member 149 via the operating pinion 148 descends from the movable position toward the original position, so that the direct-acting second movable body 89 at the operating position is parallel downward. Moving. At this time, since the linearly movable second movable body 89 moves from the interference position to the standby position side before the tilting second movable body 88 reaches the interference position, both the movable bodies 88 and 89 come into contact with each other and the operation is hindered. It will never be done.

  Then, the lower end of the second member 150 abuts against the upper walls 144b and 144b of the third transmission portion installation portion 144 so that the lowering is restricted and the second member 150 and the first member 149 are held in their original positions. The rack member 106 that continues to rise is separated from the first member 149, and the linearly movable second movable body 89 is held at the standby position (see FIG. 32). In addition, the second movable body 88 is retracted to the right side of the display unit 13a by stopping the second motor 120 at a predetermined timing after the second detection means 134 detects the second detection piece 135. It is held at the standby position. As shown in FIG. 31, the rack member 106 that moves in the vertical direction with respect to the second apparatus main body 96 has a front long hole 94e and a rear long hole 87a corresponding to the front protrusion 106a and the rear protrusion 106b, respectively. By being guided, it moves up and down without shaking in the left-right direction. Further, the movement of the rack member 106 in the front-rear direction is also suppressed by the operation member 105 and the second detection piece 135 disposed on the front protrusion 106a and the rear protrusion 106b on the front side and the rear side of the second device main body 96. .

  Here, when the second linkage mechanism 91 moves from the second position to the first position, it is stretched between the first link rod 109 constituting the parallel link mechanism 108 and the second device main body 96. The torsion coil spring 116 biases the first link rod 109 to rotate toward the second position. Accordingly, the parallel link mechanism 108 smoothly moves following the movement of the tilting second movable body 88, and the tilting second movable body 88 moves to the standby position while maintaining its posture. The first link rod 109 is guided to the back side of the upper extension portion 94d of the second cover member 94 by the guide projection 109a provided on the first link rod 109, and the first link rod 109 extends upward. It is prevented that the movement to the second position is hindered by being caught by the portion 94d.

  That is, in the second movable effect device 38, the two second movable bodies 88 and 89 can be operated by one second motor 120. In addition, since the second movable body 89 is configured to move by the third linkage mechanism 93 that mechanically contacts the second linkage mechanism 91 linked to the tilted second movable body 88, When a part of the orbit of the two movable bodies 88 overlaps with a part of the orbit of the second movable body 89, the two second movable bodies 88 and 89 are arranged in a limited space. Even if it exists, both the 2nd movable bodies 88 and 89 do not interfere in the middle of a movement, but the operation | movement effect intended by both 2nd movable bodies 88 and 89 can be performed. Moreover, since the two second movable bodies 88 and 89 are not operated by independent motors, respectively, the number of parts can be reduced and the installation space can be reduced and controlled as compared with the case where two motors are provided. The burden on the apparatus can be reduced.

  In the second movable effect device 38, as shown in FIG. 30, the second movable bodies 88 and 89 are linearly arranged in the vertical direction at the standby position of the second movable bodies 88 and 89. Since both the second movable bodies 88 and 89 change from the state to the operation positions arranged in the left-right direction shown in FIG. 6, the operation is interesting and an interesting production can be performed.

  In the second movable effect device 38, apart from the operation of reciprocating the two second movable bodies 88 and 89 largely between the standby position and the operating position, only the tilted second movable body 88 is contacted with the standby position and the contact position. The reciprocating motion can be performed in a partial range between. That is, the number of driving steps of the second motor 120 when the second detecting means 134 detects the second detection piece 135 and descends the tilting second movable body 88 is determined by the second linkage mechanism 91. When the rack member 106 drives the second motor 120 forward and backward until the rack member 106 does not contact the first member 149 of the third linkage mechanism 93, the tilting second movable body 88 reaches the standby position and the contact position. In the previous range, only the tilting second movable body 88 reciprocates.

  In the second movable effect device 38, the operation of reciprocating the two second movable bodies 88 and 89 largely between the standby position and the operating position and the operation of reciprocating only the tilting second movable body 88 are further described. Separately, only the linearly movable second movable body 89 can be reciprocated in the vertical direction within a partial range between the standby position and the operating position. That is, by repeating the excitation / demagnetization (energization / non-energization) of the solenoid 142 with the second motor 120 stopped driving while the tilting second movable body 88 is held at the standby position, the third Only the linearly movable second movable body 89 is moved up and down by the transmission portion 143. That is, by exciting the solenoid 142 and pulling the plunger 142a into the main body, as shown in FIG. , 144b is pushed up the second member 150 of the third linkage mechanism 93 in the original position with the lower end in contact with the lower end, and the linearly movable second movable body 89 is raised. Then, by demagnetizing the solenoid 142, the linearly movable second movable body 89 is lowered by the elasticity of the compression coil spring 152 and the weight of the linearly movable second movable body 89 itself, and the second member 150 is moved to the upper wall 144b, By abutting against 144b, the linearly movable second movable body 89 is held at the standby position. In this way, the direct-acting second movable body 89 moves up and down simply by repeating excitation and demagnetization of the solenoid 142.

  That is, in the second movable effect device 38, an effect of operating only the tilting second movable body 88 by driving the second motor 120 and a tilting second movable body 88 within the range in which the second linkage mechanism 91 is moved. Further, it is possible to perform an effect in which the two movable bodies 88 and 89 of the linearly movable second movable body 89 operate in conjunction with each other, and an interesting production can be implemented with a small number of parts. In addition, since the second linkage mechanism 91 and the third linkage mechanism 93 are configured to be mechanically connectable / separable, the state in which only one movable body is operated by the mechanical configuration of the linkage mechanism and the two movable bodies are arranged. The mechanism can be simplified and the cost can be reduced as compared with a configuration that changes to a state of operating in synchronization.

  Furthermore, in the second movable effect device 38, the direct-acting second movable body 89 can be operated by the solenoid 142, so that the direct-acting second movable body 89 can be operated alone to produce effects. The entertainment can be further improved by performing the action pattern. Further, the range in which the linearly movable second movable body 89 is operated by the solenoid 142 is the standby position side from the interference position where the linearly movable second movable body 89 does not interfere with the inclined second movable body 88 and Since the first member 149 of the three linkage mechanism 93 is configured to move the third linkage mechanism 93 within a range that does not contact the rack member 106 in the second linkage mechanism 91 at the first position (see FIG. 39), When the movable second movable body 89 is operated alone, the linearly movable second movable body 89 interferes with the tilted second movable body 88, or the third linkage mechanism 93 comes into contact with the second linkage mechanism 91. Thus, the tilted second movable body 88 can be prevented from performing an unintended operation. The control of the solenoid 142 is lighter than the control of the motor, and the load on the control device when driving both the second motor 120 and the solenoid 142 is less than when using two motors. Can be kept small.

  In the second movable effect device 38, the rack member 106 and the first member 149 of both the mechanisms 91 and 93 are separated at the first position of the second linkage mechanism 91 and the original position of the third linkage mechanism 93 (FIG. 33). The rack member 106 is configured to contact the first member 149 between the contact position of the second linkage mechanism 91 and the second position (see FIGS. 34, 35, 37, and 38). Further, the second operating body 147 of the third transmission unit 143 and the second member 150 are in contact with each other at the original position of the third linkage mechanism 93. As shown in FIG. 34, when the rack member 106 contacts the first member 149 and the third linkage mechanism 93 moves from the original position to the movable position, the second member 150 of the third linkage mechanism 93 moves. The third transmission unit 143 is configured to move in a direction away from the second operating body 147. That is, when the second movable body 89 is moved from the standby position to the operating position by driving the second motor 120, the second member 150 is mechanically separated from the third transmission portion 143. No load is applied to the third transmission unit 143 or the solenoid 142.

  Further, when the first member 149 and the rack member 106 are in contact with each other, as shown in FIG. Furthermore, when the solenoid 142 is excited and the second operating body 147 contacts and pushes up the second member 150, the first member 149 moves in a direction away from the rack member 106. Even in this case, no load is applied to the second motor 120 via the second linkage mechanism 91. That is, the second linkage mechanism 91 and the third linkage mechanism 93, and the third linkage mechanism 93 and the third transmission portion 143 can be mechanically separated from each other, and the second linkage mechanism 91 and the third linkage are connected. When the mechanism 93 is linked and the driving force of the second motor 120 is applied to the third linkage mechanism 93, the third linkage mechanism 93 moves away from the third transmission portion 143, and the third transmission is performed. When the driving force of the solenoid 142 is applied to the third transmission unit 143 when the part 143 and the third connection mechanism 93 are connected, the third connection mechanism 93 moves in a direction away from the second connection mechanism 91. Therefore, even when the second motor 120 and the solenoid 142 are driven when not intended, the second motor 120, the solenoid 142, the second linkage mechanism 91, and the third linkage mechanism 93 are driven. Preliminary unnecessary load is not applied to the third transmission unit 143, etc., can prevent the occurrence of failure of these members.

(About the interaction between the first, second and third movable effect devices)
The first movable body 43 maintains the same posture at the standby position and the operating position, and the first pattern 43a formed on the first movable body 43 has the same pattern at the standby position and the operating position. Can be recognized. Further, the tilting second movable body 88 and the linearly movable second movable body 89 also maintain the same posture at the standby position and the operating position, and the second movable bodies 88 and 89 formed on the second movable bodies 88 and 89 have the same posture. The two symbols 88a and 89a can be recognized as the same symbol in the standby position and the operating position. The third movable body 154 also maintains the same posture at the standby position and the operating position, and the third symbol 154a formed on the third movable body 154 is the same at the standby position and the operating position. It can be recognized as a symbol. However, the third movable body 154 is only partially visible on the back side of the stage 29 and the transparent wall 31 of the decorative member 28 at the standby position, and is formed on the third movable body 154. The player cannot clearly recognize the entire third symbol 154a.

  In the first movable effect device 37, when the first movable body 43 is moved from the standby position toward the operating position, the first movable body 43 is displayed from the substantially upper center of the display unit 13a of the symbol display device 13. The front side of the part 13a is translated in a diagonally downward left direction, and arrives at the operating position biased to the left side at the center in the vertical direction of the display part 13a (see FIG. 6). Moreover, in the said 2nd movable production | presentation apparatus 38, if both the 2nd movable bodies 88 and 89 move toward a working position from a stand-by position, the direct-acting 2nd movable body 89 of the display part 13a of the symbol display apparatus 13 will be shown. The second movable body 88 is moved in parallel from the lower right side toward the upper side, and the second movable body 88 is moved in parallel from the upper right side of the display unit 13a toward the lower left side of the display unit 13a. Then, the linearly movable second movable body 89 arrives at the operation position that is linearly aligned along the upper side with respect to the first movable body 43 at the operation position at the center in the vertical direction of the display unit 13a. The two movable bodies 88 arrive at the operation position that is linearly arranged along the upper side between the first movable body 43 and the linearly movable second movable body 89 at the operation position at the center in the vertical direction of the display unit 13a (see FIG. 6). The first symbol 43a formed on each movable body 43, 88, 89 in a state where the first movable body 43 and the two second movable bodies 88, 89 are arranged in a straight line on the front side of the display portion 13a. The second symbol 88a and the second linear motion symbol 89a form a series of meaningful symbols. Further, in the third movable effect device 39, when the third movable body 154 is moved from the standby position toward the operating position, the third movable body 154 is straight on the front side of the display portion 13a of the symbol display device 13. The first movable body 43 and the second movable bodies 88 and 89 that are arranged in a line arrive at the operating position arranged below the second movable bodies 88 and 89 (see FIG. 6). The third symbol 154a formed on the third movable body 154 forms a meaningful series of symbols together with the first symbol 43a, the second symbol 88a for tilting, and the second symbol 89a for linear motion arranged in a straight line.

  That is, when a series of symbols is formed on the front side of the display unit 13a of the symbol display device 13, the movable bodies 43, 88, and 154 come out from the plurality of sides of the display unit 13a to the front side of the display unit 13a. It is interesting and can improve the fun of the game. In particular, the first movable body 43 and the tilted second movable body 88 do not move in a direction orthogonal to the corresponding side, but move obliquely, so that the movable body 43 is formed when forming a series of symbols. , 89's movement is not monotonous, complicated and interesting, and can enhance interest. Moreover, since the tilting second movable body 88 moves so as to enter obliquely from above between the first movable body 43 and the linearly movable second movable body 89 at the operating position, the movement of the movable body is interesting, and more It can enhance interest. Further, as shown in FIG. 6, the first movable body 43 and the two second movable bodies 88 and 89 arranged in a straight line are located in a series in the entire horizontal direction at the center in the vertical direction of the display unit 13a. It can have a big impact on the player and can be differentiated from other models.

  In the embodiment, a meaningful series of symbols is formed only by the symbols 43a, 88a, 89a formed on the three movable bodies 43, 88, 89 linearly arranged in the left-right direction. By arranging the three movable bodies 154 on the lower side, a meaningful series of symbols is formed together with the third symbols 154a formed on the third movable body 154. In this case, since the third symbol 154a of the third movable body 154 cannot be clearly recognized from the front side as a whole at the standby position as described above, the third movable body 154 moves from the standby position to the operating position. The third symbol 154a, which can be recognized from the front side as a whole, is combined with a series of symbols linearly arranged on the upper side to form a series of symbols, thereby enhancing the interest.

  Here, in the first linkage mechanism 44 that moves the first movable body 43, when the second roller body 83 of the first operating rod 79 is guided through the curved portion 84b having a small curvature in the cam groove 84, The first movable body 43 moves substantially linearly in the vertical direction with almost no displacement in the horizontal direction. That is, the first movable body 43 can be moved to the operating position without interfering with the tilting second movable body 88 that moves obliquely from the right side of the display unit 13a to the operating position, and In the operating position, the tilting second movable body 88 and the first movable body 43 can be positioned close to each other. Thereby, it is possible to suppress a sense of discomfort in a series of symbols formed in a series with a large separation between the first movable body 43 and the tilted second movable body 88 that are linearly arranged in the left-right direction.

  As shown in FIG. 5, the first movable body 43 that has moved from the operating position to the standby position is located at the center of the upper side of the display unit 13a of the symbol display device 13, and two second movable bodies 43 that have moved from the operating position to the standby position. The movable bodies 88 and 89 are positioned side by side in the vertical direction on the right side of the display unit 13a. At this time, the first symbol 43a of the first movable body 43 located on the upper side of the display unit 13a and the second symbols 88a and 89a of the two second movable bodies 88 and 89 located on the right side of the display unit 13a are: A pattern common to the series of symbols formed at the operating position is formed side by side in the bowl shape. That is, even in the standby state of the first movable body 43 and the second movable bodies 88 and 89, meaningful symbols can be displayed on the symbols 43a, 88a, and 89a, and the decoration effect can be improved.

  Here, the configuration of a series of symbols formed by the symbols 43a, 88a, 89a, 154a of the movable bodies 43, 88, 89, 154 will be described more specifically. For example, the characters “Pachi” as the first symbol 43a, “N” as the second symbol 88a for tilting, “ko” as the second symbol 89a for linear motion, and “Game” as the third symbol 154a are formed. To do. In this case, the first movable body 43, the tilted second movable body 88, and the linearly movable second movable body 89 move to the operating position, so that the front side of the display unit 13a is moved in the left-right direction. Lined up “Pachinko” symbols are formed in a series, which can improve the interest of the player. Further, by moving the third movable body 154 to the lower operating position of the three movable bodies 43, 88, and 89 arranged in the left-right direction, the “pachinko game” can be played in two steps on the front side of the display unit 13a. A series of symbols is formed, which can further enhance the interest of the player. Further, in the standby position, the first movable body 43 is positioned on the upper side of the display unit 13a, and the second movable bodies 88 and 89 are positioned side by side on the right side of the display unit 13a. A series of “Pachinko” patterns are formed from the upper side to the right side, and each movable body 43, 88, 89 not only displays a meaningless design but also a series of meaningful designs. Thus, the decorativeness of the first movable body 43, the tilted second movable body 88, and the linearly movable second movable body 89 in the standby state can be improved.

(Example of change)
The present application is not limited to the configuration of the above-described embodiment, and other configurations can be appropriately employed.
(1) In the embodiment, the game board is made of a wooden board member, but it may be made of a transparent board made of a transparent material such as acrylic.
(2) In the embodiment, the rack and pinion mechanism is adopted as the mechanism for reciprocating the movable member of the first movable effect device, but other mechanisms such as a link mechanism can be used.
(3) In the embodiment, the first movable body arranged on the movable member in the first movable effect device is positioned at the center in the left-right direction on the upper side of the display unit at the standby position and on the left side of the display unit at the operating position. However, it may be configured to be biased and positioned on the right side of the display unit at the operating position. Further, the first movable body may be configured to be biased and positioned on either the left or right side on the upper side of the display unit at the standby position, and to be positioned at the center in the left-right direction of the display unit at the operating position.
(4) In the embodiment, regarding the first movable body arranged on the movable member in the first movable effect device, the upper side of the display unit is set as the standby position, but the lower side of the display unit may be set as the standby position. In this case, the horizontal relationship between the standby position and the operating position with respect to the display unit can be as in the modified example (3).
(5) In the embodiment, the first device main body of the first movable effect device is arranged on the left side of the display unit. However, a configuration of arranging the first device main unit on the right side of the display unit may be adopted.
(6) In the embodiment, the magnet is disposed on the first device main body of the first movable effect device and the metal plate is disposed on the movable member. However, the objects to be disposed of the magnet and the metal plate are opposite to those of the embodiment. It may be provided, or both may be provided with magnets.
(7) In the embodiment, regarding the two second movable bodies arranged in the second movable effect device, one of them is reciprocated linearly (vertically) in the vertical direction, and the other is diagonally intersecting with the one movement direction. However, the moving directions of the two second movable bodies may be parallel to each other.
(8) In the embodiment, the compression coil spring is used as the return means for urging the third linkage mechanism of the second movable effect device toward the original position, but the elasticity of the tension coil spring, various types of springs, rubber, etc. is used. It is possible to adopt an elastic means having. Further, if the weight of the linearly movable second movable body acts so as to bias the third linkage mechanism toward the original position as in the embodiment, the elastic means such as a spring and rubber are omitted. Only the weight of the movable second movable body can be used as the return means.
(9) In the embodiment, the second movable effect device is arranged on the right side of the display unit. However, a configuration in which the second movable effect device is arranged on the left side, the upper side, or the lower side of the display unit may be adopted.
(10) In the embodiment, the trajectories of the two second movable bodies in the second movable effect device are configured to partially overlap. However, it is possible to employ a configuration in which the trajectories of the two second movable bodies do not overlap at all. it can. In the configuration in which the trajectories of the two second movable bodies partially overlap, when the second movable bodies move between the standby position and the operating position, the second movable bodies are operated so as not to interfere with each other. What is necessary is that the second movable body does not have to start moving after the other second movable body moves to a position away from the track of the one second movable body.
(11) In the embodiment, the driving force of the solenoid of the second movable effect device is configured to be indirectly transmitted to the third linkage mechanism via the third transmission portion, but the third linkage mechanism is directly operated by the solenoid plunger. You may comprise.
(12) In the embodiment, the solenoid is used as the driving means for moving the linearly movable second movable body of the second movable effect device alone, but a motor can be used. For example, in the case of using a motor, any configuration that can be connected to and separated from the third linkage mechanism, such as a configuration in which the third transmission unit is operated by a cam rotated by the motor or the third linkage mechanism is moved directly, is used. Other configurations may be employed.
(13) In the embodiment, the first movable body waits outside the upper side of the display unit, and the second movable body waits side by side in a state where it overlaps the front side of the right side of the display unit. The first movable body may wait in a state where it overlaps the front side of the upper side of the display unit, or the second movable body may wait on the outer side of the right side of the display unit.
(14) In the embodiment, the lower second movable body among the two second movable bodies arranged vertically on the right side of the display unit is linearly moved in the vertical direction along the right side. It is possible to adopt a configuration in which the two movable bodies are linearly moved in the vertical direction along the right side, and the lower second movable body is moved obliquely upward to the left.
(15) In the embodiment, the first movable body is positioned on the upper side of the display unit at the standby position and the two second movable bodies are positioned side by side on the right side of the display unit. The side on which the movable body and the second movable body are located may be two sides that intersect, and for example, the following configurations (a) to (c) can be employed.
(a) In the configuration in which the first movable body is moved from the center of the upper side of the display unit to the operating position biased to the right side, the second movable body is arranged side by side on the left side of the display unit. In this case, the second movable body that moves linearly in the vertical direction along the left side may be an upper one or a lower one.
(b) In the configuration in which the first movable body is moved from the center of the lower side of the display unit to the operating position biased to the left side or the right side, the second movable body is arranged vertically on the right side or the left side of the display unit. In this case, one of the second movable bodies moving linearly in the vertical direction along the right side or the left side may be the upper one or the lower one, and the other second movable body is the first one that has reached the operating position. What is necessary is just to comprise so that it may enter between a movable body and one 2nd movable body, and may move to the position located in a line in the left-right direction.
(c) In the configuration in which the first movable body is moved to the operation position biased from the center of the right side or the left side of the display unit toward the upper side or the lower side, the second movable body is arranged in the left-right direction on the upper side or the lower side of the display unit. Deploy. In this case, one of the second movable bodies moving linearly in the left-right direction along the upper side or the lower side may be the right one or the left one, and the other second movable body is the first movable body that has reached the operating position. What is necessary is just to comprise so that it may enter between a body and one 2nd movable body, and may move to the position located in a line in the up-down direction.
(16) In the second movable effect device according to the embodiment, the case where two second movable bodies are provided has been described. However, the number of the second movable bodies may be three or more, along the corresponding side at the standby position. Any one of the plurality of second movable bodies arranged side by side moves to the operating position, so long as the first movable body changes so as to be arranged in a straight line along the side on which the first movable body is waiting.
(17) In the embodiment, the description has been given by using characters as the symbols formed on the first movable body and the second movable body, but for example, a figure of a character that becomes a motif of a pachinko machine, and the like, As long as the symbols are arranged, a meaningful series of symbols may be formed.
(18) The gaming machine is not limited to a pachinko machine, and may be various other gaming machines such as an arrangement ball machine or a slot machine using a pachinko ball.

38 Second movable effect device (movable effect device)
88 tilting second movable body (first movable body)
89 Direct-acting second movable body (second movable body)
91 Second linkage mechanism (first actuation mechanism)
93 Third linkage mechanism (second actuation mechanism)
96 Second device body (device body)
106 Rack member (pressing member)
107 Second operating rod (operating rod)
108 Parallel link mechanism 120 Second motor (drive means)
148 Actuation pinion (linkage)
149 First member 150 Second member 152 Compression coil spring (return means)

Claims (3)

In a gaming machine equipped with a movable effect device that produces effects by movement,
The movable effect device is:
A first actuating mechanism connected to the driving means and moving between the first position and the second position by the driving of the driving means;
A first movable body connected to the first operating mechanism and moving with the movement of the first operating mechanism;
The first operating mechanism is brought into contact and separated in the process of moving between the first position and the second position. With the first operating mechanism in contact, the first operating mechanism moves between the original position and the movable position as the first operating mechanism moves. A second actuating mechanism that moves;
A second movable body connected to the second operating mechanism and moving with the movement of the second operating mechanism;
Return means for urging the second operating mechanism toward the original position before the first operating mechanism contacts,
The first operating mechanism is separated from the second operating mechanism at the first position, and the first operating mechanism moves between a contact position between the first position and the second position and the second position. Is a gaming machine characterized in that the first operating mechanism is in contact with the second operating mechanism.   The first movable body and the second movable body are configured so that the tracks of the first movable body and the second movable body partially overlap each other, and when the first operating mechanism moves between the contact position and the second position, The gaming machine according to claim 1, wherein the gaming machine is configured to move at a position off the track of the second movable body. The second movable body is located below the first movable body located at the standby position at the first position of the first operating mechanism;
The first actuating mechanism is connected to a pressing member that moves linearly in the vertical direction by driving of the driving means, an apparatus main body of the movable effect device, and a first movable body, and the first movable body. A parallel link mechanism that supports the first movable body, and the first movable body that is connected to the pressing member and the first movable body and supported by the parallel link mechanism along with the linear movement of the pressing member. An operating rod that moves between a position and an operating position diagonally downward from the standby position;
The second actuating mechanism includes a first member that can be brought into contact with and separated from the pressing member and linearly movable in a vertical direction, and is disposed on the second movable body and is connected to the first member via a connecting body. And a second member that is linearly moved in the reverse direction with the movement of the first member.
When the first actuating mechanism moves from the first position to the second position, the pressing member contacts the first member at the contact position and presses downward, so that the second via the connecting body. 3. The gaming machine according to claim 1, wherein the second movable body is moved to a position where the member moves upward and is aligned with a side of the first movable body that has arrived at the operating position.

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