JP2015198750A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To increase a posture stability of a movable body separately at a standby position and a movable position by using a magnet.SOLUTION: An upper movable presentation device includes: a movable body 61 for reciprocating between a standby position and a movable position in conjunction with the driving of a drive motor 150; a magnet 75 provided in the movable body 61; a first sheet metal member 93 which is provided in a device body 80 relatively displacing its position with respect to the movable body 61 in conjunction with the reciprocating movement of the movable body 61, and to which the magnet 75 magnetically attaches when the movable body 61 is at a standby position; and a second sheet metal member 133 which is provided in a support arm 121 relatively displacing its position with respect to the movable body 61 in conjunction with the reciprocating movement of the movable body 61, and to which the magnet 75 magnetically attaches when the movable body 61 is at a movable position. Since the one piece of magnet 75 provided in the movable body 61 magnetically attaches to the first sheet metal member 93 and the second sheet metal member 133 respectively, the movable body 61 is supported at both standby position and movable position in conjunction with the reciprocating movement.

Description

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

  A pachinko machine as a kind of gaming machine is provided with a frame-shaped decorative body (so-called center role) formed in a frame shape at a substantially central position of a gaming area defined on the surface of the gaming board. A display device such as a liquid crystal type or a drum type that displays a plurality of symbols in a variably displayed manner through the opening of the decorative ornament is faced from the rear, and a lower position of the frame-like decorative member on the game board In addition, there are many proposals that are configured to provide a start winning part that starts symbol variation on the symbol display device by winning a pachinko ball (game ball) and a special winning part that is opened when a winning game occurs. Yes. In such a pachinko machine, the pachinko ball launched into the game area gradually flows down due to its own weight while bouncing off by contact with a game nail or the like implanted in the game area, and starts in the process of flowing down the game area. A lottery regarding whether or not to generate a winning game is performed by winning the winning section, and various game effects such as a reach effect for reporting the result of the lottery to the player are performed on the symbol display device. When the symbols are stopped in a predetermined combination on the display device, the special winning portion is opened and a large number of prize balls can be obtained.

  In such a pachinko machine, in addition to the symbol display device that performs the symbol variation effect, a movable effect device that performs a movable effect by a required operation is provided, and the movable body provided in the movable effect device is performed by the symbol display device. It has been proposed to increase the visual effect by operating according to the game effect. For example, Patent Document 1 discloses a configuration in which a movable body that swings between a position retracted from the front side of the display unit of the symbol display device and a position overlapping the front side of the display unit of the symbol display device is disclosed. Yes.

JP 2003-190401 A

  Here, in the movable effect device described in Patent Document 1, a magnet is magnetically attached to the suction plate in a state where the movable body is in a position retracted from the front side of the display unit of the symbol display device, so that the movable body is moved at the position. It is designed to hold it stably. However, when the movable body swings to a position overlapping the front side of the display unit of the symbol display device, the magnet is not magnetically attached to the attracting plate, and the posture stability of the movable body is excellent. Absent. In this case, by providing another magnet on the movable body, and providing an adsorption plate on which the other magnet is magnetically attached when the movable body swings to a position overlapping the front side of the display unit of the symbol display device. Although it is possible to increase the stability of the movable body even at the position, there is a problem that increases the cost by adding a magnet. In addition, the pachinko machine is configured to install a magnetic sensor to detect fraud using a magnet, but the magnetic sensor is located at a position that does not react to the magnet (magnet provided on the movable body) provided in the pachinko machine. Therefore, the movement of the movable body with the movement of multiple magnets may restrict the installation location of the magnetic sensor, which may hinder the detection of fraud using the magnet. There is concern about coming.

  That is, the present invention has been proposed in order to solve this problem in view of the above-mentioned problems inherent in the gaming machine according to the prior art, and uses a single magnet for each of the standby position and the movable position. An object of the present invention is to provide a gaming machine capable of improving the posture stability of the movable body.

In order to solve the above problems and achieve the intended purpose, the invention according to claim 1 of the present application is
In gaming machines equipped with movable production means (60A, 60B) that produce production by movement,
The movable effect means (60A, 60B)
A movable body (61, 62) that reciprocates between a standby position and a movable position in accordance with driving of the driving means (150);
One magnet (75) provided on the movable body (61, 62);
The magnet is provided at a position relatively displaced with respect to the movable body (61, 62) as the movable body (61, 62) reciprocates, and the movable body (61, 62) is in a standby position. A first magnetized member (93) on which (75) is magnetized;
The magnet is provided at a position relatively displaced with respect to the movable body (61, 62) as the movable body (61, 62) reciprocates, and the movable body (61, 62) is in a movable position. A second magnetically bonded member (133) on which (75) is magnetically bonded,
One magnet (75) provided on the movable body (61, 62) is magnetically attached to each of the first magnetic attachment member (93) and the second magnetic attachment member (133), thereby enabling reciprocal movement. Accordingly, the gist is that the movable body (61, 62) is configured to be held at both the standby position and the movable position.

  In this way, one magnet provided on the movable body is magnetically attached to the first magnetized member in a state where the movable body is in the standby position, and the one magnet is in the state where the movable body is in the movable position. By being configured to be magnetically attached to the two magnetic attachment members, it is possible to improve the posture stability of the movable body regardless of the standby position or the movable position. At this time, since only one magnet needs to be provided on the movable body, the cost of the movable effect device is not increased. In addition, since only one magnet moves in accordance with the operation of one movable body, the installation position of the magnetic sensor provided in the gaming machine is not excessively restricted, and the degree of freedom in design of the movable effect device is improved. To do.

The invention according to claim 2
The movable effect means (60A, 60B)
A support portion (121, 122) that reciprocates as the drive means (150) is driven is provided, and the movable body (61, 62) moves relative to the support portion (121, 122) as the support portion (121, 122) reciprocates. Configured to displace
The movable body (61, 62) is configured to reciprocate between a standby position and a movable position by reciprocating the support portions (121, 122) as the driving means (150) is driven. The gist.
As described above, the movable body is configured such that the movable body is displaced in posture with respect to the support portion that reciprocates as the driving unit is driven, so that the operation range of the movable body can be expanded. . Moreover, even if the operation range of the movable body is expanded, the movable body can be stably held by the single magnet at each of the standby position and the movable position.

The invention according to claim 3
The movable effect means (60A, 60B)
A base portion (80) on which the driving means (150) is disposed, and the support portions (121, 122) are configured to reciprocate relative to the base portion (80).
The first magnetized member (93) is disposed on the base portion (80), and the second magnetized member (133) is disposed on the support portions (121, 122). The gist.
As described above, by disposing the first magnetized member on the base portion on which the driving means is provided, the movable body can be held in a stable posture with respect to the base portion at the standby position, and with respect to the base portion. By disposing the second magnetized member on the reciprocating support portion, the movable body can be held in a stable posture with respect to the support portion at the movable position. For this reason, while the stand-by position can enhance the sense of unity between the base portion and the movable body, the sense of unity between the support portion and the movable body can be enhanced at the movable position.

The invention according to claim 4
The one end side of the support portion (121, 122) is swingably supported with respect to the base portion (80), and the support portion (121, 122) swings on the other end side of the support portion (121, 122). An intermediate position in the longitudinal direction of the movable body (61, 62) is supported so as to be rotatable about an axis parallel to the axis,
The magnet (75) is disposed on the movable body (61, 62) so as to be positioned outwardly away from the swing shaft (88) of the support portion (121, 122) at the standby position, and The gist is that a certain magnet (75) is configured to be magnetically attached to the first magnetic attachment member (93) disposed in the base portion (80).
As described above, the movable body can be stably held at the standby position with a small magnetic force by magnetizing the magnet to the first magnetic adhesion member at the outer position away from the swing shaft of the support portion at the standby position. Can do.

  According to the gaming machine according to the present invention, the movable body can be stably held at the standby position and the movable position by one magnet provided on the movable body.

It is a front view which shows the pachinko machine which concerns on the Example of this invention. (a) is a front view showing the game board, the state where the movable body has moved to the movable position is shown by a two-dot chain line, (b) is a front view showing the installation member provided with the upper and lower movable effect device . It is a disassembled perspective view of the upper movable production | presentation apparatus which concerns on an Example. It is a disassembled perspective view of the upper movable production | presentation apparatus which concerns on an Example, Comprising: The state which decomposed | disassembled the movable body and the support arm from the apparatus main body is shown. It is a front view of the upper movable production | presentation apparatus which concerns on an Example, Comprising: The state which has a support arm and a movable body in a standby position is shown. It is a front view of the upper movable production | presentation apparatus which concerns on an Example, Comprising: The state which has a support arm and a movable body in a movable position is shown. (a) is a rear view of the first movable body, (b) is an exploded perspective view of the first movable body as viewed from the rear side, and (c) is an enlarged view of a magnet installation portion in the first movable body. FIG. It is a front view which shows the apparatus main body which concerns on an Example, Comprising: The installation site | part of a 1st movable body is expanded and shown. (a) is the disassembled perspective view which looked at the 1st support arm from the front side, (b) is the disassembled perspective view which looked at the 1st support arm from the back side. It is the front view which expands and shows the principal part which carried out the upper movable production | presentation apparatus which concerns on an Example longitudinally in the formation position of the gear accommodating part of a 1st support arm, Comprising: (a) is a support arm and a movable body in a standby position (B) shows a state where the support arm and the movable body are in the movable position. It is a rear view which expands and shows the principal part which carried out the upper movable production | presentation apparatus based on an Example longitudinally in the formation position of the wiring accommodating part of a 1st support arm, Comprising: (a) is a support arm and a movable body in a standby position (B) shows a state where the support arm and the movable body are in the movable position. It is the sectional view on the AA line of FIG. It is an enlarged view which shows the wiring accommodating part of the 1st support arm which concerns on an Example, (a) shows the state which has a support arm and a movable body in a stand-by position, (b) has a support arm and a movable body in a movable position. Shows the state.

  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 10 that plays a game using a pachinko ball as a game ball will be described as an example. In the following description, “front”, “rear”, “left”, and “right” refer to the pachinko machine 10 viewed from the front side (player side) as shown in FIG. 1 unless otherwise specified. Named by state.

(About pachinko machine 10)
As shown in FIG. 1, the pachinko machine 10 according to the embodiment is formed in a rectangular frame shape that opens front and rear, and an outer frame 11 as a fixed frame that is installed in a vertically installed posture on an installation frame base (not shown) of a game shop. An inner frame 12 (not shown) as a main body frame that detachably holds the game board 20 is detachably assembled to the front side of the opening, and a predetermined condition is established on the back side of the game board 20 ( When the pachinko ball is won at the starting winning opening of the first or second starting winning portion 35, 41, which will be described later), the display design 17a is variably displayed on the display portion 17a. The symbol display device 17 to be performed is detachably disposed. In addition, the front side of the middle frame 12 is configured to cover the window portion 13a opening front and rear with a glass plate for transparently protecting the game board 20 and a transparent protective plate 13b formed of a transparent synthetic resin material. The front frame 13 is assembled so as to be openable and closable, and a lower ball tray 15 for storing pachinko balls is assembled below the front frame 13 so as to be openable and closable. In the embodiment, an upper ball tray 14 for storing pachinko balls is integrally assembled at a lower position of the front frame 13, and the upper ball tray 14 is also opened and closed integrally with the opening and closing of the front frame 13. Configured to do. Further, the upper ball tray 14 may be formed separately from the front frame 13. The ball trays 14 and 15 are not limited to those provided with the upper and lower two ball trays 14 and 15, and only one ball tray 14 and 15 may be provided.

  The symbol display device 17 employs a liquid crystal display device in which a liquid crystal panel capable of displaying various symbols is accommodated in an accommodation case. The symbol display device 17 according to the embodiment is provided with three rows of symbol display portions (not shown) that can display the decorative drawing in a row, and the decorative drawing of each row is displayed along with the start of the symbol changing effect. By displaying the change in a predetermined change direction (for example, the vertical direction from top to bottom, the horizontal direction from right to left, etc.), and displaying all the decorations in each row at a predetermined timing, once The symbol variation production is finished. In the embodiment, the decoration drawing is basically configured to be variably displayed in the vertical direction. As the symbol display device 17, various conventionally known symbol display devices 17 capable of stopping and variably displaying various symbols such as a drum-type symbol display device 17 and a dot matrix-type symbol display device 17 can be adopted.

  An operation handle 16 for operating a ball striking device (not shown) disposed on the middle frame 12 is provided at a lower right position of the front frame 13. The operation handle 16 includes an operation lever 16a urged in the left rotation direction. When the player turns the operation lever 16a to rotate right, the hitting ball launching device is operated, Pachinko balls stored in the ball tray 14 are launched toward the game board 20. Here, the hitting force of the pachinko ball by the hitting ball launching device is changed in strength according to the turning amount of the operation lever 16a, and the player operates the turning amount of the operation lever 16a, so that the game area The so-called “left-handed” in which the pachinko ball launched into 22 flows down the left side of the frame-shaped decorative body 50 and the so-called “right-handed (rubber-launched)” in which the pachinko ball flows down the right side of the frame-shaped decorative body 50. It can be arranged separately.

(About game board 20)
As shown in FIG. 2, the game board 20 of the embodiment includes a plate-like member (game region forming member) 21 in which a game region 22 in which a pachinko ball can flow down is formed on the front side, and the plate-like member 21. An installation member (accommodating space defining member) 45 is provided on the back side and defines an accommodating space 47 between the plate-like member 21 and the plate-like member 21. The plate-like member 21 is formed in a substantially rectangular shape with a predetermined plate thickness from a synthetic resin material, a veneer material, etc., and a pachinko ball can flow down by a substantially circular guide rail 23 disposed on the front surface (board surface). A game area 22 is defined. The plate-like member 21 of the embodiment is a transparent plate formed from an acrylic resin, and the housing space 47 can be seen through from the front side of the plate-like member 21. Further, in the accommodation space 47 between the plate-like member 21 and the installation member 45, movable effect devices 60A and 60B that perform effects by the operation of the movable bodies 61 and 62 are installed. In addition to the movable effect devices 60A and 60B, various members such as a light emission effect device (not shown) that produces an effect by light emission are installed in the accommodation space 47. That is, it is configured such that the player can visually see the movable effect devices 60A, 60B and other members disposed in the accommodation space 47 from the front side of the game board 20 through the transparent plate member 21. The symbol display device 17 is attached to the back side of the installation member 45 and is provided in an opening (visible part) 45c provided in the installation member 45 and an opening 50a of the frame-shaped decorative body 50 (described later) as will be described later. It is configured so as to be visible from the front side of the game board 20 through the disposed transparent panel 51.

  As shown in FIG. 2, the guide rail 23 includes an outer rail 24 formed in an arc shape that bulges leftward from the lower left portion of the plate member 21 to the upper right portion, and an upper right portion of the plate member 21. The inner rail 25 is formed in an arc shape that bulges in the right direction so as to reach the lower right portion and the upper left portion. The inner rail 25 is connected to the upper right end portion of the outer rail 24 and is disposed from the upper right portion to the lower portion of the plate-like member 21, and the board decoration member 25 a is formed in an arc shape whose left end edge is recessed rightward. And a rail member 25b disposed from the lower part of the plate-like member 21 to the upper left part, connected to the lower end of the panel decoration member 25a, and spaced apart to the right (inner side) of the outer rail 24. The launching passage 26 that is configured and through which one pachinko ball can pass is defined by the outer rail 24 and the rail member 25b. Here, the rail member 25 b constituting the inner rail 25 is arranged so that the open end faces the upper left portion of the plate-like member 21, and defines a launch port that opens to the game area 22 between the rail member 25 b and the outer rail 24. The pachinko ball launched from the hitting ball launcher flies from the lower opening of the launch passage 26 and is launched into the game area 22 from the launch port.

  In the plate-like member 21, a mounting opening (not shown) penetrating in the front-rear direction is opened at an appropriate position in the game area 22, and various game board installation parts are arranged for each mounting opening. In the gaming board 20 of the embodiment, the frame-shaped decorative body 50, the first starting winning part 35, the second starting winning part 41, the special winning part 42, the normal winning part 38, the gate part are provided as game board installation parts. A mounting opening for installing 43 and the like is formed. In the plate-like member 21 of the game board 20, an out port 30 for discharging the pachinko ball that has flowed down to the lowest position of the game area 22 to the outside of the game board 20 is opened at the lowest position of the game area 22. Yes. The out port 30 is formed at the lowermost position of the game area 22 and is configured so that both pachinko balls flowing down the left and right sides of the frame-shaped decorative body 50 can arrive. That is, a pachinko ball that is launched from the hitting ball launching device and flows down the game area 22 is provided in the game board installation part (a first start winning part 35, a second start winning part 41, a special prize). Part 42, the normal winning part 38, the gate part 43, etc.), a predetermined game such as paying out a winning ball according to the entered part and executing a symbol variation effect is performed. The pachinko ball that has flowed down to the lowest part of 22 is configured to be discharged to the outside through the out port 30. Note that the number of the mounting openings is appropriately determined according to the arrangement position and the number of game board installation parts attached to the plate-like member 21.

  The plate-like member 21 is provided with a large number of game nails 32 in the game area 22, and a pachinko ball flowing down the game area 22 is brought into contact with the left side of a frame-shaped decorative body 50 described later. The rotating guide member 33 that is rotated in this manner is rotatably supported, and the flow direction of the pachinko balls changes irregularly by contact with the game nail 32 and the rotating guide member 33. The rotation guide member 33 is a member also referred to as a so-called “windmill”, and is a member that releases in the left-right direction so as to play a pachinko ball as the rotation guide member 33 rotates.

  As shown in FIG. 2, the plate-like member 21 of the embodiment is formed in a frame shape that opens back and forth in a mounting opening in which a large portion of the approximate center of the game area 22 surrounded by the guide rail 23 opens. The frame-shaped decorative body 50 is attached, and the opening 45 c of the installation member 45 is positioned behind the opening 50 a of the frame-shaped decorative body 50. That is, the display unit 17 a of the symbol display device 17 is positioned behind the opening 50 a of the frame-shaped decorative body 50. The frame-shaped decorative body 50 is formed in a frame shape protruding forward from the front surface of the plate-like member 21, and is configured to divide the game area 22 into left and right ball flow-down areas by the frame-shaped decorative body 50. Has been.

  In addition, a first pachinko ball flowing down the game area 22 can be won in the mounting member formed at a position below the frame-shaped decorative body 50 (a position directly above the out port 30). A start winning section 35 is provided. The first start winning portion 35 is a normally open type winning portion in which a first start winning opening where a pachinko ball can be won is always opened upward in the game area 22, and the pachinko flowing down the game area 22 of the game board 20. The pachinko ball can be entered (winned) at the first start winning opening at an arbitrary timing according to the flow of the ball. In addition, the game area 22 flows down to the plate-like member 21 through a mounting opening (not shown) formed on the left side of the first start winning portion 35 (lower left position of the frame-shaped decorative body 50). A normal winning unit 37 provided with a plurality of normal winning portions 38 capable of winning a pachinko ball is arranged. As with the first start winning portion 35, each of the normal winning portions 38 is a normally open type winning portion in which a normal winning opening where a pachinko ball can be won always opens upward in the game area 22. The pachinko balls can enter (win) the normal start winning opening at an arbitrary timing according to the flow mode of the pachinko balls flowing down the game area 22 of the board 20.

  The plate-like member 21 has a gate portion 43, a first portion in a mounting opening (not shown) formed on the right side of the first start winning portion 35 (a lower right position of the frame-shaped decorative body 50). A composite winning unit 40 having two start winning units 41 and a special winning unit 42 is provided. The gate portion 43 is a normally open type entrance portion in which a gate entrance and a gate exit through which a pachinko ball can pass are always opened vertically in the game area 22, and the pachinko ball flowing down the game area 22 of the game board 20. The pachinko ball enters (passes) the gate entrance at an arbitrary timing according to the flow-down mode, and is discharged to the game area 22 through the gate exit. The second start winning portion 41 is an open / close type winning portion that is closed by an opening / closing member 41a so that the second start winning port where a pachinko ball can be won can be opened in accordance with driving of the driving means. The pachinko ball can be awarded to the second start winning opening according to the flow mode of the pachinko ball flowing down the game area 22 of the board 20 and the opening operation timing of the opening / closing member 41a by driving of the driving means. Similarly, the special winning portion 42 is an open / close-type winning portion in which a special winning opening through which a pachinko ball can be won is closed by an opening / closing member 42a so that it can be opened as the driving means is driven. The pachinko ball can be awarded to the special prize opening according to the flow mode of the pachinko ball flowing down the region 22 and the opening operation timing of the opening / closing member 42a by driving of a driving means (not shown). FIG. 2 shows a state in which the winning openings of the second start winning portion 41 and the special winning portion 42 are closed by the corresponding opening / closing members 41a and 42a.

  Each of the first start winning section 35, the second start winning section 41, the special winning section 42, and the normal winning section 38 is a winning detection sensor that detects a pachinko ball won in each corresponding winning opening (FIG. (Not shown), and each winning detection sensor is wired to a control board disposed on the back side of the pachinko machine 10. Then, according to the detection of the pachinko ball (input of a detection signal for detecting the pachinko ball) by any of the winning detection sensors included in the first and second start winning units 35 and 41, a special figure hit determination condition (win determination condition) Is supposed to hold. Then, if the judgment per special figure is established, a special figure judgment is made regarding whether or not a special figure per hit (big hit or small hit) will occur, and if the judgment result is a win, the symbol display As a result of the symbol variation effect performed by the device 17, the decoration figure is fixedly stopped and displayed with a predetermined hit display (for example, three sets of the same symbol, etc.), and the player who opens the opening / closing member 42a of the special winning portion 42 is notified An advantageous winning game is provided. Further, in the pachinko machine 10 of the embodiment, the winning ball detection condition is configured to be established when the winning detection sensor detects the pachinko ball, and the main control board is illustrated as the prize ball paying condition is satisfied. A control signal is output to the payout control device that does not, and a predetermined number of prize balls are paid out to the upper ball tray 14 or the lower ball tray 15.

The gate portion 43 is provided with a gate sensor (not shown) that detects a pachinko ball that enters the gate port and passes through the gate portion 43. This gate sensor is connected to a control board disposed on the back side of the pachinko machine 10 and is usually connected with the input of a ball detection signal from the gate sensor to the main control board (ie, detection of a pachinko ball). The hit determination condition is established. Then, in accordance with the establishment of the universal hit determination condition, a universal hit determination regarding whether or not to generate a normal hit is performed, and when the determination result is a win determination, the second start winning portion The opening / closing member 41a is opened to open the second start winning opening. In the embodiment, it is set so that the winning ball payout condition is not satisfied when the gate sensor detects the pachinko ball, and the winning ball is not paid out as the pachinko ball passes through the gate portion 43. It has become.

(About the installation member 45)
The installation member 45 includes a substantially rectangular back plate 45a formed in a shape slightly smaller than the outer shape of the plate-like member 21, and an outer peripheral wall portion 45b protruding forward from the outer peripheral edge of the back plate 45a. (See FIG. 2 (b)), and the front end of the outer peripheral wall 45b is in contact with the back surface of the plate member 21, The installation member 45 is fixed with screws. Further, a substantially rectangular opening 45c is opened on the back plate 45a of the installation member 45 at a position aligned with the opening 50a of the frame-shaped decorative body 50 in the front-rear direction. The symbol display device 17 is detachably attached to the back side of the back plate 45a, and the display portion 17a of the symbol display device 17 faces the front side of the installation member 45 (game board 20) through the opening 45c. ing. In addition, movable effect devices 60A and 60B are installed at the upper position and the lower position of the opening 45c in the installation member 45, respectively. The movable effect device located above the opening 45c may be referred to as an upper movable effect device 60A, and the movable effect device located below the opening 45c may be referred to as a lower movable effect device 60B. .

(About movable effect devices 60A and 60B)
As shown in FIGS. 2 to 6, the upper and lower movable effect devices 60 </ b> A and 60 </ b> B include a device main body 80 disposed on the installation member 45 and a support disposed displaceably with respect to the device main body 80. The arms (support members) 121 and 122, the movable bodies 61 and 62 disposed so as to be displaceable with respect to the support arms 121 and 122, the drive motor (drive means) 150, and the support arms 121 and 122 are connected to each other. The drive transmission means 100, 101 for displacing the support arms 121, 122 relative to the apparatus main body 80 as the drive motor 150 is driven, and the movable body relative to the support arms 121, 122 as the support arms 121, 122 are operated. Actuating means 110 and 111 for displacing 61 and 62 are provided. That is, the movable bodies 61 and 62 of the upper and lower movable rendering devices 60A and 60B are integrally formed with the support arms 121 and 122 that move through the drive transmission means 100 and 101 by driving the drive motor 150. It is configured to be displaced relative to the support arms 121 and 122 via the operating means 110 and 111 as the support arms 121 and 122 move. Here, in the upper and lower movable effect devices 60A and 60B of the embodiment, one end side of the support arms 121 and 122 is pivotally supported with respect to the device main body 80, and the other end of the support arms 121 and 122 is supported. The movable bodies 61 and 62 are pivotally supported on the part side, and the movable bodies 61 and 62 are configured to rotate as the support arms 121 and 122 swing.

  Here, as shown in FIGS. 2, 5, and 6, the upper movable effect device 60A includes the support arms 121 and 122 and the movable bodies 61 and 62 in a symmetrical relationship, and supports the right side. By operating the arm 121, the corresponding right movable body 61 operates, and by operating the left support arm 122, the corresponding left movable body 62 operates symmetrically with the right movable body 61. It has become. Similarly, the lower movable effect device 60B includes the support arms 121 and 122 and the movable bodies 61 and 62 in a symmetrical relationship so that the left and right support arms 121 and 122 and the movable bodies 61 and 62 operate symmetrically. Composed. In the following description, the support arm and the movable body positioned on the right side in the upper and lower movable rendering devices 60A and 60B are referred to as the first support arm 121 and the first movable body 61, and the support arm and the movable body positioned on the left side. May be referred to as the second support arm 122 and the second movable body 62.

  In addition, since the upper movable effect device 60A and the lower movable effect device 60B of the embodiment are basically formed in a vertically symmetrical configuration, the configuration of the upper movable effect device 60A will be described in detail in the following description. For the lower movable effect device 60B, the same reference numerals are assigned to the same components, and detailed description thereof is omitted. Further, in the upper and lower movable effect devices 60A and 60B, the first and second support arms 121 and 122 and the first and second movable bodies 61 and 62 are respectively formed as left and right symmetrical members having the same basic configuration. Therefore, regarding the support arms 121 and 122 and the movable bodies 61 and 62, the first support arm 121 and the first movable body 61 in the upper movable effect device 60A will be described in detail, and the other support arms and movable bodies are the same. The same reference numerals are assigned to the constituent members and detailed description thereof is omitted.

  As shown in FIG. 2, the upper movable effect device 60 </ b> A has a device body 80 attached to the back plate 45 a so as to be positioned above the opening 45 c of the installation member 45. Then, by driving the drive motor 150, each of the first movable body 61 and the second movable body 62 in the upper movable effect device 60A is retracted outward (upward) from the opening 45c of the installation member 45. It is configured to move between the standby position (see FIGS. 2B and 5) and the movable position facing the front of the opening 45c (see FIGS. 2A and 6). In the upper movable effect device 60A, the longitudinal directions of the first movable body 61 and the second movable body 62 extend left and right at the standby position, and from a swing shaft 88 (described later) of the first support arm 121 at the standby position. The longitudinal direction of the first movable body 61 extends toward the lower right, and the longitudinal direction of the second movable body 62 extends from the swing shaft 88 (described later) of the second support arm 122 toward the lower left at the standby position. It is displaced to a posture in which the direction extends. Similarly, in the lower movable effect device 60 </ b> B, the device main body 80 is attached to the installation member 45 so as to be positioned below the opening 45 c opened in the installation member 45, and the lower movable device 60 </ b> B is movable as the drive motor 150 is driven. As each of the first movable body 61 and the second movable body 62 of the rendering device 60B moves from the standby position to the movable position, the first movable body 61 and the second movable body 62 of the upper movable rendering device 60A. The postures are displaced so as to be vertically symmetrical with each other. In FIG. 2A, the movable bodies 61 and 62 in the upper and lower movable effect devices 60A and 60B moved to the movable position are indicated by two-dot chain lines.

(About the first movable body 61)
Next, the configuration of the first movable body 61 will be described. As shown in FIG. 7, the first movable body 61 includes a light-transmitting front cover body 96 that forms a front surface, and a substrate disposed between the front cover body 96 and the front cover body 96. And a rear cover body 64 that defines the accommodating portion 65, and is formed into a box-like member whose longitudinal direction extends in a direction parallel to the plate-like member by the front and rear cover bodies. A light emitter substrate 66 mounted with a light emitter that emits light toward the front cover body 96 is accommodated in the substrate housing portion 65 defined by the rear cover body. The light transmitted through the front cover 96 is emitted to the front of the game board 20 by causing the light emitters to emit light. In addition, as a light emitter, a conventional light emitter such as an LED can be employed.

  Further, on the rear surface of the first movable body 61 (rear cover body 64), there is a rotating gear 68 that meshes with the connecting gear 111 of the first support arm 121 that constitutes the operating means, at a substantially intermediate position in the longitudinal direction. A rotating shaft 69 extending in the front-rear direction is fixed to a shaft fixing hole 68 a provided at the center of the rotating gear 68. A rotating shaft 69 protruding rearward of the rotating gear 68 is inserted into a bearing tube portion 127 (described later) of the first support arm 121 from the front, and the first movable body 61 is inserted into the first support arm 121. Is supported so as to be rotatable about a rotation shaft 69. Here, the first and second movable bodies 61 and 62 of the embodiment are configured to be able to rotate forward and backward in a rotation range of about 180 ° around the rotation shaft 69. That is, the first movable body 61 rotates 180 ° from the standby position toward the movable position in the right rotation direction around the rotation shaft 69, and at the left about the rotation shaft 69 from the movable position toward the standby position. The second movable body 62 is configured to rotate 180 ° in the rotation direction. The second movable body 62 rotates 180 ° in the left rotation direction around the rotation shaft 69 from the standby position toward the movable position, and from the movable position toward the standby position. Thus, it is configured to rotate 180 ° in the right rotation direction around the rotation shaft 69.

  As shown in FIGS. 7 and 12, the rear cover body 64 is formed with a slit hole 64 a penetrating the substrate housing portion 65 at a position spaced radially from the rotating shaft 69. A film harness (wiring) F connected to the light emitter substrate 66 accommodated in the substrate accommodating portion 65 extends to the rear of the first movable body 61 through the slit hole 64a of the rear cover body 64. It has become. This film harness F is formed so that a plurality of conductive wires formed in a flat plate shape are arranged in parallel and covered with an insulator, and can be easily flexibly deformed in the thickness direction.

  Further, as shown in FIG. 7, the rear cover body 64 is formed with a wiring support portion 70 extending rearward from the opening edge of the slit hole 64 a and holding the wiring facing the wiring support portion 70. The film harness F, to which the piece 71 is attached and pulled out from the slit hole 64a to the rear of the movable bodies 61 and 62, is held between the wiring support portion 70 and the wiring holding piece 71. That is, the wiring support part 70 and the wiring clamping piece 71 function as holding means for holding the film harness F, and may be referred to as wiring holding parts 70 and 71 in the following description. Here, the film harness F is bent so as to be twisted so as to change the extending direction by 90 degrees at the holding position by the wiring support portion 70 and the wiring holding piece 71, and the annular insertion portion 136 of the first support arm 121. Within (described later), the film harness F can be bent in an annular shape around the rotating shaft 69. That is, by extending the film harness F in an annular shape within the annular insertion portion 136, the load acting on the cable with the rotation of the first movable body 61 is reduced and the film harness F is folded and overlapped. By sandwiching and fixing the portion with the wiring support portion 70 and the wiring sandwiching piece 71, stress is prevented from concentrating on the bent portion of the film harness F, and the occurrence of disconnection or the like is prevented.

(About magnet 75)
As shown in FIG. 7, the first movable body 61 is provided with a magnet 75 at a position spaced from the rotating shaft 69 to one end in the longitudinal direction of the first movable body 61. A magnet 75 of the first movable body 61 is magnetically attached to a first sheet metal member 93 (described later) provided in the apparatus main body 80 at the standby position, and is provided on the first support arm 121 at the movable position. The magnet 75 of the first movable body 61 is configured to be magnetically attached to the second sheet metal member 133 (described later). That is, one magnet 75 provided on the first movable body 61 is magnetically attached to each of the first and second sheet metal members 93 and 133, so that the first movable body 61 is reciprocally rotated. It is held at both the standby position and the movable position.

  Here, in the first movable body 61, a magnet holder 76 is located at the standby position so as to be located outwardly from a swing shaft 88 (described later) that supports the first support arm 121 on the apparatus main body 80. Thus, the magnet 75 is arranged in the magnet holder 76. That is, in the embodiment, the magnet 75 is disposed at the end of the first movable body 61 that is farthest from the swing shaft 88 of the first support arm 121 in the standby position, and the standby position is caused by gravity action (self-weight). The magnetic force of the magnet 75 required to stably hold the first movable body 61 and the first support arm 121 at the standby position against the force to be displaced from the first position to the movable position can be minimized. Has been.

  As shown in FIG. 7, the magnet holder 76 is formed so as to protrude rearward from the rear surface of the rear cover body 64, and the insertion port 76a of the magnet 75 is opened on the front surface (front cover body 63 side). Thus, the magnet 75 is inserted into the magnet holder 76 through the insertion port 76a. The insertion opening 76a of the magnet holder 76 is closed with a cap member 78, and the magnet 75 is prevented from falling off from the magnet holder 76. The cap member 78 is inserted into an insertion portion 78a inserted into the magnet holder 76 through the insertion port 76a and an engagement hole 77 formed adjacent to the insertion port 76a. An engaging claw portion 78b that engages with the engaging hole 77 is provided. By engaging the engaging claw portion 78b with the engaging hole 77, the magnet holder 76 is inserted by the insertion portion 78a inserted through the insertion port 76a. The magnet 75 is held at a predetermined position.

(About the device body 80)
As shown in FIGS. 4 to 6 and 8, the apparatus main body 80 includes a plate-like rear base portion 81 fixed to the front surface of the back plate 45 a of the installation member 45, and the rear base portion 81. And a plate-like front base portion 82 disposed so as to be opposed to and separated from the front surface side, and in a horizontally long rectangular box shape in which an installation space 80a is defined between the front and rear base portions 81, 82. Is formed. In the installation space 80a between the front and rear base parts 81 and 82, the support arms 121 and 122, the movable bodies 61 and 62, the drive transmission means 100 and 101, the operation means 110 and 111, and the drive motor 150, respectively. Contained. Here, the installation space 80a between the front and rear base parts 81 and 82 is configured to open at least below the apparatus main body 80 (in the direction of the opening formed in the installation member 45), and the drive motor When 150 is driven, the first and second support arms 121 and 122 and the first and second movable bodies 61 and 62 are moved through the lower opening of the installation space 80a as the standby position moves to the movable position. Protrudes downward from the apparatus main body 80 and can move to the front side of the display portion 17a of the symbol display device 17. In the embodiment, the front base portion 82 is fixed to the protruding end portions of a plurality of fixed protrusions 81a provided to protrude forward from the outer peripheral portion of the rear base portion 81, and the device The outer periphery of the main body 80 opens in the vertical direction and the left and right sides, so that the inside of the installation space 80a can be confirmed from the upper and lower sides and the left and right sides of the apparatus main body 80.

  Further, as shown in FIG. 3, the apparatus main body 80 includes a light emitter substrate 66 and a drive motor 150 disposed on the front side of the front base portion 82 on the first and second movable bodies 61 and 62. Is connected to a control board (not shown) connected to the connection board 95. Further, a front cover body 96 that covers the front base portion 82 and the front surface of the connection substrate 95 is disposed on the front surface side of the connection substrate 95. That is, the light emitter substrate 66 and the drive motor 150 disposed on the first and second movable bodies 61 and 62 are electrically connected to the control device via the connection substrate 95. In addition, a light emitter (not shown) that irradiates light toward the front cover body 96 is mounted on the front surface of the connection substrate 95, and the first and second light sources are connected to each other based on a control signal from the control device. The light emitters provided on the light emitter substrate 66 of the second movable bodies 61 and 62 and the light emitter of the connection substrate 95 emit light and extinguish.

  As shown in FIGS. 4, 6, and 8, the rear base portion 81 has a substantially central upper position in the left-right direction of the flat plate portion 83 fixed to the installation member 45, to the rear of the flat plate portion 83. A stepped portion 84 is provided that protrudes and has a concave shape that opens forward and upward. A plurality of driven gears 100 constituting the drive transmission means are pivotally supported in front of the stepped portion 84. Further, in front of the stepped portion 84, a support plate 85 that pivotally supports the driven gear 100 with the stepped portion 84 is disposed so as to face and separate from the front side of the flat plate portion 83. A motor installation plate 86 on which the drive motor 150 is installed is attached to the front surface of the support plate 85. The stepped portion 84 and the support plate are respectively connected to the support plate 85 through the front and rear motor shaft through holes 85a and the motor installation plate 86 through the front and rear motor shaft through holes 86a. The drive shaft 150a of the drive motor 150 projects into a space between the drive motor 150 and the drive gear 151 attached to the drive shaft 150a in the space engages with the driven gear 100. . Here, each of the driven gears 100 positioned on the left and right sides of the support plate 85 is formed to have a size protruding forward from the flat plate portion 83, and the first and second support arms 121 and 122. Each of the oscillating plates 101 is oscillated by driving the drive motor 150, and the oscillating plate is oscillated. As the 101 swings, the second support arms 121 and 122 swing between the standby position and the movable position.

  The front base portion 82 is formed with a motor support hole 82a penetrating back and forth corresponding to the position of the drive motor 150 in the rear base portion 81, and the front and rear base portions 81 and 82 are assembled. At this time, the rear end portion of the drive motor 150 disposed on the motor installation plate 86 is fitted and supported in the motor support hole 82a. That is, the drive motor 150 is fitted into the motor support hole 82a provided in the front base portion 82, thereby reducing the thickness of the apparatus main body 80 in the front-rear direction and reducing the size of the upper movable effect device 60A. .

  Further, as shown in FIG. 4, a support protrusion 87 protruding forward is formed on the front surface of the rear base portion 81 (flat plate portion 83) at a position below the step portion 84 (motor installation plate 86). Then, an operation plate 110 (described later) constituting the operation means is attached to the protruding end portion of the support protrusion 87. The actuating plate 110 of the actuating means is located in front of the flat plate portion 83 of the rear base portion 81 by an amount corresponding to the protruding height of the support protrusion 87. The rocking plate 101 is disposed between the two. And the cylindrical part 87a opened to the front is formed in the left-right edge part of the said support protrusion 87, respectively, The said rocking | fluctuation axis | shaft 88 fixed to each of the said right-and-left cylindrical part 87a is said. The first and second support arms 121 and 122 are swingably supported. The swing shaft 88 fixed to the left and right cylindrical portions 87a is configured to protrude forward of the operation plate 110 through a through hole 110a formed through the operation plate 110 in the front-rear direction. The support arms 121 and 122 are supported at the end of the swing shaft 88 that protrudes forward of the operation plate 110. Further, shaft support holes 89 that open to the front are formed on both the left and right sides of the front surface of the rear base portion 81 (flat plate portion 83) with the support protrusion 87 interposed therebetween. The swing plate 101 is swingably supported by each of the supported spindles 90.

  Further, as shown in FIGS. 4 and 6, the left and right swing plates 101 supported by the support shaft 90 supported by the shaft support hole 89 are sandwiched between the rear base portion 81 (flat plate portion 83). On both the left and right sides, arcuate guide holes 91 extending in an arc shape centering on the left and right swing shafts 88 that support the first and second support arms 121 and 122 are formed to penetrate in the front-rear direction. . A guide shaft 129 (described later) formed on the first support arm 121 is inserted into the arcuate guide hole 91 located on the right side from the front, and the second support is inserted into the arcuate guide hole 91 located on the left side. A guide shaft 129 (described later) formed on the arm 122 is inserted from the front, and the first and second support arms 121 and 122 can swing within a range in which the guide shaft 129 can move in the arcuate guide hole 91. It has become.

  As shown in FIGS. 4, 6, and 8, the first sheet metal member (first plate) on which the magnet 75 can be magnetically attached to the left and right end portions of the rear base portion 81 (flat plate portion 83). Magnetized member) 93 is disposed, and magnets 75 (described later) provided on the movable bodies 61 and 62 correspond to the first and second movable bodies 61 and 62 in the standby position. The left and right first sheet metal members 93 are magnetically attached. That is, the first sheet metal member 93 is provided on the apparatus main body 80 that is displaced relative to the movable bodies 61 and 62 as the movable bodies 61 and 62 reciprocate. Here, the first sheet metal member 93 includes a fixed plate portion 93a fixed to the rear base portion 81, and a magnetized plate portion 93b extending forward from the lower end of the fixed plate portion 93a. It is formed by bending an L-shaped metal plate on which a magnet can be worn occasionally, and when the first movable body 61 is moved from the movable position to the standby position, the moving direction of the first support arm 121 (from below) The magnet 75 of the first movable body 61 is moved and magnetized from the lower side in the same direction as the upward movement direction) to the corresponding magnetized plate portion 93b.

  Further, as shown in FIGS. 4 and 6, guide portions 97 that open downward in the direction of the arrangement position of the working plate 110 and at the lower positions of the left and right ends of the rear base portion 81 (flat plate portion 83) are provided. A guide protrusion 145 (described later) formed on the support arms 121 and 122 is guided when moving from the movable position to the standby position. Here, the guide portion 97 includes a rear guide surface 97a formed on the rear base portion 81 (flat plate portion 83) and a front guide surface 97c formed on a support body 97b arranged to face the rear guide surface 97a. It consists of and. Further, the rear guide surface 97a and the front guide surface 97c are curved so as to be separated from each other as they go downward, and the support arms 121, 122 move from below when moving from the movable position to the standby position. The guide protrusion 145 can be easily received. Further, a position detection sensor 98 that detects a position detection piece 146 formed on the first support arm 121 is disposed above the right guide portion 97, and the position detection sensor 98 moves the position detection piece 146. By detecting, the standby positions of the first and second support arms 121 and 122 are detected.

(About the swing plate 101)
As shown in FIGS. 4, 8, and 9, the swing plate 101 is a flat plate having a through hole 102 a through which the support shaft 90 supported by the shaft support hole 89 of the apparatus main body 80 is inserted. A support substrate 102, a swinging gear portion 103 formed on the support substrate 102 and meshing with the driven gear 100, and formed in the support substrate 102 and inserted into operation holes 128 (described later) of the support arms 121 and 122. The operation shaft 104 is provided. Specifically, the operation shaft 104 of the right swing plate 101 is inserted into the operation hole 128 of the first support arm 121, and the operation shaft 104 of the left swing plate 101 is inserted into the operation hole of the second support arm 122. As the driven gear 100 rotates by driving the drive motor 150, the left and right swing plates 101 rotate about the support shaft 190, and the corresponding support arms 121, 122 are inserted. Is made to swing. The swing gear portion 103 is formed on the rear surface of the support substrate 102, and the operating shaft 104 is formed to protrude forward on the outer peripheral portion of the front surface of the support substrate 102, and the operating shaft 104 corresponds thereto. It is configured to be inserted from behind the operation hole 128. Here, the left and right rocking plates 101 supported by the left and right support shafts 90 of the apparatus main body 80 are formed in a bilaterally symmetric shape and are configured to rotate in the reverse rotation direction as the drive motor 150 is driven. The first and second support arms 121 and 122 are synchronously swung in the reverse rotation direction along with the left and right rocking plates 101. That is, when moving from the standby position toward the movable position, the first support arm 121 swings in the clockwise direction about the swing shaft 88, while the second support arm 122 swings about the swing shaft 88. When swinging counterclockwise and moving from the movable position toward the standby position, the first support arm 121 swings counterclockwise about the swing shaft 88 while the second support arm 122 swings. The moving shaft 88 is configured to swing in the clockwise rotation direction.

(Operating plate 110)
Further, as shown in FIGS. 4 and 8, the operation plate 110 is formed in a horizontally long flat plate shape and is disposed so as to overlap the front side of the left and right swing plates 101. The left and right side end portions of the operating plate 110 are provided with operating gear portions 110b extending in an arc shape centering on the swing shaft 88, and support arms 121 are provided on the left and right operating gear portions 110b. , 122 are configured to mesh with each other. Specifically, the connection gear 111 of the first support arm 121 meshes with the operation gear portion 110b at the right end portion of the operation plate 110, and the second support is provided at the operation gear portion 110b at the left end portion of the operation plate 110. The connecting gear 111 of the arm 122 is engaged. That is, as the support arms 121 and 122 swing, the connecting gear 111 meshed with the operating gear portion 110b is rotated, and each of the movable bodies 61 and 62 meshed with the connecting gear 111 meshes with the rotating gear 68. It is rotated about 69. That is, as the first support arm 121 swings from the standby position to the movable position, the first movable body 61 rotates in the clockwise direction around the rotation shaft 69, while the second support from the standby position to the movable position is performed. As the arm 122 swings, the second movable body 62 rotates counterclockwise around the rotation shaft 69, and as the first support arm 121 swings from the movable position to the standby position, the first movable body 61. Rotates in the left rotation direction about the rotation shaft 69, while the second movable body 62 rotates in the right rotation direction about the rotation shaft 69 as the second support arm 122 swings from the movable position to the standby position. It is configured to

(About the first and second support arms 121 and 122)
Next, the first and second support arms 121 and 122 will be described. Here, since the first support arm 121 and the second support arm 122 are formed in a symmetrical shape and configuration, in the following description, the first support arm 121 located on the right side will be described. About the 2nd support arm 122, the same code | symbol is attached | subjected about the same structure and detailed description is abbreviate | omitted. As shown in FIG. 3, the first support arm 121 is provided so as to extend from the right swing shaft 88 in the radial direction, and the second support arm 122 is provided on the left swing shaft. It is provided so as to extend from 88 in the radial direction. Each of the corresponding first movable body 61 and second movable body 62 is rotatably supported at the end portion of the swing shaft 88 located on the opposite side of the pivotally supported end portion.

  As shown in FIG. 9, the first support arm 121 includes a first arm body 123 pivotally supported by a swing shaft 88 provided in the apparatus main body 80 and a rear side of the first arm body 123. A second arm body 125 provided between the first arm body 123 and the second arm body 125, and a housing portion (hereinafter referred to as gear housing) that houses the connecting gear 111 that constitutes the operating means. Part 130). The first arm body 123 and the second arm body 125 are configured to partially overlap in the front-rear direction, and the end of the first arm body 123 that protrudes outward from the second arm body 125 is configured. A first shaft hole 123a penetrating in the front-rear direction is formed on the portion side (the end portion side that does not overlap in the front-rear direction), and the swing shaft 88 is inserted into the first shaft hole 123a from the rear, thereby The one support arm 121 is supported to be swingable with respect to the apparatus main body 80. Further, a bearing projecting rearward from the second arm body 125 on the end side of the second arm body 125 projecting to the side of the first arm body 123 (the end side not overlapping in the front-rear direction). A cylindrical portion 127 is formed, a second shaft hole 127a penetrating in the front-rear direction is formed in the bearing tube portion 127, and the rotation shaft 69 of the first movable body 61 is forward of the second shaft hole 127a. As a result, the first movable body 61 is rotatably supported by the first support arm 121.

  Further, as shown in FIGS. 9 and 11, the second arm body 125 is formed with a plate-like position detection piece 146 extending outward from the end on the formation side of the second shaft hole 127a. The position detection sensor 98 provided in the apparatus main body 80 detects the first support arm 121 in a state where the first support arm 121 is in the standby position. That is, when the first and second support arms 121 and 122 operate symmetrically and integrally, the position detection sensor 98 detects the position detection piece 146 provided on the first support arm 121, so that both the support arms The standby positions of 121, 122 (first and second movable bodies 61, 62) are detected. Further, a guide protrusion 145 extending in the front-rear direction along the end of the position detection piece 146 is formed at the protruding end of the position detection piece 146, and is moved when moving from the movable position to the standby position. Further, the guide protrusion 145 is guided by the guide portion 97 of the apparatus main body 80.

  Further, as shown in FIG. 10, the gear accommodating portion 130 is provided between the first and second arm bodies 123 and 125 so as to open on the first shaft hole 123a side and the second shaft hole 127a side, respectively. It is defined. That is, the connecting gear 111 housed in the gear housing portion 130 is configured to be exposed to the outside of the gear housing portion 130 through the openings on the first shaft hole 123a side and the second shaft hole 127a side, The gear portion of the operating plate 110 and the rotating gear 68 of the first movable body 61 are engaged with the connecting gear 111 exposed from the opening of the gear housing portion 130. That is, when the first support arm 121 rotates (swings) about the swing shaft 88, the connecting gear 111 that meshes with the operating gear portion 110b of the operating plate 110 is rotated, and the connecting gear 111 rotates. As a result, the rotating gear 68 meshing with the connecting gear 111 is rotated, and the first movable body 61 rotates about the rotating shaft 69 or the like. The gear housing portion 130 is configured such that two linkage gears 111 housed in a rotatable state about a support shaft 111a extending in the front-rear direction mesh with each other, and one linkage gear 111 is engaged. Is engaged with the operating gear portion 110b of the operating plate 110, and is engaged with the rotating gear 68 of the first movable body 61 with the other connecting gear 111.

  As shown in FIGS. 9 and 11, the second arm body 125 is provided with an operation hole 128 that functions in the front-rear direction at the upper end portion on the first shaft hole 123a side. The operating hole 128 is formed in a long hole shape extending a predetermined length in the radial direction of the rocking shaft 88, and the working shaft 104 of the rocking plate 101 is inserted into the working hole 128 from behind. It has come to be. Thereby, the first support arm 121 swings about the swing shaft 88 as the swing plate 101 rotates. On the rear surface of the first support arm 121 (second arm body 125), there is a guide shaft 129 that protrudes rearward at a position aligned with the arcuate guide hole 91 of the apparatus main body 80 in the front-rear direction. The guide shaft 129 is slidably inserted from the front of the arcuate guide hole 91. That is, by moving the guide shaft 129 along the arcuate guide hole 91, the first support arm 121 can be stably rocked around the rocking shaft 88, and the arcuate guide hole 91. The first support arm 121 is swung within a range in which the guide shaft 129 abuts both ends in the extending direction, so that it can move between the standby position and the movable position.

(About the second sheet metal member 133)
Further, as shown in FIGS. 9 and 10, the gear accommodating portion 130 of the first support arm 121 has a second magnet magnet 75 that can be magnetically attached to the lower wall portion of the first support arm 121 in the standby position. A sheet metal member (second magnetized member) 133 is provided. The second sheet metal member 133 is disposed at a position where the magnet holder 76 (magnet 75) of the first movable body 61 that rotates and displaces relative to the first support arm 121 is opposed to the first movable body 61. Is moved to the movable position, the magnet 75 of the first movable body 61 is magnetically attached to the second sheet metal member 133. Accordingly, the magnet 75 of the first movable body 61 is moved from below to the lower wall portion of the first support arm 121 in accordance with the rotation in the clockwise direction from the standby position to the movable position (movement from above to below). The second sheet metal member 133 is moved close to and magnetically attached. That is, the second sheet metal member 133 is provided on the support arms 121 and 122 that are displaced relative to the movable bodies 61 and 62 as the movable bodies 61 and 62 reciprocate. The second sheet metal member 133 is formed from a metal plate on which a magnet can be magnetically attached, and is inserted from the front side into a slit groove 125a formed in the second arm body 125 so as to open forward. It is attached by that.

(Containment structure of film harness F)
Further, as shown in FIGS. 9 and 11 to 13, a cylindrical wiring housing portion 135 that opens rearward is formed on the rear surface of the first support arm 121 (second arm body 125). The bearing tube portion 127 is provided at the inner center position of the wiring housing portion 135 so as to protrude rearward. An arc-shaped hole 131 extending in an arc shape centering on the bearing tube portion 127 is formed on the bottom surface of the wiring housing portion 135 so as to penetrate in the front-rear direction, and the second shaft of the bearing tube portion 127 is formed. When the rotation shaft 69 of the first movable body 61 is inserted into the hole 127a, the wiring holding portions 70 and 71 provided in the first movable body 61 are connected to the inside of the wiring housing portion 135 via the arc-shaped hole 131. Until it is inserted. That is, the first support arm 121 has a rotation axis 69 line (rotation axis 69) of the first movable body 61 between the inner peripheral surface 135 a of the wiring housing portion 135 and the outer peripheral surface 127 b of the bearing tube portion 127. Is formed so that the wiring holding portions 70 and 71 of the first movable body 61 face (position) inside the annular insertion portion 136. A film harness F that extends annularly around the bearing tube portion 127 in the annular insertion portion 136 is sandwiched and held by the wiring holding portions 70 and 71.

  As shown in FIGS. 11 and 13, the first support arm 121 is formed with a wiring introduction portion 140 that communicates with the wiring accommodation portion 135 (annular insertion portion 136), and is connected to the connection substrate 95. The film harness F is guided to the wiring housing part 135 through the wiring introduction part 140. Here, the wiring introduction portion 140 is formed on the outer wall portion 124 extending rearward from the upper end portion of the first arm body 123 in the state of the standby position, and the outer wall portion 124 of the first arm body 123. A slit is defined between the second arm body 125 and the outer wall 126 facing each other, and extends along the outer edge (upper edge) of the gear housing 130. Then, the film harness F led out from the connection board 95 can be introduced into the wiring introduction portion 140 through the opening of the wiring introduction portion 140 opened at the end on the formation side of the first shaft hole 123a. . The wiring introduction part 140 is configured to communicate with the wiring accommodation part 135 (annular insertion part 136) via a slit-like introduction port 140a formed in the inner peripheral surface 135a of the wiring accommodation part 135. Thus, the film harness F can be introduced from the wiring introduction part 140 to the annular insertion part 136 via the introduction port 140a. That is, the wiring introduction part 140 is provided so as to be continuous in the tangential direction of the annular insertion part 136, and the rotation axis direction and the width direction of the first movable body 61 are parallel to the wiring introduction part 140. The film harness F is inserted in a posture. Therefore, the film harness F introduced into the annular insertion portion 136 via the introduction port 140a of the wiring introduction portion 140 is bent in the thickness direction so as to be annular around the rotation shaft 69 and around the outer periphery of the bearing tube portion 127. It can be extended in an annular shape without difficulty so as to be wound around.

  Here, as shown in FIGS. 11 and 13, the film harness F introduced into the annular insertion portion 136 through the introduction port 140 a of the wiring introduction portion 140 is moved from the standby position to the movable position in the annular insertion portion 136. An annular insertion portion 136 (wiring housing portion) is formed so as to extend around the outer periphery of the bearing tube portion 127 in the rotation direction of the first movable body 61 (that is, the right rotation direction in the first movable body 61). 135) is held by the wiring holding portions 70 and 71. Here, the film harness F is configured to extend in an annular shape on the outer peripheral side of the bearing tube portion 127 in a relaxed state allowing the rotation of the first movable body 61 from the standby position to the movable position. As the first movable body 61 is rotated, the film harness F wound around the bearing cylinder portion 127 is loosened (relaxed) or wound (contracted), whereby the first movable body 61 is reciprocally rotated. Is allowed. That is, as the first movable body 61 is rotated from the standby position to the movable position, the film harness F extending in an annular shape is wound around the annular insertion portion 136 to reduce the diameter, and from the movable position to the standby position. As the first movable body 61 is rotated, the winding of the film harness F is loosened and the diameter is increased. As described above, the film harness F is annularly wound around the bearing tube portion 127 in the wiring housing portion 135, thereby reducing the load acting on the cable in accordance with the rotational operation of the first movable body 61, and disconnection or the like. Occurrence is prevented.

  As shown in FIG. 13, the wiring holding portions 70 and 71 are closer to the introduction port 140a of the wiring introduction portion 140 in a state where the first movable body 61 is in a standby position than in a state where the first movable body 61 is in a movable position. Are configured to be located. That is, in a state where the first movable body 61 is in the standby position, the wiring holding portions 70 and 71 are located closer to the introduction port 140a side of the wiring introduction portion 140 than the bearing tube portion 127 (the rotation shaft 69). In a state where the single movable body 61 is in the movable position, the wiring holding portions 70 and 71 are positioned on the opposite side to the introduction port 140a of the wiring introduction portion 140 with the bearing tube portion 127 (rotating shaft 69) interposed therebetween. Yes. Therefore, when the first movable body 61 moves from the standby position to the movable position, the film harness F is wound as the wiring holding portions 70 and 71 move away from the introduction port 140a of the wiring introduction portion 140. When the first movable body 61 moves from the movable position to the standby position, the wire holding portions 70 and 71 move so as to be close to the introduction port 140a of the wire introduction portion 140. With this, the film harness F is slackened (the diameter wound in an annular shape is increased). That is, the film harness F is configured to be in the most slack state when the first movable body 61 is in the standby position.

  Here, the film harness F introduced into the wiring housing part 135 from the introduction port 140a of the wiring introduction part 140 is the bearing in the annular insertion part 136 in a state where the first movable body 61 is in the standby position. It is configured to be sandwiched and held by the wiring holding portions 70 and 71 of the first movable body 61 in a state where the tube portion 127 (rotating shaft 69) is rotated around the cylinder portion one round. Note that the state in which the film harness F is circularly rotated once is not only the state in which the film harness F completely rotates, but also the rotation shaft 69 in a state in which the first movable body 61 is in the standby position. And it should just be in the state wound circularly so that the line segment L (refer FIG. 13) which connects the inlet 140a of the wiring introduction part 140 may be exceeded.

  As shown in FIGS. 7 and 13, the outer surfaces of the wiring holding portions 70, 71 that are separated from the bearing tube portion 127 (the wiring holding pieces 71 facing the inner peripheral surface 135 a of the wiring housing portion 135) A curved surface portion 72 is formed by curving both ends in the rotational direction of the first movable body 61 into a curved surface shape. That is, the wiring holding portions 70 and 71 have both ends in the rotational direction on the side surface facing the film harness F in the annular insertion portion 136 formed in a curved shape, and between the standby position and the movable position. When the first movable body 61 is rotated, the curved surface portions 72 of the wiring holding portions 70 and 71 smoothly guide the film harness F, thereby preventing the film harness F from being damaged or worn. Thus, the surplus length of the film harness F in the standby position is minimized by forming the curved surface portion 72 at the edge portion of the wiring holding portions 70 and 71 facing the film harness F.

  Further, as shown in FIGS. 9 and 12, on the rear surface of the first support arm 121, a back cover member that closes the rear opening of the wiring housing portion 135 (annular insertion portion 136) and the rear opening of the wiring introduction portion 140. 143 is provided to prevent the film harness F from falling off from the wiring housing part 135 and the wiring introduction part 140. The back cover member 143 includes a plurality of portions that penetrate the front and rear at positions that are separated from each other in the circumferential direction around the rotation shaft 69 of the first movable body 61 in the covering portion of the wiring housing portion 135 (annular insertion portion 136). (Four in the embodiment) four windows 143a are formed. The window 143a is formed so as to open inside the wiring housing part 135 (annular insertion part 136), and the film harness F in the annular insertion part 136 is formed from the outside of the first support arm 121 via the window 143a. Can be confirmed visually.

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

  When a player rotates the operation handle 16 provided on the front surface of the pachinko machine 10, a game area 22 defined by a guide rail 23 provided on the game board 20 is formed by a pachinko ball launched from a ball hitting device. The pachinko ball launched into the game area 22 contacts the game nail 32 provided on the game board 20 and flows down while changing the flow direction. Then, in the process of flowing down the game area 22, a big hit lottery is performed when the pachinko ball wins the starting winning opening of the first or second starting winning portion 35, 41, and the control of the control device is performed. Based on this, the symbol display effect on the symbol display device is started, and when the big win is won, a predetermined winning display (for example, a set of three identical symbols) is displayed on the symbol display device 17 as a result of the symbol change effect. Is a big hit. When a big hit occurs, according to the symbol combination displayed on the symbol display device 17, the special winning portion 42 provided below the game board 20 is opened, and the symbol display device 17 is controlled based on the control of the control device. A big hit game production will be performed.

  Then, the upper and lower movable effect devices 60A and 60B are operated based on the control signal from the control device in accordance with the symbol variation effect and the big hit game effect developed in the symbol display device 17, and the upper movable effect. An operation effect is performed between the standby position and the movable position of each of the first and second movable bodies 61 and 62 included in the device 60A and the first and second movable bodies 61 and 62 included in the lower movable rendering device 60B. In the upper and lower movable effect devices 60A and 60B, the light emitters of the light emitter substrate 66 included in each of the movable members 61 and 62 according to the symbol variation effect and the big hit game effect developed in the symbol display device 17. Is emitted based on a control signal from the control device, and a light emission effect is performed.

  Here, in the first and second movable bodies 61 and 62 of the upper and lower movable effect devices 60A and 60B, one magnet 75 is disposed in the magnet holder 76, and each of the first and second movable bodies 61 is arranged. , 62 is in the standby position, the magnet 75 is magnetically attached to the magnetically attached plate portion 93b of the first sheet metal member 93 disposed in the apparatus main body 80, and the first and second movable bodies 61, 62 are connected to each other. In the state of being movable, the same magnet 75 is magnetically attached to the second sheet metal member 133 disposed on the corresponding first and second support arms 121 and 122, and each movable body 61, 62 is configured to be held by magnetic force at both the standby position and the movable position. As described above, the magnets 75 provided on the movable bodies 61 and 62 are magnetically attached to the first sheet metal member 93 and the second sheet metal member 133, so that any position of the standby position and the movable position can be obtained by the magnetic force of the magnet 75. Even if it exists, the attitude | position stability of the movable bodies 61 and 62 can be improved. Therefore, even if vibration is transmitted to the upper and lower movable rendering devices 60A and 60B in a state where the first and second movable bodies 61 and 62 of the upper and lower movable rendering devices 60A and 60B are at the standby position, 61 and 62 can be prevented from moving from the standby position.

  In addition, when the upper movable effect device 60A and the lower movable effect device 60B are operated independently and moved from the standby position to the movable position, the first and second movable bodies 61 and 62 that operate symmetrically are magnetized. With the magnetic force of 75, it can be stably held in a symmetrically aligned posture at the movable position, and a movable appearance with good appearance can be performed. When the upper movable effect device 60A and the lower movable effect device 60B are simultaneously operated to move from the standby position to the movable position, the first and first operations that operate vertically and horizontally in each of the movable effect devices 60A and 60B. 2 The movable bodies 61 and 62 can be stably held in a vertically and horizontally symmetrical posture by the magnetic force of the magnet 75, and a more attractive moving effect can be performed, and the entertainment of the game can be enhanced. .

  Since the movable bodies 61 and 62 in the upper and lower movable presentation devices 60A and 60B can be held at the standby position and the movable position by one magnet 75 provided in each movable body 61 and 62, the movable presentation device 60A. , 60B will not increase the cost. Further, since only one magnet 75 moves when one movable body 61, 62 operates, the installation position of the magnetic sensor provided in the pachinko machine 10 is not excessively restricted, and the movable effect device 60A. , 60B can be improved.

  In the upper and lower movable rendering devices 60A and 60B, the first and second movable bodies 61 and 62 are disposed on the first and second support arms 121 and 122, respectively, which reciprocately swing as the drive motor 150 is driven. Accordingly, the corresponding first and second movable bodies 61 and 62 are configured to rotate (posture displacement) as the first and second support arms 121 and 122 swing back and forth. As described above, the movable bodies 61 and 62 are configured such that the corresponding movable bodies 61 and 62 rotate (posture displacement) with respect to the support arms 121 and 122 that reciprocally swing with the driving of the drive motor 150. Since the operation range can be expanded as compared with the configuration in which the camera is operated at a fixed position, and the operations of the movable bodies 61 and 62 can be complicated, it is possible to improve the production effect by the movable effect. And even if the operating range of the movable bodies 61, 62 is expanded, each movable body 61, 62 can be stably magnetized and held at each of the standby position and the movable position by one magnet 75. Good movable performance can be performed, and the interest of the game can be enhanced.

  Further, the first sheet metal member 93 is disposed on the apparatus main body 80 where the first and second support arms 121 and 122 are swingably supported, and the second sheet metal member 133 is disposed on each of the support arms 121 and 122. By wiring, the movable bodies 61 and 62 can be held in a stable posture with respect to the apparatus main body 80 at the standby position, and the movable bodies 61 and 62 can be stably held with respect to the support arms 121 and 122 at the movable position. Can be held in. For this reason, the unity of the apparatus main body 80 and the movable bodies 61 and 62 can be enhanced at the standby position, and the unity of the support arms 121 and 122 and the movable bodies 61 and 62 can be enhanced at the movable position. Further, the movable bodies 61 and 62 are disposed by stably magnetizing the first sheet metal member 93 and holding the movable bodies 61 and 62 with respect to the apparatus main body 80 at the standby position. Thus, the stability of the support arms 121 and 122 with respect to the apparatus main body 80 can be enhanced. That is, since the support arms 121 and 122 can be held in a stable posture by providing the magnets 75 on the movable bodies 61 and 62, it is necessary to separately provide the magnets 75 that hold the support arms 121 and 122 in the standby position. However, the cost can be reduced and the number of magnets 75 can be reduced.

  Further, one end side of the support arms 121 and 122 is supported so as to be swingable with respect to the apparatus main body 80, and the support arms 121 and 122 are swung on the other end side of the support arms 121 and 122. By supporting an intermediate position in the longitudinal direction of the corresponding movable bodies 61 and 62 so as to be rotatable about an axis parallel to the axis 88, an end that is displaced in the vertical direction as the support arms 121 and 122 swing is supported. The movable bodies 61 and 62 can be rotated. At this time, the connecting gear 111 disposed in the gear accommodating portion 130 of the support arms 121 and 122 moves along the operation gear provided in the apparatus main body 80, so that the movable bodies 61 corresponding to the support arms 121 and 122, respectively. , 62 can be rotated, and it is not necessary to provide a separate driving means for operating the movable bodies 61, 62, so that the support arms 121, 122 and the movable bodies 61, 62 can be reduced in size and weight. Can do.

  And, in the standby position, a magnet 75 is disposed at the end of the corresponding movable body 61, 62 so as to be located outwardly away from the swing shaft 88 of the support arm 121, 122, and the magnet 75 is It is magnetically attached to the first sheet metal member 93 of the apparatus main body 80. For this reason, the magnet 75 is magnetically attached to the first sheet metal member 93 at the end position (outward position) farthest from the swinging shaft 88 of the support arms 121 and 122 in the standby position, so that each support arm 121, The magnetic force of the magnet 75 required to hold 122 and the movable bodies 61 and 62 can be made as small as possible. That is, the support arms 121 and 122 and the movable bodies 61 and 62 can be stably held at the standby position with a small magnetic force. Then, by reducing the magnetic force of the magnet 75 provided on the movable bodies 61 and 62, it is possible to suppress as much as possible the range in which the magnet 75 moving with the operation of the support arms 121 and 122 and the movable bodies 61 and 62 affects. Therefore, the magnet 75 can be prevented from affecting the behavior of the pachinko sphere, and the installation position of the magnetic sensor is not excessively restricted, and the design freedom of the movable rendering devices 60A and 60B is increased. It becomes possible.

  Further, in the upper movable effect device 60A according to the embodiment, each of the support arms 121 and 122 moves from the lower side to the upper side and rotates while moving from the movable position to the standby position. The arrangement end portion (magnet holder 76) of the magnet 75 in the bodies 61 and 62 moves from the lower side to the upper side and moves close to the first sheet metal member 93 (magnetized plate portion 93b). Is configured to wear. That is, the direction in which the disposed end portions of the movable bodies 61 and 62 in the support arms 121 and 122 move when moving from the movable position to the standby position, and the direction in which the magnet 75 moves close to the first sheet metal member 93. And the magnet 75 is made to be relative to the first sheet metal member 93 by utilizing the momentum that the support arms 121 and 122 swing upward due to the inertial force when the drive of the drive motor 150 is stopped. Thus, the magnet 75 can be reliably magnetically attached to the first sheet metal member 93. On the other hand, in the upper movable effect device 60A according to the embodiment, when moving from the standby position to the movable position, each of the support arms 121 and 122 moves from the upper side to the lower side, and each movable element that rotates. The arrangement end portion (magnet holder 76) of the magnet 75 in the bodies 61 and 62 moves from the lower side to the upper side and moves close to the second sheet metal member 133 (the magnetized plate portion 93b) so that the magnet 75 is magnetized. Is configured to wear. That is, when the end position of the movable bodies 61 and 62 in the support arms 121 and 122 is moved when moving from the standby position to the movable position, and the direction in which the magnet 75 moves close to the second sheet metal member 133. Are reversed, the magnet 75 is moved relative to the second sheet metal member 133 by utilizing the momentum of the support arms 121 and 122 swinging downward due to the inertial force when the drive of the drive motor 150 is stopped. The magnets 75 can be reliably attached to the second sheet metal member 133. In the lower movable effect device 60B, the magnet 75 is moved relatively close to the corresponding sheet metal members 93 and 133 in accordance with the movement from the standby position to the movable position and the movement from the movable position to the standby position. The same can be said for the upper movable effect device 60A.

  Here, the film harness F for connecting the light emitter substrate 66 disposed on each of the movable bodies 61 and 62 to the connection substrate 95 disposed on the apparatus main body 80 ((the front base portion 82) is provided on the movable bodies 61 and 62. Thus, the bearing tube portion 127 is wound around the annular insertion portion 136 of the wiring housing portion 135 provided on the corresponding support arms 121 and 122 so as to surround the rotation shaft 69. As the movable bodies 61 and 62 rotate and move to the standby position and the movable position, the winding portion of the film harness F around the bearing tube portion 127 bends and relaxes. Since a load for bending the film harness F is not applied with the rotation, disconnection of the conductive wire inside the cable can be prevented, and the movable bodies 61 and 62 can be reciprocally rotated. As described above, by using the film harness F that can be flexibly deformed in the thickness direction, it is possible to reduce the load applied to the film harness F that is annularly wound in the annular insertion portion 136 and to rotate the movable bodies 61 and 62. In addition, the diameter of the cable wound in an annular shape can be quickly reduced / expanded (contracted / relaxed).

  Moreover, the film harness F is introduced into the annular insertion portion 136 through the introduction port 140a of the wiring introduction portion 140 that opens to the outer peripheral surface 127b of the wiring accommodation portion 135, and protrudes inside the annular insertion portion 136. Since it is held by the wiring holding portions 70 and 71 of the movable bodies 61 and 62, the deformation of the cable accompanying the rotation of the movable bodies 61 and 62 is limited to the inside of the annular insertion portion 136 (that is, the winding portion around the bearing tube portion 127). Therefore, it is possible to prevent a load from being applied to a bent portion or an unexpected part of the film harness F, and it is possible to effectively prevent disconnection of the film harness F. That is, the wiring holding portions 70 and 71 provided on the movable bodies 61 and 62 are faced to the inside of the annular insertion portion 136, and the film harness F that is annularly extended by the annular insertion portion 136 is connected to the wiring holding portion 70, By holding at 71, there is no need to bend the cable in order to pull it out from the annular insertion part 136. Accordingly, when the movable bodies 61 and 62 are rotated, it is possible to effectively prevent the stress from being concentrated on the bent portion of the wiring and causing a disconnection or the like. Then, by opening the introduction port 140a of the wiring introduction part 140 to the outer peripheral surface 127b of the wiring accommodation part 135, the film harness F is introduced into the wiring accommodation part 135 (annular insertion part 136) without bending the film harness F. When the diameter of the film harness F is reduced / expanded (contracted / relaxed) with the rotation of the movable bodies 61, 62, the wiring accommodating portion 135 (annular insertion portion 136) is connected to the wiring introduction portion 140 of the cable. ) Can be prevented from being overloaded.

  Also. The wiring holding portions 70 and 71 are provided with a curved surface portion 72 that is curved in a curved shape at an edge portion facing the cable portion wound around the rotation axis 69 of the movable bodies 61 and 62 in the annular insertion portion 136. It has been. Thus, the wiring which moves inside the annular insertion part 136 by forming the end edges of the wiring holding parts 70 and 71 facing the film harness F wound in an annular shape in the annular insertion part 136 in a curved shape. It is possible to effectively prevent the wiring from being worn or damaged in contact with the holding portions 70 and 71, and to prevent the cable from being disconnected more effectively. And since the said film harness F is wound in the annular penetration part 136 extended annularly on the outer side of the said bearing cylinder part 127, the winding part of the film harness F loosened at the time of rotation operation of the movable bodies 61 and 62 Can always be accommodated in the wiring accommodating portion 135 (annular insertion portion 136), and problems such as disconnection due to the biting of the cable can be prevented.

  In addition, the rear opening of the wiring accommodating portion 135 (annular insertion portion 136) is closed by the back cover member 143 disposed on the rear surface of each of the support arms 121 and 122, so that it is wound around the bearing tube portion 127. When the wound portion of the film harness F is bent so as to be contracted and relaxed, it is possible to prevent the film harness F from dropping from the wiring housing portion 135 (annular insertion portion 136). Similarly, since the rear opening of the wiring introduction part 140 is blocked by the back cover member 143, the film harness F is reliably prevented from falling off from the wiring introduction part 140 when the support arms 121 and 122 are swung. be able to. Further, the back cover member 143 that closes the opening of the wiring accommodating portion 135 (annular insertion portion 136) has a window that opens to the annular insertion portion 136 at a plurality of positions that are separated in the rotational direction of the movable bodies 61 and 62. 143a is formed so that the inside of the annular insertion portion 136 can be seen from the outside, so that the occurrence of disconnection or wear of the wiring accompanying the rotational operation of the movable bodies 61 and 62 can be easily confirmed from the outside, It is possible to efficiently check the rotation operation of the movable bodies 61 and 62, perform maintenance work, and the like.

  Further, in the upper and lower movable effect devices 60A and 60B according to the embodiment, when the movable bodies 61 and 62 are in the standby position, the introduction port of the wiring introduction unit 140 is more than the bearing tube portion 127 (the rotation shaft 69). In a state where the wiring holding portions 70 and 71 are located on the 140a side and the movable bodies 61 and 62 are in the movable positions, they are opposite to the introduction port 140a of the wiring introduction portion 140 with the bearing tube portion 127 (rotating shaft 69) interposed therebetween. The wiring holding portions 70 and 71 are located on the side. That is, the diameter of the film harness F in the annular insertion portion 136 decreases with the rotation of the movable bodies 61 and 62 from the standby position to the movable position, and the annular insertion with the rotation of the movable bodies 61 and 62 from the movable position to the standby position. The diameter of the film harness F in the part 136 is increased, and the film harness F is in the most slack state at the standby position. Therefore, it is possible to reduce the load applied to the film harness F in the standby position where the movable bodies 61 and 62 are held for a long time in the process of playing the game, and effectively prevent the cable from being disconnected. obtain. Further, the wiring holding portions 70 and 71 at the standby position are positioned closer to the introduction port 140a of the wiring introducing portion 140 than the wiring holding portions 70 and 71 at the movable position, so that the film harness is formed in the annular insertion portion 136. It is possible to reduce the wiring length of the cable to the minimum while reducing the load applied to the cable and preventing disconnection by simply rotating F once. As described above, the wiring length of the film harness F connected to the light emitter substrate 66 disposed on the movable bodies 61 and 62 is shortened within a range in which the rotational movement of the movable bodies 61 and 62 is allowed, and the movable body 61 is arranged. , 62 can be effectively prevented from being damaged.

(Change example)
In addition, as a gaming machine, not only what was shown in the Example but various structures are employable.

(1) In the embodiment, the movable body is configured to reciprocate between the standby position and the movable position. However, the movable body may be configured to move linearly between the standby position and the movable position. Any structure may be used as long as the movable body reciprocates.
(2) In the embodiment, the support portion (support arm) on which the movable body is disposed is configured to swing about the swing axis. However, the support portion may be configured to move linearly. Any configuration may be used as long as the support portion reciprocates between the standby position and the movable position.
(3) In the embodiment, the movable body is disposed on the support portion (support arm), and is moved to a position (device main body and support portion) that is relatively displaced with respect to the movable body as the movable body reciprocates. The apparatus main body is configured to dispose the first magnetic adhesion member and the second magnetic adhesion member, but displaces the movable body relative to the movable body by reciprocating the movable body by arranging the movable body in the apparatus main body. The first and second magnetized members may be disposed on the first and second magnetized members.
(4) In the embodiment, a metal plate on which a movable magnet can be magnetized is adopted as the first and second magnetized members. However, the first and second magnetized members are movable by using magnets. It can also be configured to be magnetically attached to a body magnet. In this case, although the number of magnets increases, only one magnet moves in accordance with the operation of one movable body, so that the installation position of the magnetic sensor provided in the gaming machine is the same as in the embodiment. The degree of freedom in designing the movable effect device can be improved.
(5) In the embodiment, the movable effect device is arranged on the installation member. However, the movable effect device may be arranged on the plate-like member, and the middle frame (main body frame) or the front frame ( You may make it arrange | position with respect to frame bodies of gaming machines, such as a decoration frame. In addition, when a movable effect device is employed in a slot machine (rotating-type game machine), the movable effect device is arranged on a housing that forms the main body of the slot machine or a door that closes the opening of the housing. It is also possible to adopt a configuration to be provided.
(6) In the embodiment, the magnet moves closer to the first magnetized member in the direction in which the arrangement end of the movable body in the support portion moves when displaced from the movable position to the standby position. Although it is configured to be magnetically attached, the magnet may be moved closer to the first magnetically attached member in the direction opposite to the direction in which the movable body arranged end portion moves in the support portion.
(7) In the embodiment, an annular insertion part is formed around the bearing cylinder part through which the rotating shaft of the movable body is inserted, and the wiring (film harness) is wound. A winding part may be formed.
(8) In the embodiment, the movable body is disposed on the support portion (support arm), and is moved to a position (device main body and support portion) that is relatively displaced with respect to the movable body as the movable body reciprocates. Although the first magnetic adhesion member and the second magnetic adhesion member are arranged, the movable body may be arranged in the apparatus main body, and the annular insertion portion may be formed in the apparatus main body. Moreover, you may make it provide a cyclic | annular insertion part in a movable body.
(9) The electric component disposed on the movable body is not limited to the light emitting substrate shown in the embodiment, and may be any component that operates electrically, and may be disposed on the movable body. The number of electrical components installed is also determined as appropriate.
(10) In the embodiment, the game board is made of a transparent plate. However, the game board is not limited to this, and the game board may be made opaque by using a plywood or a synthetic resin material.
(11) In the embodiment, the pachinko machine has been described as an example of the gaming machine. However, the present invention is not limited to this, and various gaming machines such as an arrangement ball machine, a pinball machine, and a slot machine machine can be adopted.

Further, the present application includes, for example, the following technical ideas.
A gaming machine including the configuration according to claim 4,
When the movable body (61, 62) is displaced from the movable position to the standby position, the magnet (75) is moved in the direction in which the arrangement end of the movable body (61, 62) in the support section (121, 122) moves. ) Is configured to move close to and magnetically attach to the first magnetic attachment member (93).
As described above, the direction in which the arrangement end of the movable body in the support portion moves when the displacement from the movable position to the standby position is made to coincide with the direction in which the magnet moves close to the first magnetized member. Accordingly, the magnet can be urged toward the first magnetized member as the support portion swings, and the magnet can be securely magnetized to the first magnetized member.

60A Upper movable production device (movable production means)
60B Lower movable effect device (movable effect means)
61 First movable body (movable body)
62 Second movable body (movable body)
75 Magnet 80 Device body (base part)
93 First sheet metal member (first magnetized member)
121 1st support arm (support part)
122 Second support arm (support part)
133 2nd sheet metal member (2nd magnetized member)
150 Drive motor (drive means)

Claims (4)

In a gaming machine equipped with a movable effect means that produces an effect by movement,
The movable production means is
A movable body that reciprocates between a standby position and a movable position as the driving means is driven;
One magnet provided on the movable body;
A first magnetized member that is provided at a position that is relatively displaced with respect to the movable body as the movable body reciprocates, and on which the magnet is magnetized while the movable body is in a standby position;
A second magnetically attached member that is provided at a position that is relatively displaced with respect to the movable body as the movable body reciprocates, and on which the magnet is magnetically attached in a state where the movable body is in the movable position;
One magnet provided on the movable body is magnetized on each of the first and second magnetized members, so that the movable body is moved to both the standby position and the movable position along with the reciprocating movement. A gaming machine configured to be held in position. The movable production means is
A support unit that reciprocates as the drive unit is driven is configured, and the movable body is configured to be displaced with respect to the support unit as the support unit reciprocates.
The gaming machine according to claim 1, wherein the movable body reciprocates between a standby position and a movable position by reciprocating the support portion in accordance with driving of the driving means. The movable production means is
Comprising a base portion on which the driving means is disposed, the support portion being configured to reciprocate with respect to the base portion;
The gaming machine according to claim 2, wherein the first magnetized member is disposed on the base portion, and the second magnetized member is disposed on the support portion. The one end side of the support portion is swingably supported with respect to the base portion, and the other end side of the support portion is rotatable about an axis parallel to the swing axis of the support portion. The intermediate position in the longitudinal direction of the movable body is supported,
The first magnet in which the magnet is disposed on the movable body so as to be positioned outwardly away from the swing shaft of the support portion at the standby position, and the magnet at the standby position is disposed on the base portion. The gaming machine according to claim 3, wherein the gaming machine is configured to be magnetically attached to the magnetically attached member.

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