JP5608390B2 - Movable production device for pachinko machines - Google Patents

Description

  The present invention relates to a pachinko gaming machine, and more particularly, to a movable effect device for a pachinko gaming machine that produces an effect by operating along a board surface of a game board in accordance with a player's game.

  Conventionally, in pachinko gaming machines, a gaming machine having two movable panel surface parts (gimmicks) described in Patent Document 1 below has been proposed. In this gaming machine, the two movable board surface parts are each constituted by a gimmick main body and a drive mechanism, and are provided at the lower edge of the opening of the gaming board.

  Thus, the two movable platen parts are configured to tilt the gimmick bodies in opposite directions in the left-right direction under the drive of the corresponding drive mechanisms.

  Here, the two movable platen surface parts each include a surface member, a printed board, an arm portion, and a harness for each gimmick main body. The printed circuit board is provided on the front surface member from the back side, and a plurality of light emitting diodes are mounted on the printed circuit board so as to face the front surface member from the back surface side. The harness is wired along the arm portion so as to connect the plurality of light emitting diodes to the power source.

JP 2009-195339 A

  By the way, in each of the two movable panel surface parts of the gaming machine, in order to connect a plurality of light emitting diodes to a power source through a harness, a troublesome work of connecting the harness to the power source through a connector is required. There is a problem that it takes time to connect the light emitting diode to the power source.

  In addition, although the harness is wired along the arm portion, the harness is only pressed into the arm portion, and is independent of the arm portion and exists as a free part. As a matter of course, there is a problem that an extra configuration necessary for pressing the harness is required.

  On the other hand, if a single flexible printed circuit board is used instead of the printed circuit board, arm part and harness of each of the two movable panel surface parts, the printed circuit board, harness and arm of each of the two movable panel surface parts. The six parts called the parts become a single part called the flexible printed circuit board, which leads to a reduction in the number of parts.

  However, the above-mentioned single flexible printed circuit board is constituted by, for example, a common substrate portion and two strip-like independent substrate portions extending from the common substrate portion, and two gimmick bodies are respectively provided. Each band-like independent substrate portion is supported by a band-like independent substrate portion, and for each gimmick main body, the light-emitting diode is connected to a power source via the wiring in the corresponding belt-like independent substrate portion and the wiring in the common substrate portion. When each gimmick body is tilted in the opposite direction in the left-right direction as described above by swinging in a curved shape in the plate thickness direction, the wiring of each strip-like independent substrate portion is simply formed in a straight line. If the wiring of each strip-like independent substrate portion is repeatedly bent in the thickness direction of the strip-like independent substrate portion, the wiring becomes fatigued over time, leading to poor conduction such as disconnection. Failure occurs.

  Therefore, in order to cope with the above, the present invention not only uses a single flexible printed board, but also an independent board provided with at least one corresponding lighting operation element for each movable decorative body. The above-mentioned flexible printed circuit board is configured to have a plurality of parts, and by elaborating on the wiring configuration in a plurality of independent board parts, the number of circuit boards, which has been essential in the past, for the lighting operation of each lighting operation element The number of parts such as wiring and assembly man-hours can be reduced, and even if multiple independent board parts are repeatedly swung in the direction of their thickness, the wiring in these independent board parts can be improved from fatigue. An object of the present invention is to provide a movable effect device for a pachinko gaming machine that is to be protected.

In solving the above problems, according to the present invention, in the movable effect device provided in the game board (Ba) of the pachinko gaming machine,
Illumination means (230);
A plurality of movable decorative bodies (240a, 240b, 240c);
Drive means (270, 260a-260c, 250a-250c, 245-247),
The illumination means comprises a single flexible printed circuit board (230a) and a plurality of illumination operation elements (236a, 236b, 237a, 237b, 238a, 238b),
Flexible printed circuit board
The common board part (230c) supported by a part of the game board, and the common board part are configured with a plurality of band-like independent board parts (230d to 230f) formed integrally,
From the plurality of parallel signal wiring portions (232a to 232c, 233a to 233c, 234a to 234c) that are included so as to extend independently over the common substrate portion and the plurality of strip-like independent substrate portions, and are independent from each other. A plurality of one-side wirings (232 to 234),
The other wiring included in the common substrate portion and the plurality of strip-like independent substrate portions so as to be electrically insulated from the plurality of one-side wiring, and the common wiring included in the common substrate portion The other side wiring which consists of a part (235a) and at least 1 independent wiring part (235b-235d) integrally extended from this common wiring part and each included in each of these strip | belt-shaped independent board | substrate parts (235), and
Each of the plurality of electrical decoration actuating elements is connected to each of the extending tip portions of the plurality of strip-like independent substrate portions from the plurality of one-side wiring sides, and the plurality of signal wiring portions and the at least one independent wiring portion. It is mounted so that it can be operatively connected to
The plurality of movable decorative bodies are movably supported by the driving means, and each of the plurality of strip-like independent substrate portions is curved in the thickness direction between the extended tip portion and the common substrate portion. Are held to form curved portions (j, k, m) ,
Each of the plurality of independent wiring portions is formed wider than each of the plurality of signal wiring portions,
In the above SL multiple independent board unit, for respective independent substrate portion, its said plurality of at least one of the signal wiring portion and the at least one independent wire portion has a width at the corresponding site for its respective said curved portion It is formed by bending in a direction to form bent portions (W1 to W3, Wa to Wf).
Movable production device for gaming machines.

  As described above, the common board portion supported by a part of the game board, and the plurality of independent board portions formed integrally with the common board portion and independently extending from the common substrate portion, However, it is comprised with a single flexible printed circuit board.

  For this reason, a plurality of substrates that have been conventionally required in the movable effect device need only be a single flexible printed circuit board. As a result, the number of component parts in the movable effect device, the illumination operation of each illumination activation element It is possible to reduce the number of connecting parts such as wiring and the assembly man-hour of the movable effect device.

Here, as described above, each of the plurality of independent wiring portions is formed wider than each of the plurality of signal wiring portions. Accordingly, the plurality of strip-like independent substrate portions of the flexible printed circuit board are curved so as to protrude from the independent wiring portion side toward the plurality of signal wiring portions, respectively. Even if it is repeatedly displaced so as to be positioned inside the plurality of signal wiring portions, each of the at least one independent wiring portion is formed wider than each of the plurality of signal wiring portions. At least one independent wiring portion does not cause a conduction failure such as disconnection.
Further, as described above, in each of the plurality of independent substrate portions, at least one of the plurality of signal wiring portions and the at least one independent wiring portion is a corresponding portion with respect to the corresponding bending portion. And bent in the width direction to form a bent portion.

  Accordingly, each bent portion is formed with a spread in each width direction in each corresponding curved portion. For this reason, when each independent substrate portion is repeatedly displaced in its plate thickness direction at each corresponding curved portion, the strain stress due to the curved deformation of each curved portion caused by this displacement is respectively applied to each bent portion. It acts as a load throughout.

  As a result, the load acting on each bent portion is significantly reduced as compared with the case where at least one of the plurality of signal wiring portions and at least one independent wiring portion is simply formed in a straight line. Therefore, even if each independent board | substrate part repeats curved displacement as mentioned above, the elastic fatigue of each corresponding bending part can be reduced favorably.

According to the second aspect of the present invention, in the movable effect device provided in the game board (Ba) of the pachinko gaming machine,
A support wall member (220) supported on a part of the game board on the back side thereof and extending toward the back side of the central opening (13) of the game board;
Illumination means (230);
A plurality of movable decorative bodies (240a, 240b, 240c);
Drive means (270, 260a-260c, 250a-250c, 245-247),
Illumination means
A single flexible printed circuit board (230a);
A plurality of illumination operation elements (236a, 236b, 237a, 237b, 238a, 238b) each having a plurality of illumination operation parts (R, G, B);
Flexible printed circuit board
A common substrate portion (230c) supported on the back surface of the support wall member;
The common substrate portion is formed integrally with a plurality of band-like independent substrate portions (230d to 230f) that are independently extended from the common substrate portion.
The common layer portion (231a) included in the common substrate portion and the common layer portion are integrally formed and extend independently from the common layer portion in parallel to each other, and each of the plurality of strip-like independent substrates. A flexible electrical insulating layer (231) formed by each band-shaped independent layer portion (231b to 231d) included in each of the portions;
A plurality of one-side wirings formed of a flexible metal thin film so as to extend independently from the common layer portion to the plurality of strip-like independent layer portions along one side surface of the flexible electrical insulating layer. A plurality of one-side wirings (232 to 234) each including a plurality of parallel signal wiring parts (232a to 232c, 233a to 233c, 234a to 234c),
A common wiring portion (235a) provided along the other side surface of the common layer portion, and a plurality of independent wiring portions (235b to 235d) extending from the common wiring portion and provided along the plurality of strip-like independent layer portions, respectively. And the other side wiring (235) formed with a flexible metal thin film,
Each of the plurality of electrical decoration actuating elements is mounted on each extending tip of the plurality of strip-like independent substrate parts from the one side surface of the flexible electrical insulating layer, and the corresponding plurality of electrical decoration operation parts Each one side terminal of each of the plurality of corresponding signal wiring portions is connected to each of the corresponding plurality of electric decoration operating portions, and each of the corresponding one of the plurality of electrical lighting operation portions, each of the plurality of strip-like independent layer portions. Are connected to each of the plurality of independent wiring portions via
The plurality of movable decorative bodies are movably supported by the driving means via the support wall member, and each of the plurality of strip-like independent substrate portions is disposed between the extended tip portion and the common substrate portion. Curving in the plate thickness direction to hold the curved portion (j, k, m) ,
Each of the plurality of independent wiring portions is formed wider than each of the plurality of signal wiring portions,
In the above SL multiple independent board unit, for respective independent substrate portion, its said plurality of at least one of the signal wiring portion and the at least one independent wire portion has a width at the corresponding site for its respective said curved portion It is formed by bending in a direction to form bent portions (W1 to W3, Wa to Wf).

  As described above, the common substrate portion supported on the back surface of the support wall member, and the plurality of independent substrate portions formed integrally with the common substrate portion and independently extending from the common substrate portion, However, it is comprised with a single flexible printed circuit board.

  Here, among the flexible electrical insulating layer included in the flexible printed circuit board, the plurality of one-side wirings, and the other-side wirings, the flexible electrical insulating layer is integrally formed with the common layer portion and the common layer portion. And each band-like independent layer portion that is formed and extends from the common layer portion independently and in parallel to each other. The common layer portion is included in the common substrate portion of the flexible printed circuit board, and each band-like independent layer portion is formed. The layer portion is included in each of the plurality of strip-like independent substrate portions.

  In addition, the plurality of one-side wirings are formed as a plurality of parallel signal wiring portions that are independent from each other, extending from the common layer portion to the plurality of strip-like independent layer portions along one side surface of the flexible electrical insulating layer. Is included. In addition, the other side wiring is constituted by a common wiring portion and a plurality of independent wiring portions integrally extending from the common wiring portion, and the common wiring portion forms a common layer portion of the flexible electrical insulating layer. In addition, it is formed from the side of the other side, and is formed on the plurality of independent wiring portions from the back side to the plurality of strip-like independent layer portions of the flexible electrical insulating layer, and is included in the flexible printed circuit board.

  In addition, a plurality of illumination actuating elements are respectively mounted on the plurality of strip-like independent substrate portions from one side of the flexible electrical insulating layer, and each of the plurality of illumination actuating elements is operated The part is connected to each of the plurality of signal wiring parts at each one side terminal, and is connected to each of the above independent wiring parts via each of the plurality of strip-like independent layer parts at each other side terminal. Yes.

  For this reason, a plurality of substrates that have been conventionally required in the movable effect device need only be a single flexible printed circuit board. As a result, the number of component parts in the movable effect device, the illumination operation of each illumination activation element It is possible to reduce the number of connecting parts such as wiring and the man-hour for assembling the movable effect device.

  Here, as described above, in each of the plurality of independent substrate portions, at least one of the plurality of signal wiring portions and the at least one independent wiring portion corresponds to the corresponding curved portion. Are bent in the width direction to form a bent portion.

  Accordingly, each bent portion is formed with a spread in each width direction in each corresponding curved portion. For this reason, when each independent substrate portion is repeatedly displaced in its plate thickness direction at each corresponding curved portion, the strain stress due to the curved deformation of each curved portion caused by this displacement is respectively applied to each bent portion. It acts as a load throughout.

As a result, the load acting on each bent portion is significantly reduced as compared with the case where at least one of the plurality of signal wiring portions and at least one independent wiring portion is simply formed in a straight line. Therefore, even if each independent board | substrate part repeats curved displacement as mentioned above, the elastic fatigue of each corresponding bending part can be reduced favorably.
Here, each independent wiring portion is formed wider than each of the plurality of signal wiring portions. Accordingly, the plurality of independent board portions of the flexible printed circuit board are curved so as to protrude from the independent wiring portion side toward the plurality of signal wiring portions, respectively, and each independent wiring portion has a plurality of corresponding ones. Even if it is repeatedly displaced so as to be positioned inside the signal wiring portion, conduction failure such as disconnection of each independent wiring portion can be prevented even better.
As a result, the effects of reducing the number of component parts in the movable effect device as described above, the number of connection parts such as wiring for the illumination operation of each illumination activation element, and the assembly work man-hours of the movable effect device, This can be achieved while more reliably preventing the occurrence of poor conduction such as disconnection of the plurality of signal wiring portions.

  According to the third aspect of the present invention, in the movable effect device for the pachinko gaming machine according to the first or second aspect, in the plurality of independent substrate portions, for each independent substrate portion, The plurality of signal wiring portions are bent in the width direction at corresponding portions with respect to the corresponding bending portions to form bent portions (W1 to W3, Wa to Wf).

  Thereby, the effect of the invention of Claim 1 or 2 can be achieved more specifically. In addition, the above-mentioned width direction means the direction along the surface of the said independent board | substrate part.

  Here, as described in claim 4, in the invention described in any one of claims 1 to 3, the shape of each bent portion is trapezoidal, V-shaped, or W-shaped. Also good.

  If each at least one independent wiring portion is formed wider than each of the plurality of signal wiring portions, each at least one independent wiring portion prevents conduction failure such as disconnection. The above-mentioned operational effects can be achieved.

  If each of the plurality of signal wiring portions has a width within a range of 2.5 to 3.5 times the conventional predetermined width, each of the independent printed circuit boards of the flexible printed circuit board is As described above, even when both of the at least one connector member and the plurality of lighting operation elements are mounted on the flexible printed circuit board as described above, Each of them can be more resistant to fatigue than the prior art, and can achieve the effects of the above-described invention while preventing the occurrence of poor conduction due to disconnection or the like even better.

  In addition, if the plurality of illumination actuating elements and at least one connector member are respectively mounted on the plurality of strip-like independent substrate portions and the common substrate portion of the flexible printed circuit board from one side of the flexible electrical insulating layer, Each of the electrical decoration actuating element and the at least one connector member is mounted on the plurality of strip-like independent substrate portions and the common substrate portion of the flexible printed circuit board from the same surface side.

  For this reason, the operation of connecting the plurality of lighting operation elements and at least one connector member to the plurality of one-side wirings and the other-side wirings by soldering or the like at the respective connection terminals may turn the flexible printed circuit board over. It can be done continuously without having to. As a result, the above-described effects can be achieved while simplifying the work required for mounting and connecting the plurality of illumination actuating elements and at least one connector member to the flexible printed circuit board.

In the invention according to claim 1 or 2, the driving means is
An electric motor (270);
A plurality of gear members (260a to 260c) accommodated sequentially adjacent in the left-right direction in the housing;
A plurality of plate-shaped guide members (250a to 250c) positioned corresponding to the plurality of gear members in the housing,
Each of the plurality of gear members includes a gear portion (261, 263, 266) that is rotatably supported via the rear wall, and a protrusion portion that protrudes forward from the gear at a position that is shifted from its axis. 262, 264, 267),
The electric motor is supported on the rear wall of the housing so as to be coaxially opposed to the gear portion of any one of the plurality of gear members, and coaxially with the gear portion of any one of the gear members. Are connected,
Each of the plurality of plate-shaped guide members has a long plate portion (251, 254, 255) and a corresponding gear member of the plurality of gear members formed so as to open in a concave shape toward the rear from the long plate portion. A concave wall portion (252, 255, 258) that accommodates the projection portion of the projection plate in a relatively movable manner, and a projection portion (253, 256, 259) projecting forward from the longitudinal plate portion,
The common board part is fixed to the lower part of the front wall in the housing, and the independent board parts are arranged on the front wall so as to expose the corresponding electrical operation elements to the front side. It is inserted forward through each opening (221-223) formed in the left-right direction on the upper side of the lower part,
Each of the plurality of movable decorative bodies includes a decorative member (241) that holds the corresponding independent substrate portion so as to enclose a corresponding electric decoration actuating element, and a longitudinal support arm that extends upward from the decorative member ( 242 to 244),
Each of the plurality of plate-like guide members has a plurality of electrical lighting operations through the longitudinal grooves (226 to 228) formed in the upper portions of the openings of the front wall of the housing at the protrusions. It is connected to the longitudinal direction intermediate portion of each support arm of the element so as to be movable in the longitudinal direction of the longitudinal groove,
Each support arm of the plurality of lighting operation elements may be connected to the longitudinal groove portion so as to be movable in the longitudinal direction at the upper part in the longitudinal direction.

  According to this, when the electric motor rotates, any one of the gear members rotates together with the gear portion, the remaining both gear members also rotate, and the protrusions of the gear members move to the gear members. Rotate around the gear axis.

  Along with this, when the plurality of plate-shaped guide members are respectively pushed along with the rotation by the projections of the corresponding gear members in the respective longitudinal groove portions, the plurality of plate-shaped guide members are As a result, the protrusions reciprocate along with the corresponding movable decorative bodies in the pushing directions of the protrusions of the corresponding gear members along the longitudinal grooves of the housing. At this time, in the electrical decoration means, each independent substrate portion of the flexible printed circuit board is reciprocally displaced in the movement direction of each corresponding movable decorative body in each curved state as described above.

  In such a state, if a plurality of electric decoration actuating elements perform an electric decoration operation for each corresponding independent substrate part in each electric decoration operation part, a plurality of movable decorative bodies correspond to each corresponding Combined with the lighting operation of the lighting operation element, the production operation for the pachinko gaming machine is exhibited.

  In addition, if each one-side wiring of the flexible printed circuit board is formed on the front side rather than the back side of the flexible electrical insulating layer, each signal wiring portion of each one-side wiring may cause poor conduction due to disconnection or the like. Nor.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows a corresponding relationship with the specific means as described in embodiment mentioned later.

It is a front view showing one embodiment of a pachinko gaming machine according to the present invention. It is a front view which shows the game board of the pachinko gaming machine of FIG. FIG. 2 is an exploded perspective view showing the movable effect device in FIG. 1. It is an expansion perspective view which shows the other side housing member which assembled | attached the electrical decoration board and this electrical decoration board in the movable production | presentation apparatus of FIG. It is a perspective view which shows the electrical decoration board of FIG. It is a partially broken surface view of the flexible printed circuit board in the electrical decoration board of FIG. It is a partially broken rear view of the flexible printed circuit board in the electrical decoration board of FIG. It is a surface view which shows the flexible printed circuit board formed by mounting and connecting 3 pairs of light emitting diodes and both one side connector members in this embodiment. It is a side view which shows the flexible printed circuit board which mounts and connects three pairs of light emitting diodes and both one side connector members in this embodiment. It is a perspective view which shows an example of a positional relationship between an electrical decoration actuating element, the independent board | substrate part of a flexible printed circuit board, and a pair of electrical decorating actuating element in the movable production | presentation apparatus of FIG. FIG. 4 is an assembly configuration diagram illustrating a configuration in which a plurality of electrical decoration actuating elements are assembled to the other housing member together with a plurality of gear members and an electrical decoration board in one operation state viewed from the plurality of electrical decorating element sides in the movable effect device of FIG. 3. is there. In the movable effect device of FIG. 3, the assembly configuration between the plurality of lighting operation elements, the plurality of gear members, and the lighting board is from the side of the lighting board and the plurality of gear members in a state where the other housing member is omitted. It is a partially broken assembly | attachment block diagram shown in the seen one operation state. In the movable effect device of FIG. 3, the assembly configuration between the plurality of lighting operation elements, the plurality of gear members, and the lighting board is from the side of the lighting board and the plurality of gear members in a state where the other housing member is omitted. It is a partially broken assembly | attachment structure perspective view shown in the seen one operation state. FIG. 3 is an assembly configuration diagram illustrating a configuration in which a plurality of electric decoration actuating elements are assembled to the other housing member together with a plurality of gear members and an electric decoration board in another operating state as viewed from the plurality of electric decoration actuating elements. It is. In the movable effect device of FIG. 3, the assembly configuration between the plurality of lighting operation elements, the plurality of gear members, and the lighting board is from the side of the lighting board and the plurality of gear members in a state where the other housing member is omitted. It is a partially broken assembly | attachment block diagram shown in the other operating state seen. In the movable effect device of FIG. 3, the assembly configuration between the plurality of lighting operation elements, the plurality of gear members, and the lighting board is from the side of the lighting board and the plurality of gear members in a state where the other housing member is omitted. It is a partially broken assembly | attachment structure perspective view shown in the other operating state seen. FIG. 3 is an assembly configuration diagram illustrating a configuration in which a plurality of electric decoration actuating elements are assembled to the other housing member together with a plurality of gear members and an electric decoration board in another operating state as viewed from the plurality of electric decoration actuating elements. It is. In the movable effect device of FIG. 3, the assembly configuration between the plurality of lighting operation elements, the plurality of gear members, and the lighting board is from the side of the lighting board and the plurality of gear members in a state where the other housing member is omitted. It is a partially broken assembly | attachment block diagram shown in the other operating state seen. In the movable effect device of FIG. 3, the assembly configuration between the plurality of lighting operation elements, the plurality of gear members, and the lighting board is from the side of the lighting board and the plurality of gear members in a state where the other housing member is omitted. It is a partially broken assembly | attachment structure perspective view shown in the other operating state seen. (A)-(c) is a fragmentary fracture | rupture explanatory drawing which shows the change of the movement state of one electrical decoration actuating element along the other side housing member in the movable production | presentation apparatus of FIG. 3 in the state seen from the said electrical decoration actuating element side. . It is the elements on larger scale which show one of the principal parts of 2nd Embodiment of this invention. It is a partial expanded fracture view which shows one of the principal parts of the said 2nd Embodiment. It is a partial expanded fracture view which shows one of the principal parts of 3rd Embodiment of this invention. It is a partial expanded fracture view which shows one of the principal parts of the said 3rd Embodiment. It is the elements on larger scale which show one of the principal parts of 4th Embodiment of this invention. It is a partial expanded fracture view which shows one of the principal parts of the said 4th Embodiment.

Embodiments of the present invention will be described below with reference to the drawings.
(First embodiment)
FIG. 1 shows a first embodiment of a pachinko gaming machine to which the present invention is applied. The pachinko gaming machine is erected on an island in the pachinko hall. The pachinko gaming machine has a machine frame (not shown) and a gaming machine main body supported to be openable and closable in the front-rear direction. B and the front door FD. The pachinko machine is a so-called digipachi pachinko machine.

  As shown in FIG. 2, the gaming machine main body B includes a gaming board Ba, and the gaming board Ba is fitted into a frame (not shown) of the gaming machine main body B. The gaming machine main body B is supported by the frame so as to be openable and closable in the front-rear direction with respect to the machine frame.

  The game board Ba includes a game board 10, a guide rail 20, an annular center structure 30, and a game nail group 40. The guide rail 20 is disposed along the front surface 11 of the game board 10 (hereinafter also referred to as the board surface 11 of the game board Ba). The guide rail 20 is disposed on the front surface 11 of the game board 10 on the inner peripheral side thereof. The game area 12 is formed.

  Thus, the guide rail 20 guides a game ball launched from a ball launching device (not shown) by the turning operation of the handle H (see FIG. 1), and rolls it into the game area 12. In addition, the said ball | bowl launching device is arrange | positioned in the lower right part of the said frame of the gaming machine main body B. In addition, the handle H is provided as a component part of the ball launcher from the front of the lower right portion of the frame body of the gaming machine main body B.

  As shown in FIG. 2, the center structure 30 is assembled from the front surface 11 side to the outer peripheral portion of the central opening 13 of the game board 10 (also referred to as the central opening 13 of the game board Ba). The game nail group 40 is composed of a large number of game nails 41. These game nails 41 are arranged on the game board 10 on the front surface 11 side from the left side to the lower side of the center structure 30 inside the guide rail 20. It has been distributed from. Thus, according to the game nail group 40, the game ball guided from the guide rail 20 into the game area 12 rolls downward along the front surface 11 of the game board 10 through collision with each game nail 41. To do.

  Further, the game board Ba includes a start chucker 50, an electric tulip 60, a through gate 70, a windmill 80, a plurality of ordinary winning ports 90 and an attacker 100. The start chucker 50, the electric tulip 60, the through gate 70, The windmill 80, each normal winning opening 90, and the attacker 100 are assembled in the game area 12 on the front surface 11 of the game board 10 at each position shown in FIG.

  The start chucker 50 is located immediately below the center of the lower edge of the center structure 30. The start chucker 50 is a jackpot lottery (lottery of whether or not the jackpot is based on the winning of a game ball in the start winning opening. ) And an opportunity to pay out a predetermined number of prize balls.

  The electric tulip 60 is positioned directly below the start chucker 50 in order to play a role as an ordinary electric accessory. The electric tulip 60 closes both blade members for winning a game ball in the starting winning opening. Regulate by state. In addition, the electric tulip 60 facilitates the winning of a game ball to the start winning opening in the open state of the both blade members, and gives an opportunity to pay out a predetermined number of prize balls based on the winning, Like the start chucker 50, it provides a chance to win a jackpot.

  As shown in FIG. 2, the through gate 70 is located on the left side of the center of the left edge of the center structure 30, and this through gate 70 rolls downward along the front surface 11 of the game board 10 from directly above. Give an opportunity to pass to the playing ball. Thereby, the through gate 70 provides an opportunity to draw a normal symbol based on the passing of the game ball.

  The windmill 80 is located below the through gate 70, and the windmill 80 rotates when it is hit along the front surface 11 of the game board 10 by a game ball rolling downward from the through gate 70 or its periphery. While rolling the game ball downward. Each of the plurality of normal winning ports 90 provides an opportunity to pay out a predetermined number of prize balls as the game balls are won.

  As shown in FIG. 2, the attacker 100 is located immediately below the electric tulip 60, and the attacker 100 provides an opportunity for winning a game ball to the grand prize opening by opening the grand prize opening.

  Further, as shown in FIG. 2, the game board Ba includes an effect image display device 110 and left and right movable effect devices 200. The effect image display device 110 includes a display panel 111, and the display panel 111 is provided on the game board 10 so as to face the central opening 13 from the back side.

  As shown in FIG. 2, the left and right both-side movable effect device 200 is provided on both left and right sides of the mountain-shaped decorative accessory 31 formed on the upper portion of the center structure 30. The left movable effect device 200 includes the game board Ba and the display panel 111 so that the three movable decorative bodies 240 a to 240 c are moved up and down along the front surface of the display panel 111 just below the left side of the mountain-shaped decorative object 31. Is assembled to the game board Ba from the back side.

  As shown in FIG. 3, the left-side movable effect device 200 includes a one-side housing member 210 having a substantially U-shaped cross section and an other-side housing member 220 having a substantially flat plate shape. At its outer peripheral portion, it is assembled to the opening of the one-side housing member 210 to form a substantially rectangular parallelepiped housing.

  Further, as shown in FIG. 3, the left movable effect device 200 includes an electrical decoration board 230, three movable decorative bodies 240 a to 240 c, three plate guide members 250 a to 250 c, and three gear members 260 a to 260 c. And.

  As shown in any of FIGS. 3 to 5, the electrical decoration board 230 includes a single flexible printed board 230 a that is a flexible wiring board and a belt-like back board 230 b. The flexible printed circuit board 230a is configured to include a flexible electrical insulating layer 231, three flexible positive-side wirings 232 to 234, and one flexible negative-side wiring 235 (see FIGS. 5 to 7). .

  The flexible electrical insulating layer 231 is made of 12 (μm) with an electrically insulating material such as polyimide so that the strip-shaped common layer portion 231a and the three strip-shaped independent layer portions 231b to 231d have the shape shown in FIG. It is formed in a thin film and integrally with a thickness within a range of ˜50 (μm).

  In the electrical insulating layer 231, the three strip-shaped independent layer portions 231 b to 231 d are formed integrally with the strip-shaped common layer portion 231 a and intersect the longitudinal direction from one side edge in the width direction of the strip-shaped common layer portion 231 a. In such a manner, they are extended side by side at an interval from each other.

  Here, among the independent layer portions 231b to 231d, the band-like independent layer portion 231b includes a narrow portion a extending from one side edge portion in the width direction of the common layer portion 231a, and the narrow portion a in FIG. And a wide portion b extending so as to bend gently toward the right side of the figure.

  The band-like independent layer part 231c is gently bent from the narrow side c extending from one side edge in the width direction of the band-like common layer part 231a and the extending end of the narrow part c to the left in FIG. And a wide portion d extending in this manner.

  Further, the band-like independent layer portion 231d is formed so that the narrow portion e extending from one side edge portion in the width direction of the common layer portion 231a and the extending end portion of the narrow portion e gradually toward the right side in FIG. It is formed by a wide portion f extending so as to be bent.

  The three positive-side wirings 232 to 234 are formed of longitudinal flexible copper foil along the surface of the electrical insulating layer 231 as shown in FIG. Among the three positive-side wirings 232 to 234, the positive-side wiring 232 includes three signal wiring portions 232a to 232c for a pair of light emitting diodes 236a and 236b (described later). As shown in FIG. 6, the portions 232a to 232c extend from the wide portion b through the narrow portion a of the independent layer portion 231b along the surface of the strip-like independent layer portion 231b of the electrical insulating layer 231, and are further common to the strip shape. It is formed so as to extend in parallel with each other from the left end portion to the right end portion along the surface of the layer portion 231a. The flexible copper foil described above may generally be a flexible copper thin film.

  Here, as shown in FIG. 6, the positive-side wiring 232 has a bent portion W <b> 1, and the bent portion W <b> 1 is a convex curved portion j to be described later in the narrow portion a of the positive-side wiring 232. In the corresponding wiring part (see FIG. 5) (corresponding wiring parts with respect to the convex curved portion j of the three signal wiring parts 232a to 232c), it is formed to be bent in a trapezoidal shape to the right side in the figure.

  The positive wiring 233 includes three signal wiring portions 233a to 233c for another pair of light emitting diodes 237a and 237b (described later). These signal wiring portions 233a to 233c are shown in FIG. As shown in the figure, it extends along the surface of the band-shaped independent layer portion 231c of the electrical insulating layer 231 from the wide portion d through the narrow portion c of the independent layer portion 231c, and further extends along the surface of the band-shaped common layer portion 231a. It is formed so as to extend in parallel with each other from the intermediate portion in the direction to the right end portion.

  Here, as shown in FIG. 6, the positive-side wiring 233 has a bent portion W <b> 2, and the bent portion W <b> 2 is a convex curved portion k described later in the narrow portion c of the positive-side wiring 233. In a corresponding wiring part (see FIG. 5) (corresponding wiring parts with respect to the convex curved part k of the three signal wiring parts 233a to 233c), it is formed to be bent in a trapezoidal shape to the left in the figure.

  Further, the positive wiring 234 includes three signal wiring portions 234a to 234c for the other pair of light emitting diodes 238a and 238b (described later). These signal wiring portions 234a to 234c are electrically connected to each other. Along the surface of the strip-shaped independent layer portion 231d of the insulating layer 231, it extends from the wide portion f through the narrow portion e of the independent layer portion 231d, and is parallel to the longitudinal intermediate portion along the surface of the strip-shaped common layer portion 231a. It is formed to extend.

  Here, as shown in FIG. 6, the positive-side wiring 234 has a bent portion W <b> 3, and the bent portion W <b> 3 is a convex curved portion m, which will be described later, of the narrow portion e of the positive-side wiring 234. In the corresponding wiring part (see FIG. 5) (corresponding wiring parts with respect to the convex curved portion m of the three signal wiring parts 234a to 234c), it is formed to be bent in a trapezoidal shape to the left in the figure.

  In the first embodiment, the thicknesses of the positive-side wirings 232 to 234 are, for example, 0.2 (mm), as in the conventional case, but the signal wiring portions 232a to 232c, 233a to 233c, and The widths 234a to 234c are wider than a predetermined width (for example, 0.5 (mm)) of the conventional signal wiring portion, and are set to, for example, three times the width (1.5 (mm)).

  One negative-side wiring 235 is a long flexible copper foil so as to integrally have a negative-side common wiring portion 235a and three negative-side independent wiring portions 235b to 235d in the shape shown in FIG. Therefore, it is formed along the back surface of the electrical insulating layer 231. In the first embodiment, the thickness of the negative-side wiring 235 is, for example, 0.2 (mm), as in the conventional case. However, the width of each of the negative-side independent wiring portions 235b to 235d is different from each signal. It is wider than the widths of the wiring portions 232a to 232c, 233a to 233c, and 234a to 234c, for example, 2 (mm).

  Here, the negative common wiring portion 235a faces each corresponding wiring portion with respect to the strip-shaped common layer portion 231a of the electrical insulating layer 231 among the signal wiring portions 232a to 232c via the strip-shaped common layer portion 231a. The strip-shaped common layer portion 231a is formed along the longitudinal direction thereof.

  Of the three negative-side independent wiring portions 235b to 235d, the negative-side independent wiring portion 235b is negative so as to face the corresponding portion of the signal wiring portion 232 with respect to the belt-like independent layer portion 231b via the belt-like independent layer portion 231b. The side common wiring portion 235a is formed along the back surface of the band-like independent layer portion 231b from one side edge in the width direction.

  The negative-side independent wiring portion 235c extends from one side edge in the width direction of the negative-side common wiring portion 235a so as to face the corresponding portion of the signal wiring 233 with respect to the band-like independent layer portion 231c via the band-like independent layer portion 231c. It is formed along the back surface of the band-shaped independent layer portion 231c.

  Further, the negative-side independent wiring portion 235d has one side edge in the width direction of the negative-side common wiring portion 235a so as to face a corresponding portion of the signal wiring 234 with respect to the band-like independent layer portion 231d via the band-like independent layer portion 231d. Is formed along the back surface of the belt-like independent layer portion 231d.

  In addition, the electrical insulating layer 231 is covered with a transparent insulating coating film part h via the positive-side wirings 232 to 234 on the surface, and the back surface of the electrical insulating layer 231 is connected to the negative-side wiring 235. And is covered with a transparent insulating coating film part i (see FIGS. 6 and 7). As a result, the electrical insulating layer 231, the positive-side wirings 232 to 234, and the negative-side wiring 235 are included in the flexible printed circuit board 230 a.

  In the first embodiment, the corresponding portion of the flexible printed circuit board 230a corresponding to the common layer portion 231a of the electrical insulating layer 231 is hereinafter referred to as a common substrate portion 230c, and the individual independent layer portions 231b to 231d of the electrical insulating layer 231 are used. Corresponding portions for are referred to as independent substrate portions 230d to 230f. Accordingly, corresponding portions of the positive-side wirings 232 to 234 and the negative-side wiring 235 with respect to the common layer portion 231a are included in the common substrate portion 230c, and among the positive-side wirings 232 to 234 and the negative-side wiring 235, The corresponding portions corresponding to the individual independent layer portions 231b to 231d are included in the independent substrate portions 230d to 230f, respectively.

  Further, as shown in any of FIGS. 3, 5, 8, and 9, the illumination board 230 includes three pairs of light-emitting diodes 236a, 236b, 237a, 237b, and 238a, 238, and both one-side connector members. 239a and 239b.

  The three pairs of light emitting diodes 236a, 236b, 237a, 237b, and 238a, 238 serve as an illumination operating element for each light emitting diode, and the three pairs of light emitting diodes 236a, 236b, 237a, 237b, and 238a 238b emits light having red (R), green (G), and blue (B) light emitting parts (hereinafter also referred to as light emitting part R, light emitting part G, and light emitting part B) as the respective lighting operation parts. It is composed of a diode (hereinafter also referred to as LED).

  The pair of LEDs 236a and 236b are shown in FIG. 5 from the side of the insulating coating film portion h at a position corresponding to the wide portion b (see FIG. 6) of the independent layer portion 231b of the independent substrate portion 230d of the flexible printed board 230a. It is mounted so as to be positioned up and down.

  Here, of the pair of LEDs 236a and 236b, the LED 236a corresponds to the wide portion b of the insulating coating film portion h at the positive terminals of the light emitting portion R, the light emitting portion G, and the light emitting portion B, respectively. The one side connection part R11 of the signal wiring part 232a of the positive side wiring 232, the connection part G11 of the signal wiring part 232b, and the signal wiring part 232c through the one-side uncovered hole for LED (described later) formed in the part. Are connected to the connection part B11 (see FIG. 6) by soldering.

  In addition, the LED 236b is the other side non-covering for LED formed at the corresponding portion with respect to the wide portion b of the insulating coating film portion h at each positive side terminal of the light emitting portion R, the light emitting portion G, and the light emitting portion B. Via the hole (described later), to the other side connection part R12 of the signal wiring part 232a of the positive side wiring 232, the connection part G12 of the signal wiring part 232b, and the connection part B12 of the signal wiring part 232c (see FIG. 6). Connected by soldering.

  As shown in FIG. 5, the pair of LEDs 237a and 237b are disposed on the corresponding portion of the independent substrate portion 230e of the flexible printed board 230a with respect to the wide portion d (see FIG. 6) of the independent layer portion 231c from the insulating coating film portion h side. It is mounted so as to be positioned up and down.

  Here, of the pair of LEDs 237a and 237b, the LED 237a corresponds to the wide part d of the insulating coating film part h at the positive terminals of the light emitting part R, the light emitting part G, and the light emitting part B, respectively. The one side connection part R21 of the signal wiring part 233a of the positive side wiring 233, the connection part G21 of the signal wiring part 233b, and the signal wiring part 233c through the one-side uncovered hole for LED (described later) formed in the part. Are connected to the connection part B21 (see FIG. 6) by soldering.

  In addition, the LED 237b is an LED one-side uncovered formed on the corresponding portion of the insulating coating film portion h with respect to the wide portion d at each positive side terminal of the light emitting portion R, the light emitting portion G, and the light emitting portion B. Via the hole (to be described later), the other connection part R21 of the signal wiring part 233a, the connection part G22 of the signal wiring part 233b, and the connection part B22 of the signal wiring part 233c (see FIG. 6) of the positive wiring 233. Connected by soldering.

  Further, the pair of LEDs 238a and 238b are connected to the corresponding portion of the independent substrate portion 230f of the flexible printed board 230a with respect to the wide portion f (see FIG. 6) of the independent layer portion 231d from the insulating coating film portion h side in FIG. It is mounted so as to be positioned up and down as shown.

  Here, of the pair of LEDs 238a and 238b, the LED 238a corresponds to the wide portion f of the insulating coating film portion h at the positive terminals of the light emitting portion R, the light emitting portion G, and the light emitting portion B, respectively. The one side connection part R31 of the signal wiring part 234a of the positive side wiring 234, the connection part G31 of the signal wiring part 234b, and the signal wiring part 234c through the one-side uncovered hole for LED (described later) formed in the part. Are connected to the connection part B31 (see FIG. 6) by soldering.

  In addition, the LED 238b is one-side uncovered for LED formed at a corresponding portion with respect to the wide portion f of the insulating coating film portion h at each positive side terminal of the light emitting portion R, the light emitting portion G, and the light emitting portion B. Via the hole (to be described later), the other side connection part R31 of the signal wiring part 234a, the connection part G32 of the signal wiring part 234b, and the connection part B32 of the signal wiring part 234c (see FIG. 6) of the positive side wiring 234. Connected by soldering.

  Further, each of the light emitting part R, the light emitting part G, and the light emitting part B of the pair of LEDs 236a and 236b is connected to the negative side independent wiring part 235b of the negative side wiring 235 at the negative side terminal thereof. The light emitting part R, the light emitting part G, and the light emitting part B of each of the pair of LEDs 237a and 237b are connected to the negative side independent wiring part 235c of the negative side wiring 235 at the respective negative side terminals. The light emitting portion R, the light emitting portion G, and the light emitting portion B of each of the pair of LEDs 238a, 238b are connected to the negative side wiring 235 at their negative side terminals, respectively, through the wide portion d of the independent layer portion 231c. The negative-side independent wiring portion 235d is solder-connected through the wide portion f of the independent layer portion 231d.

  As a result, each of the pair of LEDs 236a and 236b is connected to the light-emitting portion R, light-emitting portion G, or light-emitting portion B from the light-emitting drive circuit (not shown) through the one-side connector member 239a (described later). A signal voltage is applied between the negative common wiring portion 235a and the negative independent wiring portion 235b of the negative wiring 235, and light is emitted in red, green, or blue.

  In addition, each of the pair of LEDs 237a and 237b includes a light-emitting portion R, a light-emitting portion G, and a light-emitting portion B. A signal voltage is applied between the negative common wiring portion 235a and the negative independent wiring portion 235c of 235, and light is emitted in red, green, or blue.

  Each of the pair of LEDs 238a and 238b includes a light emitting part R, a light emitting part G, or a light emitting part B, and a light emitting part R, a light emitting part G, or a light emitting part B. A signal voltage is applied between the positive-side wiring 234 and the negative-side common wiring portion 235a and the negative-side independent wiring portion 235d of the negative-side wiring 235 through (described later), and light is emitted in red, green, or blue. . In the first embodiment, the three pairs of LEDs 236a, 236b, 237a, 237b and 238a, 238b are driven by the light emission drive circuit so as to emit light independently for each pair.

  Both one-side connector members 239a and 239b are fitted to respective other-side connector members (not shown) connected to respective extending end portions of a plurality of wires extending from an external circuit (not shown). Each connector is electrically configured together with each other-side connector member.

  Here, as shown in FIGS. 8 and 9, the one-side connector member 239a is mounted on the right end portion of the common substrate portion 230c of the flexible printed board 230a from the insulating coating film portion h side. The member 239a is connected to each extension end of each signal wiring portion 232a to 232c of the positive side wiring 232 and each extension end portion of each signal wiring portion 233a to 233c of the positive side wiring 233 at each positive side connector pin. Are electrically connected by soldering through an uncovered hole portion for a connector (described later) formed in a portion corresponding to the right end portion of the common substrate portion 230c of the electric decoration board 230 in the insulating coating film portion h.

  Further, the one-side connector member 239b is mounted from the insulating coating film portion h side on the intermediate portion in the longitudinal direction of the common substrate portion 230c of the electrical decoration board 230, and the one-side connector member 239b is connected to each positive-side connector. Non-covering for connectors formed at the corresponding portions of the insulating coating film portion h with respect to the intermediate portion in the longitudinal direction of the insulating coating film portion h at the extending end portions of the signal wiring portions 234a to 234c of the positive-side wiring 234 by pins. They are connected by soldering through holes (described later).

  Further, both the one-side connector members 239a and 239b are soldered to the common wiring portion a of the negative wiring 235 through the common layer portion 231a at the respective negative connector pins.

  In the first embodiment, among the insulating coating film portion h, each of the side connection portions R11, R12, G11, G12, B11, B12, R21, R22, G21, G22, B21, B22 and R31, R32, G31, Corresponding parts for G32, B31, and B32, the extended end portions (respective connection ends) of the signal wiring portions 231a to 231c and 233a to 233c, and the extended end portions of the signal wiring portions 234a to 234c ( Corresponding portions with respect to each connection end portion are formed as the above-described LED non-covered hole portion and connector non-covered hole portion, respectively.

  Here, a method of mounting and connecting both the one-side connector members 239a and 239b and the above-described three pairs of LEDs 236a, 236b, 237a, 237b and 238a, 238b to the flexible printed board 230a will be described in detail.

  First, the flexible printed circuit board 230a is detachably fixed on a work table of an automatic soldering apparatus (not shown) from the insulating coating film part i side so as to face upward at the insulating coating film part h. At this time, each of the positive-side wirings 232 to 234 is positioned above the flexible electrical insulating layer 231 (see FIG. 6).

  In this state, of the pair of LEDs 236a and 236b, the LED 236a is formed at the corresponding portion of the insulating coating film portion h of the flexible printed board 230a with respect to the independent substrate portion 230d. Are mounted on the connection parts R11, G11 and B11 through the part, and the positive terminals of the light emitting part R, the light emitting part G and the light emitting part B of the LED 236a are connected to the connection parts R11, G11 and B11 by soldering, respectively. .

  Next, the LED 236b is mounted on each connection part R12, G12, and B12 through the other side non-covering hole for LED formed in the part corresponding to the independent board part 230d in the insulating coating film part h of the flexible printed board 230a. At the same time, the positive terminals of the light emitting part R, the light emitting part G, and the light emitting part B of the LED 236b are connected to the respective connection parts R12, G12, and B12 by soldering.

  Thereafter, among the pair of LEDs 237a and 237b, each LED 237a is passed through the one-side uncovered hole portion for LED formed in the corresponding portion of the insulating coating film portion h of the flexible printed board 230a with respect to the independent substrate portion 230e. It mounts on connection part R21, G21, and B21, and each positive side terminal of the light emission part R of the LED237a, the light emission part G, and the light emission part B is connected to each connection part R21, G21, and B21 by soldering, respectively.

  Next, the LED 237b is mounted on each connection part R22, G22, and B22 through the other side non-covering hole for LED formed in the part corresponding to the independent substrate part 230e in the insulating coating film part h of the flexible printed board 230a. At the same time, the positive terminals of the light emitting part R, the light emitting part G, and the light emitting part B of the LED 237b are connected to the connection parts R22, G22, and B22 by soldering.

  Further, among the remaining pair of LEDs 238a, 238b, each LED 238a is passed through the one-side uncovered hole portion for LED formed in the corresponding portion with respect to the independent substrate portion 230f in the insulating coating film portion h of the flexible printed board 230a. It is mounted on the connection parts R31, G31 and B31, and the light emitting part R, the light emitting part G and the light emitting part B of the LED 238a are connected to the connection parts R31, G31 and B31 by soldering, respectively.

  Next, the LED 238b is mounted on each connection part R32, G32, and B32 through the other side non-covering hole for LED formed in the part corresponding to the independent board part 230f in the insulating coating film part h of the flexible printed board 230a. At the same time, the positive terminals of the light emitting part R, the light emitting part G, and the light emitting part B of the LED 238b are connected to the connection parts R32, G32, and B32 by soldering, respectively.

  The above-mentioned soldering connection is performed by automatically holding the LED by the robot hand of the automatic soldering apparatus for each LED, and the positive terminals of the light emitting part R, the light emitting part G, and the light emitting part B of the LED. Is automatically connected to the connection portion corresponding to the LED by solder through the opening of the insulating coating film portion h corresponding to the LED.

  Further, of the one-side connector members 239a and 239b, the one-side connector member 239a corresponds to the extended end portions of the two signal wiring portions 231a to 231c and 233a to 233c of the insulating coating film portion h. Each connector pin of the one-side connector member 239a is connected to each extension end by soldering while being mounted on each extension end through the uncovered hole for connector.

  Next, the one-side connector member 239b is mounted on each extension end through the connector uncovered hole corresponding to the extension end of each of the signal wiring portions 234a to 234c in the insulating coating film portion h. At the same time, the connector pins of the one-side connector member 239b are connected to the extended end portions by soldering.

  Such soldering connection is performed by automatically holding the one-side connector member by the robot hand of the automatic soldering device for each one-side connector member, and connecting each connector pin of the one-side connector member to the relevant one. This is done by automatically connecting the extended ends of the signal wiring portions 234a to 234c corresponding to the one-side connector member by solder through the corresponding openings of the insulating coating film portion h.

  The electric decoration board 230 configured as described above is assembled to the other-side housing member 220 in the left movable effect device 200 in the following manner prior to the configuration of the housing described above.

  First, the electric decoration board 230 is bent so as to have the shape shown in FIG. In other words, each of the strip-like independent substrate portions 230d to 230f of the illumination board 230 includes three pairs of LEDs 236a, 236b, 237a, 237b, and 238a, 238b, respectively. In order to face the front side of the side housing member 220, it is bent so as to form a convex curved shape toward the upper side in FIG. 5 to form the convex curved portions j, k, and m.

  Specifically, as shown in FIG. 5, the convex curved portion j is an extended proximal end portion of the narrow portion a of the independent substrate portion 230 d from the common substrate portion 230 c (a rising portion from the common substrate portion 230 c). ), And the convex curved portion k is a base portion extending from the common substrate portion 230e (from the common substrate portion 230e) in the narrow portion d of the independent substrate portion 230e. The convex curved portion m is formed in a curved shape that protrudes upward from the common substrate portion 230f in the narrow portion e of the independent substrate portion 230f. At the rising portion from the common substrate portion 230f), a curved shape protruding upward is formed. Accordingly, the connector member 239b is positioned on the rear side (insulation coating film portion h side) of the common substrate portion 230c.

  In addition, as described above, the convex curved portions j, k, and m are formed on the independent substrate portions 230d, 230e, and 230f, respectively, so that the bent portions of the three signal wirings 232, 233, and 234 are formed. W1, W2, and W3 each extend from the top to the front of each convex curved portion j, k, and m (see FIG. 5).

  Moreover, the common board | substrate part 230c of the electrical decoration board 230 is bend | folded by the crank shape in the illustration right end part, and comprises the bending insertion part g, as shown in FIG. Accordingly, the connector member 239a is positioned on the opposite side of the band-shaped independent substrate portion 230f with respect to the bending insertion portion g of the common substrate portion 230c.

  Therefore, each of the strip-like independent substrate portions 230d to 230f of the electric decoration board 230 bent in this way is connected to the back surface of the other-side housing member 220 together with the pair of LEDs 236a, 236b, 237a, 237b and 238a, 238b. From the side, the other side housing member 220 is inserted forward through the respective rectangular openings 221 to 223 (see FIG. 4).

  Further, the common board portion 230c of the electric decoration board 230 is attached to the lower part of the other housing member 220 from the back surface side thereof by fastening a plurality of screws with the belt-like back plate 230b via the one side connector member 239b. At this time, as shown in FIG. 4, the one-side connector member 239a is inserted into the opening 225a formed in the bent portion 225 of the other-side housing member 220 and protrudes to the right in the figure, and the bent insertion portion g The opening 224 of the side housing member 220 is inserted from the back side thereof, and is locked to the bent portion 225 of the other side housing member 220 from the front side. Further, the other-side connector member 239b is inserted into a notch 239c (described later) formed in the belt-like back plate 230b and protrudes rearward (see FIG. 3).

  However, in the other-side housing member 220, the rectangular openings 221 to 223 described above are spaced apart from each other in the left-right direction as shown in FIG. Is formed. Moreover, the opening part 224 mentioned above is formed in the lower right side lower part of the other side housing member 220, as shown in FIG. Further, as shown in FIG. 4, the above-described bent portion 225 is bent and formed in an L shape forward from the lower right side lower portion of the other housing member 220 so as to be positioned on the right side of the opening 224 in the drawing.

  The strip-shaped back plate 230b is formed by forming a notch 239c in a U-shape corresponding to the outer shape of the one-side connector member 239b at a portion corresponding to the one-side connector member 239b. The one-side connector member 390b is inserted into the portion 239c as described above.

  As will be described later, the three movable decorative bodies 240a to 240c are connected to the three plate-like guide members 250a to 250c together with the respective band-like independent substrate portions 230d to 230f of the electric decoration board 230, so that these three plate-like guides. The other side housing member 220 is connected to the members 250a to 250c.

  As shown in FIG. 3, FIG. 10 or FIG. 11, the movable decorative body 240a has a lantern 241. The lantern 241 is composed of a semi-cylindrical transparent lantern body 241a and a back plate 241b.

  Here, the back plate 241b is attached to the opening end of the transparent lantern body 241a so as to sandwich the corresponding portion of the band-shaped independent substrate portion 230d of the electrical decoration board 230 with respect to the wide portion b of the independent layer portion 231b together with the transparent lantern body 241a. It is fixed by fastening multiple screws. Thereby, the corresponding | compatible site | part with respect to the wide part b of the independent layer part 231b among the strip | belt-shaped independent board | substrate parts 230d is pinched | interposed between the opening edge part of the transparent lantern main body 241a, and the backplate 241b.

  In addition, the pair of light emitting diodes 236a and 236b is transparent at a portion corresponding to the wide portion b of the independent layer portion 231b in the belt-like independent substrate portion 230d so as to emit light forward through the semi-cylindrical wall portion of the transparent lantern body 241a. The lantern is mounted from the lantern body 241a side and is included in the lantern 241.

  Further, the movable decorative body 240a has a support arm 242. As shown in FIG. 10, the support arm 242 has a base 242a extending rearward from the upper end of the transparent lantern body 241a, and the base. The arm portion 242b extends upward in an L shape from the extending end portion of 242a.

  Thus, the movable decorative body 240a configured as described above is moved up and down together with the strip-shaped independent substrate portion 230d of the electric decoration board 230 in conjunction with the plate-shaped guide member 250a that moves up and down along the other housing member 220 as described later. It comes to move.

  The movable decorative body 240b includes a lantern 241 similar to the movable decorative body 240a and a support arm 243. The lantern 241 of the movable decorative body 240b is disposed between the transparent lantern body 241a and the back plate 241b. While sandwiching a corresponding portion of the independent layer portion 231c with respect to the wide portion d of the strip-like independent substrate portion 230e of the electrical decoration board 230, the pair of LEDs 237a and 237b are included. Here, the pair of LEDs 237a and 237b are independent layer portions of the strip-shaped independent substrate portion 230e from the transparent lantern body 241a side so as to emit light forward through the semi-cylindrical wall portion of the transparent lantern body 241a of the movable decorative body 240b. The lantern 241 is attached to a corresponding portion of the wide portion d of 231c.

  Further, as shown in FIG. 3, the support arm 243 includes a base 243a extending rearward from the upper end of the transparent lantern body 241a of the movable decorative body 240b and an L-shaped upper portion extending from the extended end of the base 243a. It is comprised with the arm part 243b extended to. The extension length of the base portion 243a is longer than the extension length of the base portion 242a, and the extension length of the arm portion 243b is shorter than the extension length of the arm portion 242b.

  Thus, the movable decorative body 240b configured as described above is moved up and down together with the belt-like independent substrate portion 230e of the electric decoration board 230 in conjunction with the plate-like guide member 250b that moves up and down along the other housing member 220, as will be described later. It comes to move.

  The movable decorative body 240c includes a lantern 241 similar to the movable decorative body 240a and a support arm 244. The lantern 241 of the movable decorative body 240b includes a transparent lantern body 241a and a back plate 241b. A portion corresponding to the wide portion f of the independent layer portion 231d is sandwiched between the strip-like substrate portions 230f of the electric decoration board 230, and a pair of LEDs 238a and 238b are included. Here, the pair of LEDs 238a and 238b are independent layer portions of the strip-shaped independent substrate portion 230f from the transparent lantern body 241a side so that light is emitted forward through the semi-cylindrical wall portion of the transparent lantern body 241a of the movable decorative body 240c. The lantern 241 is attached to the corresponding portion of the wide portion f of 231d.

  Further, as shown in FIG. 3, the support arm 244 includes a base 244a extending rearward from the upper end of the transparent lantern body 241a of the movable decorative body 240c, and an L-shaped upper portion extending from the extended end of the base 244a. It is comprised with the arm part 244b extended to. The extension length of the base portion 244a is longer than the extension length of the base portion 242a and shorter than the extension length of the base portion 243a. Further, the extension length of the arm portion 244b is shorter than the extension length of the arm portion 243b.

  Thus, the movable decorative body 240c configured as described above is moved up and down together with the strip-shaped independent substrate portion 230f of the electric decoration board 230 in conjunction with the plate-shaped guide member 250c that moves up and down along the other housing member 220 as described later. It comes to move.

  Of the three plate-like guide members 250a to 250c, the plate-like guide member 250a has a longitudinal plate portion 251 as shown in FIG. 3, and an intermediate portion in the vertical direction on the back surface of the longitudinal plate portion 251. The long U-shaped wall portion 252 is formed along the width direction of the long plate portion 251 and protrudes from the back surface thereof. In addition, a cylindrical projection 253 is formed at the center in the width direction of the long plate portion 251 so as to protrude forward from the long plate portion 251 immediately below the U-shaped wall portion 252.

  The plate-shaped guide member 250 b has a long plate portion 254, and a long ellipse wall portion 255 is formed in the long plate portion 254 at the intermediate portion in the vertical direction on the back surface of the long plate portion 254. It is formed along the width direction of and protrudes from the back side thereof. In addition, a cylindrical protrusion 256 is formed at the center in the width direction of the long plate portion 254 so as to protrude forward from the long plate portion 254 immediately below the long elliptical wall portion 255.

  The plate-shaped guide member 250c has a long plate portion 257, and a long U-shaped wall portion 258 is formed in the long plate in the middle portion of the back surface of the long plate portion 257 in the vertical direction. It is formed along the width direction of the portion 257 and protrudes toward the back side thereof. In addition, a cylindrical projection 259 is formed at the central portion in the width direction of the long plate portion 257 so as to protrude forward from the long plate portion 257 immediately below the U-shaped wall portion 258.

  In the first embodiment, the connection configuration between the three movable decorative bodies 240a to 240c, the three plate-shaped guide members 250a to 250c configured as described above, and the other-side housing member 220 is as follows. .

  The movable decorative body 240a is formed in a female screw hole portion formed coaxially with the cylindrical portion 245a of the stepped boss 245 at a through hole portion 242c (see FIG. 3) formed at the upper end portion of the arm portion 242b of the support arm 242. The other side housing member 220 is fastened by a small screw 242e through the longitudinal guide groove 226. However, the stepped boss 245 is fitted in the longitudinal guide groove portion 226 at the cylindrical portion 245a so as to be movable up and down, and the flange portion 245b of the stepped boss 245 is coaxial with the cylindrical portion 245a. It is formed so as to come into contact with the longitudinal guide groove 226 so as to be movable up and down from the back side.

  The movable decorative body 240a has a female screw hole portion formed coaxially with the cylindrical projection portion 253 of the plate-like guide member 250a at a through-hole portion 242d formed in the longitudinal intermediate portion of the arm portion 242b of the support arm 242. In addition, the other side housing member 220 is fastened by a small screw 242e through a longitudinal guide groove 226 of the other side housing member 220. However, the cylindrical protrusion 253 of the plate-shaped guide member 250 a is movably inserted into the longitudinal guide groove 226 of the other housing member 220.

  Thereby, the movable decorative body 240a holds the independent substrate portion 230d together with the plate-like guide member 250a so as to form the convex curved portion j in the narrow portion a of the independent substrate portion 230d in the flexible printed board 230a as described above. However, it moves up and down along the longitudinal guide groove 226 of the other housing member 220 in conjunction with the vertical movement of the plate-like guide member 250a.

  Here, in the first embodiment, as shown in FIG. 4, the longitudinal guide groove 226 is formed so as to be gently curved in the width direction at the vertical intermediate portion 226 a. Therefore, when the movable decorative body 240a moves up and down, the upper end of the movable decorative body 240a swings the lantern 241 in the horizontal direction shown in FIG. 4 with reference to the cylindrical protrusion 253 of the plate-like guide member 250a. Tilt to.

  The movable decorative body 240b has a through hole 243c formed in the upper end portion of the arm portion 243b of the support arm 243, and a female screw hole portion formed coaxially with the cylindrical portion 246a of the stepped boss 246. Are tightened with a small screw 243e through the longitudinal guide groove 227. However, the stepped boss 246 is fitted in the longitudinal guide groove portion 227 at its cylindrical portion 246a so as to be movable up and down, and the flange portion 246b of the stepped boss 246 is coaxial with the cylindrical portion 246a. It is formed so as to come into contact with the longitudinal guide groove 227 so as to be movable up and down from the back side.

  The movable decorative body 240b has a female screw hole portion formed coaxially with the cylindrical projection portion 256 of the plate-like guide member 250b at a through-hole portion 243d formed in the longitudinal intermediate portion of the arm portion 243b of the support arm 243. Further, the other side housing member 220 is fastened by a small screw 243f via the longitudinal guide groove portion 227. However, the cylindrical projection 256 of the plate-like guide member 250b is movably inserted into the longitudinal guide groove 227 of the other housing member 220.

  Accordingly, the movable decorative body 240b holds the independent substrate portion 230e together with the plate-like guide member 250b so as to form the convex curved portion k in the narrow portion c of the independent substrate portion 230e in the flexible printed circuit board 230a as described above. However, it moves vertically along the longitudinal guide groove 227 of the other housing member 220 in conjunction with the vertical movement of the plate-like guide member 250b.

  Here, in the first embodiment, as shown in FIG. 4, the longitudinal guide groove portion 227 is formed so as to be gently curved in the width direction at an intermediate portion 227 a in the vertical direction. Therefore, when the movable decorative body 240b moves up and down, the upper end of the movable decorative body 240b swings the lantern 241 in the horizontal direction shown in FIG. 4 with reference to the cylindrical protrusion 256 of the plate-like guide member 250b. Tilt to.

  Further, the movable decorative body 240c has a through-hole portion 242a formed at the upper end portion of the arm portion 244b of the support arm 244, and a female screw hole portion formed coaxially with the cylindrical portion 247a of the stepped boss 247 on the other side. The housing member 220 is fastened by a small screw 244e via a longitudinal guide groove 228 of the housing member 220. However, the stepped boss 247 is fitted in the longitudinal guide groove portion 228 so that the stepped boss 247 can move up and down, and the flange portion 247b of the stepped boss 247 is coaxial with the tube portion 247a. It is formed so as to come into contact with the longitudinal guide groove 228 so as to be movable up and down from the back side.

  The movable decorative body 240c has a female screw hole formed coaxially with the cylindrical projection 259 of the plate-like guide member 250c at a through-hole 244d formed in the longitudinal intermediate portion of the arm 244a of the support arm 244. The other side housing member 220 is fastened with a small screw 244f via a longitudinal guide groove 228 of the other side housing member 220. However, the cylindrical projection 259 of the plate-shaped guide member 250c is movably inserted into the longitudinal guide groove 228 of the other housing member 220.

  Thereby, the movable decorative body 240c holds the independent substrate portion 230f together with the plate-shaped guide member 250c so as to form the convex curved portion m in the narrow portion e of the independent substrate portion 230f in the flexible printed board 230a as described above. However, it moves up and down in conjunction with the vertical movement of the plate-shaped guide member 250b via the longitudinal guide groove portion 228 of the other housing member 220.

  Here, in the first embodiment, as shown in FIG. 4, the longitudinal guide groove 228 is formed so as to be gently zigzag curved in the width direction at the upper portion 228a in the longitudinal direction. Therefore, when the movable decorative body 240c moves up and down, the upper end of the movable decorative body 240c swings the lantern 241 in the horizontal direction shown in FIG. 4 with reference to the cylindrical protrusion 259 of the plate-like guide member 250c. Tilt to.

  The three gear members 260a to 260c are arranged between the three plate-like guide members 250a to 250c and the one-side housing member 210, and the common board portion 230c and the strip-like back plate 230b of the electric decoration board 230 and the three plate-like guides. Along with the members 250a to 250c, they are disposed in the housing.

  Of the three gear members 260a to 260c, the gear member 260a protrudes forward from the front surface (surface on the plate-shaped guide member 250a side) of the spur gear portion 261 and a radial intermediate portion of the spur gear portion 261. It is comprised by the cylindrical projection part 262 to do.

  The gear member 260b includes a spur gear portion 263, a columnar projection portion 264 that protrudes forward from the front surface (surface on the plate-like guide member 250b side) of the spur gear portion 263 in the radial direction, and a spur gear portion. It is comprised by the annular wall part 265 extended coaxially from the H.263 to the back surface side.

  The gear member 260c includes a spur gear portion 266 and a columnar protrusion portion 267 that protrudes forward from a front surface (a surface on the plate-like guide member 250c side) of the spur gear portion 266 in a radial intermediate portion. Has been.

  In the three gear members 260a to 260c configured as described above, the gear member 260a is rotatably supported by the spur gear portion 261 in the through hole portion 211 of the bottom wall 210a of the one-side housing member 210. The rotary shaft 212 is coaxially supported so as to mesh with the spur gear portion 263 of the gear member 260b, and the columnar protrusion 262 of the gear member 260a is a longitudinal U-shape of the plate-shaped guide member 250a. The wall portion 252 is engaged so as to be relatively slidable.

  Thus, when the gear member 260a rotates, the cylindrical protrusion 262 rotates around the axis of the spur gear portion 261 as the gear member 260a rotates. For this reason, the plate-like guide member 250a is slid by being pushed along the inner surface of the U-shaped wall portion 252 as the cylindrical projection portion 262 rotates. Accordingly, the plate-shaped guide member 250a moves down along with the movable housing 240a along the other housing member 220 in accordance with the half rotation of the protrusion 262 from the position shown in FIG. 3, and the protrusion It moves up according to the remaining half rotation of 262. In other words, the electric decoration board 230 moves downward or upward along with the pair of LEDs 236a and 236b while forming the convex curved portion j in accordance with the downward or upward movement of the movable decorative body 240a in the belt-like independent substrate portion 230d. To do.

  The gear member 260b meshes with the spur gear portion 266 of the gear member 260c by the rotation shaft 214 rotatably supported by the through-hole portion 213 of the bottom wall 210a of the one-side housing member 210 at the spur gear portion 263. The columnar projection 264 of the gear member 260b is engaged with the long oval wall 255 of the plate-like guide member 250b so as to be relatively slidable.

  Further, the annular wall portion 265 of the gear member 260b is concentrically and rotatably fitted in a concave annular portion 215 formed on the bottom wall 210a of the one-side housing member 210 around the axis of the through-hole portion 213. Has been. In the present embodiment, the concave annular portion 215 is formed in the bottom wall 210a of the one-side housing member 210 in a concave shape with a predetermined depth from the front surface side with the through-hole portion 213 as the center. However, the concave annular portion 215 is smaller in inner diameter than the inner diameter of the annular wall portion 265 of the gear member 260b, and the outer diameter of the concave annular portion 215 is larger than the outer diameter of the annular wall portion 265. Largely formed.

  Thus, when the gear member 260b rotates, the cylindrical protrusion 264 rotates around the axis of the spur gear portion 263 with the rotation of the gear member 260b. For this reason, the plate-shaped guide member 250b is pushed and slid along the inner surface of the longitudinal elliptical wall portion 255 along with the rotation of the columnar projection portion 264. Thereby, the plate-shaped guide member 250b moves down along with the movable housing 240b along the other housing member 220 in accordance with the half rotation of the protrusion 264 from the position shown in FIG. 3, and the protrusion It moves up in response to the remaining half rotation of H.264. In other words, the electric decoration board 230 moves downward or upward together with the pair of LEDs 237a and 237b while forming the convex curved portion k in accordance with the downward or upward movement of the movable decorative body 240b in the belt-like independent substrate portion 230e. To do.

  The gear member 260c is coaxially supported by an output shaft 272 (described later) of the step motor 270 through an opening 216 formed in the bottom wall 210a of the one-side housing member 210 at the spur gear portion 266. The cylindrical protrusion 267 of the gear member 260c is engaged with the longitudinal U-shaped wall 258 of the plate-shaped guide member 250c so as to be slidable relative to each other.

  Thus, when the gear member 260c rotates, the cylindrical protrusion 267 rotates around the axis of the spur gear portion 267 as the gear member 260c rotates. For this reason, the plate-shaped guide member 250c is slid by being pushed along the inner surface of the U-shaped wall portion 258 as the cylindrical projection portion 267 rotates. Accordingly, the plate-shaped guide member 250c moves down along with the movable housing 240c along the other housing member 220 in accordance with the half rotation of the protrusion 267 from the position shown in FIG. 3, and the protrusion It moves up according to the remaining half rotation of 267. In other words, the electric decoration board 230 moves downward or upward together with the pair of LEDs 238a and 238b while forming the convex curved portion m in accordance with the downward or upward movement of the movable decorative body 240c at the belt-like independent substrate portion 230f. To do.

  The step motor 270 is attached to the bottom wall 210a of the one-side housing member 210 coaxially with the opening 216 from the back side thereof in the motor main body 271, and the output shaft 272 of the step motor 270 has the opening 216. The spur gear portion 267 is coaxially supported.

  When the step motor 270 rotates, the spur gear portion 266 of the gear member 260c rotates in the same direction as the step motor 270, and the spur gear portion 263 of the gear member 260b rotates in the opposite direction to the step motor 270. The spur gear portion 261 of the gear member 260 a rotates in the same direction as the step motor 270.

  However, in the first embodiment, the projection 262 of the gear member 260a, the projection 264 of the gear member 260b, and the projection 267 of the gear member 260c are respectively the spur gear portions 261 and 263 as shown in FIG. The rotational angle positions of the spur gear portions 261, 263, and 266 when positioned immediately above the shaft centers of the spur gear portions 266, 266 are set to the initial rotational angle positions of the spur gear portions 261, 263, and 266, respectively. In the present embodiment, the rotation of the step motor 270 is controlled by a control circuit (not shown).

  The step motor 270 and the gear members 260a to 260c, the guide members 250a to 250c, and the cylindrical bosses 245 to 247 correspond to the drive mechanism in the movable effect device.

  The initial rotation angle position sensor 280 detects the initial rotation angle position of the spur gear portion 263 of the gear member 260b. The initial rotation angle position sensor 280 is a U-shaped photo interrupter 280a as shown in FIG. And a support member 280b, and is assembled from the back side of the bottom wall 210a to a T-shaped opening 217 formed in the bottom wall 210a of the one-side housing member 210.

  Here, the T-shaped opening 217 is formed in the bottom wall 210a so as to have a leg corresponding to the photo interrupter 280a and a head corresponding to the support member 280b in a T shape. Further, in the leg portion of the T-shaped opening 217, the top of the inner peripheral side disk portion 215 a of the concave annular portion 215 is arranged so as to correspond to the corresponding portion of the photo interrupter 280 a with respect to the light receiving portion 282 (described later). A U-shaped recess 215b is formed. In addition, the inner peripheral disc part 215a is formed on the inner peripheral side of the concave annular part 15 by hollowing out the concave annular part 215 on the bottom wall 210a.

  As shown in FIG. 3, the U-shaped photointerrupter 280a is formed by connecting a light emitting unit 281 and a light receiving unit 281 in parallel with each other by a connecting unit 283, and this photointerrupter 280a has a U-shaped photodetecting unit 282. It is fitted to the leg portion of the T-shaped opening 217 so as to be fitted into the recess 215b. Here, the gap between the light emitting portion 281 and the light receiving portion 282 matches the distance between the inner peripheral surface and the outer peripheral surface of the concave annular portion 215. The light emitting unit 281 and the light receiving unit 282 are opposed to each other through a slit 265a formed at the top of the annular wall 265 of the gear member 260b.

  The support member 280b is formed in an L-shaped plate shape with the bottom wall portion 284 and the rear wall portion 285. The support member 280b is fitted to the head of the T-shaped opening 217 together with the flange portion 281a of the light emitting portion 281 at the bottom wall portion 284, and the rear wall portion 285 of the support member 280b is The bottom wall 210a of the one-side housing member 210 is fastened by a plurality of screws on the left and right sides of the T-shaped opening 217 from the back side. Further, the bottom wall portion 284 of the support member 280b is fastened to the both flange portions extending from the light emitting portion 281 of the photo interrupter 280a to the left and right sides by a plurality of screws from above.

  According to the initial rotation angle position sensor 280 configured as described above, the slit 265a of the annular wall 265 reaches between the light emitting unit 281 and the light receiving unit 282 of the photo interrupter 280a as the gear member 260b rotates. When the light receiving unit 282 receives the emitted light from the light emitting unit 281, the photo interrupter 280 a detects the initial rotation angle position of the gear member 260 b based on the light received by the light receiving unit 282. This means that the initial rotation angle position sensor 280 detects the initial rotation angle position of the spur gear portion 263 of the gear member 260b. Note that the photo interrupter 280a is driven to emit light by a light emission driving circuit (not shown) in the light emitting unit 281.

  Further, as shown in FIG. 3, the left-side movable effect device 200 includes a circuit board 290a and a transparent decorative plate 290b. The transparent decorative plate 290b, together with the circuit board 290a, is disposed on the front side of the other housing member 220. To the movable decorative bodies 240a to 240c through the support arms 242b, 243b, and 244b, and are fastened in a laminated manner by a plurality of screws.

  Thereby, the emitted light of the plurality of LEDs 291 provided on the circuit board 290a is emitted forward through the decorative plate 290b. The right movable effect device 200 is configured in the same manner as the left movable effect device 200. As shown in FIG. 2, the right movable effect device 200 includes three movable decorative bodies 240a to 240c immediately below the right side portion of the mountain-shaped decorative accessory 31. The game board 10 is provided on the back surface side so as to move up and down along the front surface of the display panel 111.

  In the first embodiment configured as described above, the operation of the left and right movable effect device 200 will be described by taking the left movable effect device 200 as an example. At this stage, it is assumed that the movable decorative body 240a is positioned at the upper moving end as shown in FIGS. 11 to 13 and 20A.

  At this time, the remaining movable decorative bodies 240b and 240c are in the positions shown in any of FIGS. 11 to 13, respectively, and the three independent substrate portions 230d to 230f of the electrical decoration board 230 are shown in FIG. As shown, each of the corresponding narrow portions a, c and e is curved so as to form curved portions j, k and m that are convex upward.

  In such a state, the other side connector members connected to the extended ends of the plurality of wirings extending from the external circuit are fitted and electrically connected to the one side connector members 239a and 239b. Then, a voltage is applied between the positive side wirings 232 to 234 and the negative side wiring 235 of the illumination board 230 from the external circuit. Along with this, each predetermined signal is applied to each positive-side wiring 232 to 234 of the electrical decoration board 230. Then, the three pairs of LEDs 236a, 236b, 237a, 237b and 238a, 238b are driven to emit light by the above-described light emission drive circuit at different timings for each pair. Therefore, the three pairs of LEDs 236a, 236b, 237a, 237b and 238a, 238b emit light in full color through the lantern main bodies 241a of the three movable decorative bodies 240a, 240b, and 240c at different timings for each pair.

  Thus, when the step motor 270 is driven by a motor drive circuit (not shown) and rotates in the counterclockwise direction shown in FIG. 12 or 13 (the clockwise direction shown in FIG. 3), the gear member 260c is moved to the step motor. Rotate in the same direction as 270. In other words, the spur gear portion 266 rotates in the same direction as the step motor 270, and the protrusion 267 rotates around the axis of the spur gear portion 266 in the same direction as the step motor 270.

  As described above, when the gear member 260c rotates in the same direction as the step motor 270, the plate-shaped guide member 250c is moved under the relative sliding movement between the projection 267 on the inner surface of the U-shaped wall portion 258. The protrusion 267 is pushed upward and moves upward along the longitudinal guide groove 228 (see FIG. 11) of the one-side housing member 220.

  Then, the movable decorative body 240c is pushed upward along the longitudinal guide groove 228 by the cylindrical projection 259 in accordance with the upward movement of the plate-shaped guide member 250c (see FIGS. 14 and 17). ).

  Here, as described above, the arm portion 244b of the movable decorative body 240c is connected to the stepped boss 247 at the upper end portion thereof, and the guide groove portion 228 is gently extended in the width direction at the longitudinal upper portion 228a. It is curved in a zigzag shape.

  For this reason, the movable decorative body 240c tilts in the left-right direction with respect to the cylindrical protrusion 259 of the plate-shaped guide member 250c at the upper end of the arm 244b, and the lantern 241 is moved from the pair of LEDs 238a and 238b. It moves upward along the longitudinal guide groove 228 while swinging in the left-right direction under full color light emission. At this time, along with the upward movement of the movable decorative body 240c, the band-like independent substrate portion 230f of the electrical decoration board 230 moves the convex curved portion m upward (see FIGS. 15, 16, 18, and 19).

  When the spur gear portion 266 rotates in the same direction as the step motor 270 as described above, the spur gear portion 263 of the gear member 260b is engaged with the spur gear portion 266 to Rotate in the opposite direction. This means that the gear member 260b rotates in the opposite direction to the spur gear portion 266. Accordingly, the protrusion 264 rotates around the axis of the spur gear 263 and rotates in the opposite direction to the spur gear 266.

  Thus, when the gear member 260b rotates in the direction opposite to the spur gear portion 266 (counterclockwise as shown in FIG. 3), the plate-shaped guide member 250b contacts the protrusion 264 on the inner surface of the oblong wall 255. Under the relative sliding, the projection 264 pushes upward and moves upward along the longitudinal guide groove 227 (see FIG. 14) of the one-side housing member 220.

  Then, the movable decorative body 240b is pushed upward along the longitudinal guide groove 227 by the cylindrical projection 256 in accordance with the upward movement of the plate-shaped guide member 250b (see FIGS. 14 and 17). ). Here, the arm portion 243b of the movable decorative body 240b is connected to the stepped boss 246 at the upper end portion thereof as described above, and the guide groove portion 227 is gently extended in the width direction at the upper portion 227a in the longitudinal direction. It is curved in a zigzag shape.

  For this reason, the movable decorative body 240b tilts in the left-right direction with respect to the cylindrical protrusion 256 of the plate-like guide member 250b at the upper end of the arm 243b, and makes the lantern 241 full color from the pair of LEDs 237a and 237b. Under the light emission, it moves upward along the longitudinal guide groove portion 227 while swinging in the left-right direction (see FIGS. 14 and 17). At this time, along with the upward movement of the movable decorative body 240b, the band-shaped independent substrate portion 230e of the electrical decoration board 230 moves the convex curved portion k upward (see FIGS. 15, 16, 18, and 19).

  When the spur gear portion 263 rotates in the direction opposite to the spur gear portion 266 as described above, the spur gear portion 261 of the gear member 260 a is engaged with the spur gear portion 263. Rotates in the opposite direction (clockwise in FIG. 3). This means that the gear member 260a rotates in the opposite direction to the spur gear portion 263. Accordingly, the protrusion 262 rotates around the axis of the spur gear 261 and rotates in the opposite direction to the spur gear 263 (clockwise shown in FIG. 3).

  Thus, when the gear member 260a rotates in the opposite direction to the spur gear portion 263, the plate-like guide member 250a is moved under the relative sliding movement with the projection 262 on the inner surface of the long U-shaped wall portion 252. It is pushed downward by the protrusion 262 and moves downward along the longitudinal guide groove 226 of the one-side housing member 220 (see FIGS. 14, 17 and 20B and 20C).

  Then, the movable decorative body 240a is pushed downward along the longitudinal guide groove 226 by the cylindrical projection 253 in accordance with the downward movement of the plate-like guide member 250a (see FIGS. 14, 17 and 17). (Refer FIG.20 (b) (c)). Here, as described above, the arm portion 242b of the movable decorative body 240a is connected to the stepped boss 245 at the upper end portion thereof, and the guide groove portion 226 is gently extended in the width direction at the longitudinal upper portion 226a. It is curved in a zigzag shape.

  Therefore, the movable decorative body 240a tilts in the left-right direction with respect to the cylindrical protrusion 253 of the plate-like guide member 250a at the upper end portion of the arm portion 242b, and the lantern 241 is moved from the pair of LEDs 236a and 236b. Under full-color light emission, it moves downward along the longitudinal guide groove 226 while swinging in the left-right direction (see FIGS. 20B and 20C). At this time, along with the downward movement of the movable decorative body 240a, the strip-shaped independent substrate portion 230d of the electrical decoration board 230 moves the convex curved portion j downward (see FIGS. 15, 16, 18, and 19).

  Under the above-described operation, in the flexible printed circuit board 230a of the electric decoration board 230, after both the movable decorative bodies 240c and 240b sequentially reach the upper moving end and the movable decorative body 240a reaches the lower moving end, Conversely, the band-shaped independent substrate portion 230d moves the convex curved portion j upward, the band-shaped independent substrate portion 230e moves the convex curved portion k downward, and the band-shaped independent substrate portion 230f moves to the convex curved portion. Move m down. Thereafter, in the flexible printed circuit board 230a of the illumination board 230, the operation of each of the belt-like independent circuit board portions 230d, 230e, and 230f is repeated. In the present embodiment, the upward movement (or downward movement) of each bending portion j, k, m is such that each bending portion j, k, m is displaced upward (or downward) at the top. To bend.

  As described above, according to the first embodiment, in the electrical decoration board 230, the common board portion 230c supported by the game board Ba via the housing composed of the housing members 210 and 220 on one side and the other side, A plurality of strip-like independent substrate portions 230d to 230f formed integrally with the common substrate portion 230c and independently extending from the common substrate portion are formed by a single flexible printed circuit board 230a. Yes.

  For this reason, the plurality of substrates that have been conventionally required in the movable effect device need only be a single flexible printed circuit board 230a. As a result, the number of substrates in the movable effect device and the assembly work man-hours of the movable effect device are reduced. Can be made.

  Furthermore, the flexible printed circuit board 230a is configured to include a flexible electrical insulating layer 231, a plurality of positive-side wirings 232 to 234, and a negative-side wiring 235, and the flexible electrical insulating layer 231 is configured to include the flexible printed circuit board 230a. The common layer portion 231a included in the common substrate portion 230c and the common layer portion 231a included in each of the plurality of strip-like independent substrate portions 230d to 230f are integrally formed and independent from the common layer portion. And each of the strip-like independent layer portions 231b to 231d extending in parallel.

  In addition, the plurality of positive-side wirings 232 to 234 are formed as a plurality of signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234c, which are parallel to each other, parallel to each other along the surface of the flexible electrical insulating layer 231. It is formed from the portion 231a to the plurality of band-like independent layer portions 231b to 231d and is included in the flexible printed board 230a.

  On the other hand, the negative side wiring 235 is included in each of the negative side common wiring part 235a included in the common board part 230c of the flexible printed board 230a and the plurality of independent board parts 230d to 230f of the flexible printed board 230a. Each of the plurality of strip-like independent layer portions 231b to 231d of the electrical insulating layer 231 is constituted by the negative side independent wiring portions 235b to 235d formed from the back side thereof.

  Further, three pairs of LEDs 236a, 236b, 237a, 237b and 238a, 238b are mounted on each of the plurality of strip-like independent substrate portions 230d to 230f from the surface side of the flexible electrical insulating layer 231 for each pair. The plurality of light emitting portions R, light emitting portions G, and light emitting portions B of each of the three pairs of LEDs 236a, 236b, 237a, 237b, and 238a, 238b have a plurality of signal wiring portions 232a to 232c, 233a at their one-side terminals. To 233c and 234a to 234c, and connected to the negative-side independent wiring portions 235b to 235d via the plurality of strip-like independent layer portions 231b to 231d at their other terminals.

  For this reason, it is possible to reduce the number of connecting parts such as wiring and connectors for light emission of the three pairs of LEDs 236a, 236b, 237a, 237b and 238a, 238b in the movable rendering device, and the assembly work man-hour of the movable rendering device. .

  In addition, as described above, the flexible printed circuit board 230a includes a plurality of corresponding signal wiring portions from the intermediate portions in the longitudinal direction of the negative side independent wiring portions 235b to 235d, respectively, in the plurality of strip-like independent substrate portions 230d to 230f. Each of the plurality of movable decorative bodies 240a to 240c and the housing are supported so as to have a curved shape that is convex toward the intermediate portion in the longitudinal direction of 232a to 232c, 233a to 233c, and 234a to 234c.

  In addition, the plurality of movable decorative bodies 240a to 240c are respectively supported on the front end sides of the plurality of strip-like independent substrate portions 230d to 230f, and are driven by the driving mechanism, and the plurality of signal wiring portions 232a. ˜232c, 233a˜233c and 234a˜234c are moved independently while being displaced in the bending direction of each longitudinal intermediate portion or in the opposite direction.

  Thereby, when the flexible printed circuit board 230a is displaced as described above by the plurality of strip-like independent substrate portions 230c to 230e, the plurality of signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234c are separated from each other by the plurality of negative side independent portions. The individual substrate portions 230d to 230f are displaced in a curved shape as described above in a state where they are positioned outside the wiring portions 235b to 235d. Thereafter, the curved displacement of each of the independent substrate portions 230d to 230f is repeated.

  In such a repeating process, the load due to the above-described curved displacement of the plurality of band-like independent substrate portions 230c to 230e is more than the plurality of negative-side independent wiring portions 235b to 235d. 233c and 234a to 234c act smaller. Accordingly, the plurality of signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234c do not cause a conduction failure such as disconnection at the longitudinally curved portion.

  As a result, the effects of reducing the number of component parts such as a substrate in the movable effect device as described above, the number of connection parts such as wiring for light emission of each LED, and the assembly work man-hour of the movable effect device are plural. This can be achieved while preventing the occurrence of poor conduction such as disconnection of the signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234c.

  Here, as described above, in the process in which the independent substrate portions 230d to 230f repeat the curved displacement, the independent substrate portions 230d to 230f repeat at the corresponding convex curved portions m, k, and j. It will be displaced to move up and down.

  However, the respective signal wirings 232 to 234 are formed so as to bend the corresponding bent portions W1, W2, and W3 into trapezoidal shapes as described above at the corresponding convex curved portions m, k, and j, respectively. Yes.

  For this reason, each bending part W1, W2, and W3 will be formed in each corresponding convex curved part m, k, and j so that it may spread in the width direction. Therefore, when the individual substrate portions 230d to 230f are displaced so as to repeatedly move up and down at their corresponding convex curved portions m, k, and j as described above, the convex curved portions m, The strain stresses caused by the curved deformations of k and j act as loads on the respective bent portions W1, W2 and W3 over the entirety thereof.

  As a result, the load acting on the corresponding bent portions W1, W2, and W3 in each of the signal wirings 232 to 234 is significantly reduced as compared with the case where each of the signal wirings 232 to 234 is simply formed in a straight line. The Rukoto. Therefore, even if each independent board | substrate part 230d-230f repeats curved displacement as mentioned above, the elastic fatigue of each corresponding bending part W1, W2, and W3 can be reduced favorably. As a result, each of the signal wirings 232 to 234 can maintain a function as a wiring satisfactorily without causing a conduction failure such as disconnection at each of the bent portions W1, W2, and W3.

  Further, as described above, the width of each of the plurality of signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234c is three times that of the conventional one, and the plurality of negative side independent wiring portions 235b to 235d are also included. , Having a wider width than before.

  For this reason, the plurality of strip-like independent board portions 230d to 230f of the flexible printed board 230a are respectively connected to the plurality of positive side signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234c from the negative side independent wiring portions 235b to 235d. The negative-side independent wiring portions are positioned inside the corresponding positive-side independent wiring portions 232a to 232c, 233a to 233c, and 234a to 234c. Even if repeatedly displaced, each of the plurality of signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234c and each of the negative side independent wiring portions 235b to 235d do not further cause a conduction failure such as disconnection. The above-described effects can be achieved.

  Also, if any of the plurality of negative-side independent wiring portions 235b to 235d is disconnected, a pair of LEDs mounted on the strip-shaped independent substrate portion 230c, 230d, or 230e corresponding to the negative-side independent wiring portion related to the disconnection is obtained. Cannot emit light. On the other hand, if any one of the signal wiring portions 232a to 232c, 233a to 233c, or 234a to 234c is disconnected, if the remaining signal wiring portions are normal, the remaining The light emission operation of the LED having the light emitting portion connected to the signal wiring portion can be normally maintained. Therefore, the degree of influence on the light emission of the LED due to the disconnection of the signal wiring portion is lighter than the degree of influence on the light emission of the LED due to the disconnection of the negative side independent wiring portion.

  In addition, as described above, the three pairs of LEDs 236a, 236b, 237a, 237b and 238a, 238b and the one-side connector members 239a, 239b are both flexible printed circuit boards on the work table by the automatic soldering device. 230a is mounted and connected from the insulating coating portion h side. This means that each LED and each one-side connector member are mounted and connected on the same surface side to the flexible printed circuit board 230a on the work table by the automatic soldering apparatus.

In other words, each LED and each one-side connector member are automatically mounted on the flexible printed board 230a by the automatic soldering apparatus without turning the flexible printed board 230a on the workbench. Will be connected. Therefore, in mounting and connecting each LED and each one-side connector member to the flexible printed circuit board 230a, each LED and each one-side connector member are mounted and connected separately on both surfaces of the flexible printed circuit board 230a. Compared to the case, work man-hours can be reduced.
(Second Embodiment)
21 and 22 show the main part of the second embodiment of the present invention. In the second embodiment, the flexible printed circuit board 230a described in the first embodiment is changed as follows.

  That is, in the independent substrate portion 230d described in the first embodiment, the positive-side wiring 232 has a bent portion Wa instead of the bent portion W1, and the bent portion Wa is an independent substrate. As shown in FIG. 21, the convex curved portion j (see FIG. 5) of the narrow portion a of the portion 230d is formed so as to be bent in an inclined manner from the right side to the left side in the drawing.

  Further, in the independent substrate portion 230e described in the first embodiment, the positive wiring 233 has a bent portion Wb instead of the bent portion W2, and the bent portion Wb is an independent substrate. The convex curved part k (see FIG. 5) of the narrow part c of the part 230e is formed so as to be bent downwardly from the left side to the right side as shown in FIG.

  Further, in the independent substrate portion 230f described in the first embodiment, the positive wiring 234 has a bent portion Wb instead of the bent portion W3, and the bent portion Wb is an independent substrate. In the convex curved portion m (see FIG. 5) of the narrow portion e of the portion 230f, as shown in FIG. 22, it is formed so as to be bent in an inclined manner from the left side to the right side in the drawing. Other configurations are the same as those in the first embodiment.

  In the second embodiment configured as described above, as in the first embodiment, in the process in which each of the independent board portions 230d to 230f of the flexible printed board 230a repeats a curved displacement, each of the independent boards. The portions 230d to 230f are displaced so as to repeatedly move up and down at the corresponding convex curved portions m, k, and j.

  However, each of the signal wirings 232 to 234 bends the corresponding bent portion Wa and the corresponding bent portion Wb downward in an inclined manner at the corresponding convex curved portions m, k, and j, respectively, as described above. It is formed as follows.

  For this reason, the bent portion Wa and each bent portion Wb are formed so as to spread in the respective width directions in the corresponding convex curved portions m, k, and j, respectively. Therefore, when the individual substrate portions 230d to 230f are displaced so as to repeatedly move up and down at their corresponding convex curved portions m, k, and j as described above, the convex curved portions m, The strain stresses due to the curved deformations of k and j act as loads on the entire bent portions Wa and the respective bent portions Wb, respectively.

Thereby, in each signal wiring 232-234, the load which acts on each corresponding bending part Wa and each bending part Wb is significantly compared with the case where each said signal wiring 232-234 is each formed in the shape of a straight line each. Will be alleviated. Therefore, even if each independent board | substrate part 230d-230f repeats a curved displacement as mentioned above, the elastic fatigue of the corresponding bending part Wa and each corresponding bending part Wb can be reduced favorably. As a result, each of the signal wirings 232 to 234 can maintain the function as a wiring satisfactorily without causing a conduction failure such as disconnection in the bent portions Wa and the respective bent portions Wb. Other functions and effects are the same as those of the first embodiment.
(Third embodiment)
23 and 24 show the main part of the third embodiment of the present invention. In the third embodiment, the flexible printed board 230a described in the first embodiment is changed as follows.

  That is, in the independent substrate portion 230d described in the first embodiment, the positive-side wiring 232 has a bent portion Wc instead of the bent portion W1, and the bent portion Wc is an independent substrate. As shown in FIG. 23, the convex curved portion j (see FIG. 5) of the narrow portion a of the portion 230d is formed to be bent in a V shape toward the left side in the drawing.

  In the independent substrate portion 230e described in the first embodiment, the positive wiring 233 has a bent portion Wd instead of the bent portion W2, and the bent portion Wd is an independent substrate. The convex curved portion k (see FIG. 5) of the narrow portion c of the portion 230e is formed so as to be bent in a V shape toward the right side of the drawing as shown in FIG.

  In the independent substrate portion 230f described in the first embodiment, the positive wiring 234 has a bent portion Wd instead of the bent portion W3. The bent portion Wd is an independent substrate. The convex curved portion m (see FIG. 5) of the narrow portion e of the portion 230f is formed so as to be bent in a V shape toward the right side of the drawing as shown in FIG. Other configurations are the same as those in the first embodiment.

  In the third embodiment configured as described above, as in the first embodiment, in the process in which each independent board portion 230d to 230f of the flexible printed board 230a repeats a curved displacement, each independent board The portions 230d to 230f are displaced so as to repeatedly move up and down at the corresponding convex curved portions m, k, and j.

  However, the signal wirings 232 to 234 are formed so as to bend the corresponding bent portions Wc and the respective bent portions Wd into V-shapes as described above at the corresponding convex curved portions m, k, and j, respectively. Has been.

  For this reason, the bent portion Wc and each bent portion Wd are formed so as to spread in the respective width directions in the corresponding convex curved portions m, k, and j, respectively. Therefore, when the individual substrate portions 230d to 230f are displaced so as to repeatedly move up and down at their corresponding convex curved portions m, k, and j as described above, the convex curved portions m, The strain stresses due to the curved deformations of k and j act as loads on the entire bent portions Wc and the respective bent portions Wd, respectively.

Thereby, in each signal wiring 232-234, the load which acts on each corresponding bending part Wc and each bending part Wd is significantly compared with the case where each said signal wiring 232-234 is each formed in the shape of a straight line, respectively. Will be alleviated. Therefore, even if each independent board | substrate part 230d-230f repeats curved displacement as mentioned above, the elastic fatigue of the corresponding bending part Wc and each corresponding bending part Wd can be reduced favorably. As a result, each of the signal wirings 232 to 234 can maintain the function as a wiring satisfactorily without causing a conduction failure such as disconnection in the bent portion Wc and each bent portion Wd. Other functions and effects are the same as those of the first embodiment.
(Fourth embodiment)
25 and 26 show the main part of the third embodiment of the present invention. In the fourth embodiment, the flexible printed circuit board 230a described in the first embodiment is changed as follows.

  In other words, in the independent substrate portion 230d described in the first embodiment, the positive-side wiring 232 has a bent portion We instead of the bent portion W1, and the bent portion We has an independent substrate. The convex curved portion j (see FIG. 5) of the narrow portion a of the portion 230d is formed to be bent in a W shape toward the left side of the drawing as shown in FIG.

  In the independent substrate portion 230e described in the first embodiment, the positive wiring 233 has a bent portion Wf instead of the bent portion W2, and the bent portion Wf is an independent substrate. The convex curved portion k (see FIG. 5) of the narrow portion c of the portion 230e is formed so as to be bent in a W shape toward the right side of the drawing as shown in FIG.

  Further, in the independent substrate portion 230f described in the first embodiment, the positive-side wiring 234 has a bent portion Wf instead of the bent portion W3, and the bent portion Wf is an independent substrate. The convex curved portion m (see FIG. 5) of the narrow portion e of the portion 230f is formed so as to be bent in a W shape toward the right side of the drawing as shown in FIG. Other configurations are the same as those in the first embodiment.

  In the fourth embodiment configured as described above, as in the first embodiment, in the process in which each of the independent substrate portions 230d to 230f of the flexible printed circuit board 230a is repeatedly subjected to the curved displacement, The portions 230d to 230f are displaced so as to repeatedly move up and down at the corresponding convex curved portions m, k, and j.

  However, the signal wirings 232 to 234 are formed so that the corresponding bent portions We and the respective bent portions Wf are bent into a W-shape as described above at the corresponding convex curved portions m, k, and j. Has been.

  For this reason, the bent portion We and each bent portion Wf are respectively connected to the V-shaped bent portion Wd and the bent portion Wd described in the third embodiment in the corresponding convex curved portions m, k, and j, respectively. That is, it is formed more widely than each bent portion Wd. Therefore, when the individual substrate portions 230d to 230f are displaced so as to repeatedly move up and down at their corresponding convex curved portions m, k, and j as described above, the convex curved portions m, The distortion stress due to the curved deformation of k and j acts as a load over a wider range than the above-described bent portion Wc and each bent portion Wd with respect to the bent portion We and each bent portion Wf, respectively.

  Thereby, in each signal wiring 232-234, the load which acts on each corresponding bending part We and each bending part Wf is significantly compared with the case where each said signal wiring 232-234 is each formed in the shape of a straight line each. Naturally, it is alleviated more greatly than the third embodiment. Therefore, even if each independent board | substrate part 230d-230f repeats curved displacement as mentioned above, the elastic fatigue of the corresponding bending part We and each corresponding bending part Wf can be reduced much more favorably. As a result, each of the signal wirings 232 to 234 can maintain a function as a wiring even better without causing a conduction failure such as disconnection at the bent portions We and the respective bent portions Wf. Other functions and effects are the same as those of the first embodiment.

In carrying out the present invention, the following various modifications are possible without being limited to the above embodiment.
(1) In the above embodiment, as described above, the width of each of the signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234c is 1.5 (mm). A width within the range of 2.5 to 3.5 times the width 0.5 (mm) is substantially sufficient. The conventional predetermined width is not limited to 0.5 (mm), and may be a width slightly increased or decreased from 0.5 (mm).
(2) In carrying out the present invention, the widths of the negative side independent wiring portions 235b to 235d of the flexible printed circuit board 230a are not limited to 2 (mm), and the signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234a If it is wider than the width of 234c, it may be a width increased or decreased from 2 (mm). Each signal wiring part 232a-232c, 233a-233c, and 234a-234c
(3) In carrying out the present invention, each of the signal wiring portions 232a to 232c, 233a to 233c, and 234a to 234c has a predetermined predetermined cross-sectional area (for example, 0.1 (mm ² )) unlike the above embodiment. Even if it has a cross-sectional area within the range of 2.5 times to 3.5 times, the same effect as that of the above embodiment can be achieved.
(4) The LEDs described in the above embodiments are full-color LEDs each having a plurality of light-emitting portions R, light-emitting portions G, and light-emitting portions B. It may be a plurality of LEDs having a single light emitting unit having the same color.
(5) The configuration is not limited to the movable decorative bodies 240a to 240c described in the above embodiment, and any configuration can be used as long as it can be decorated.
(6) Instead of the step motor described in the above embodiment, another electric motor such as a DC motor may be employed.
(7) The plurality of negative-side independent wiring portions 235b to 235d of the negative-side wiring 235 described in the above embodiment is not limited to a single independent wiring portion, but for each negative-side independent wiring portion 235b to 235d. In addition, for example, two negative-side independent wiring portions may be used. In general, the number of the negative-side independent wiring portions may be smaller than the number of independent wiring portions of each of the plurality of positive-side wirings 232 to 234. Good. It is desirable that any negative-side independent wiring portion has a width wider than that of the positive-side wiring portion.
(8) Instead of the U-shaped wall portion 252, the elliptical wall portion 255, and the U-shaped wall portion 258 in each of the guide members 250 a to 250 c described in the above embodiment, a left and right longitudinal concave portion is formed inside. In general, a wall portion may be employed, and generally, each of the long plate portions 251, 254, and 255 may be protruded rearward from the long plate portions 251, 254, and 255. Any concave portion may be employed as long as it is a longitudinal concave portion in the left-right direction, and a through hole portion may be employed instead of the concave portion.
(9) In carrying out the present invention, unlike the above embodiment, in the flexible printed circuit board 230a, the positive wiring 234 is extended to the right end portion shown in FIG. 6 of the common layer portion 231a of the electrical insulating layer 231. Thus, the connection end portions of the signal wiring portions 234a to 234c of the positive side wiring 234 together with the connection end portions of the signal wiring portions of the other positive side wirings 232 and 233 are connected to the one side connector members 239a and 239b. Instead of this, it may be connected to each connector pin of a single one-side connector member. In addition, the connection ends of the signal wiring portions of both the positive side wires 232 and 233 may be connected to the respective connector pins of the one side connector member instead of the one side connector member 239a for each positive side wire. Good.
(10) In carrying out the present invention, the one-side connector members 239a and 239b may be mounted on the common substrate portion 230c of the flexible printed circuit board 230a from the insulating coating portion i side, unlike the above embodiment. .
(11) In carrying out the present invention, in each of the independent substrate portions 230d, 230e, and 230f of the flexible printed circuit board 230a, the corresponding narrow portions a, c, and e are cut out from at least one of the respective widthwise edge portions. The portion may be cut out.
(12) In carrying out the present invention, each of the openings 221 to 223 of the other housing member 220 may be a single opening that is long in the left direction.

Ba ... Game board, R, G, B ... Light emitting part, j, k, m ... Curved part,
W1-W3, Wa-Wf ... bent portion, 13 ... central opening, 220 ... other side housing member,
241 ... Lantern, 230 ... Illumination board, 230a ... Flexible printed circuit board,
230c ... Common substrate portion, 230d to 230f ... Independent substrate portion, 231 ... Electrical insulating layer,
231a ... Common layer part, 231b-231d ... Independent layer part, 232-234 ... Positive side wiring,
232a to 232c, 233a to 233c, 234a to 234c ... signal wiring part,
235 ... Negative side wiring, 235a ... Negative side common wiring part, 235b-235d ... Negative side independent wiring part,
236a, 236b, 237a, 237b, 238a, 238b ... LED,
239a, 239b ... one side connector member, 240a, 240b, 240c ... movable decorative body,
245 to 247 ... stepped bosses, 250a to 250c ... plate-like guide members,
260a-260c ... gear member, 270 ... step motor.

Claims (4)

In the movable effect device provided in the game board of the pachinko machine,
Illumination means,
A plurality of movable decorative bodies;
Driving means,
The electrical decoration means includes a single flexible printed circuit board and a plurality of electrical operation elements,
The flexible printed circuit board is
The common board part supported by a part of the game board, and the common board part are configured with a plurality of band-like independent board parts formed integrally,
A plurality of one-side wirings composed of a plurality of parallel signal wiring parts included independently of each other so as to extend independently over the common substrate part and the plurality of strip-like independent substrate parts;
The other wiring included in the common substrate portion and the plurality of band-like independent substrate portions so as to be electrically insulated from the plurality of one-side wiring, and the common wiring included in the common substrate portion And an other side wiring composed of at least one independent wiring part that is integrally extended from each of the plurality of strip-like independent substrate parts and is included in each of the plurality of strip-like independent substrate parts,
The plurality of lighting operation elements are respectively connected to the extending tip portions of the plurality of strip-like independent substrate portions from the plurality of one-side wiring sides, and the plurality of signal wiring portions and the at least one independent wiring. It is mounted so that it can be lit up and illuminated.
The plurality of movable decorative bodies are movably supported by the driving means, and each of the plurality of strip-like independent substrate portions is disposed between the extending tip portion and the common substrate portion in the plate thickness direction. To bend to form a curved portion ,
Each of the at least one independent wiring portion is formed wider than each of the plurality of signal wiring portions,
In previous SL multiple independent substrate portion, its each independently substrate portion, at least one of the plurality of signal line part and the at least one independent wire portion has a width at the corresponding site to the curved portion of its corresponding A movable effect device for a pachinko gaming machine, which is bent in a direction to form a bent portion. In the movable effect device provided in the game board of the pachinko machine,
A support wall member supported on a part of the game board on the back side thereof and extending toward the back side of the central opening of the game board;
Illumination means,
A plurality of movable decorative bodies;
Driving means,
The illumination means is
A single flexible printed circuit board,
A plurality of lighting operation elements each having a plurality of lighting operation parts,
The flexible printed circuit board is
The common substrate portion supported on the back surface of the support wall member, and the common substrate portion are formed integrally with a plurality of strip-like independent substrate portions that are independently extended from the common substrate portion. Being
The common layer portion included in the common substrate portion and the common layer portion are integrally formed, and extend independently from the common layer portion in parallel with each other, and each of the plurality of strip-like independent substrate portions. A flexible electrical insulating layer constituted by each band-like independent layer part included in
A plurality of one-side wirings formed of a flexible metal thin film so as to extend independently from the common layer portion to the plurality of strip-like independent layer portions along one side surface of the flexible electrical insulating layer. A plurality of one-side wirings composed of a plurality of parallel signal wiring parts,
A common wiring portion provided along the other side surface of the common layer portion and a plurality of independent wiring portions extending from the common wiring portion and provided along the plurality of strip-like independent layer portions, respectively, are integrally provided. The other side wiring formed with a flexible metal thin film,
Each of the plurality of electrical decoration actuating elements is mounted on each extending tip of the plurality of strip-like independent substrate portions from the one side surface of the flexible electrical insulating layer, and each of the corresponding plurality of electrical decorations At each one side terminal of the operating part, connected to each of the plurality of corresponding signal wiring parts, and at each other side terminal of the corresponding plurality of lighting operation parts, the plurality of strip-like independent layer parts Are connected to each of the plurality of independent wiring portions via each of
The plurality of movable decorative bodies are movably supported by the driving means via the support wall member, and each of the plurality of strip-like independent substrate portions is provided between the extending tip portion and the common substrate portion. Is bent in the thickness direction to form a curved portion ,
Each of the plurality of independent wiring portions is formed wider than each of the plurality of signal wiring portions ,
In previous SL multiple independent substrate portion, its each independently substrate portion, at least one of the plurality of signal line part and the at least one independent wire portion has a width at the corresponding site to the curved portion of its corresponding A movable effect device for a pachinko gaming machine, which is bent in a direction to form a bent portion.   In the plurality of independent substrate portions, for each independent substrate portion, the plurality of signal wiring portions are bent in the width direction at corresponding portions with respect to the corresponding curved portions to form bent portions. The movable effect device for a pachinko gaming machine according to claim 1 or 2, characterized by the above.   The movable effect device for a pachinko gaming machine according to any one of claims 1 to 3, wherein each of the bent portions has a trapezoidal shape, a V shape, or a W shape.

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