JP2004041316A - Game machine, its game board and control apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To further improve a shielding ability against electromagnetic noise caused by discharge of static electricity in a game machine and its game board and control apparatus, by electrically connecting to each other at least 2 shielding plates among respective shielding plates of a plurality of control units making up the control apparatus. <P>SOLUTION: A shielding plate 101 and a main control circuit 104 of a main control unit 100 are grounded to a wiring board 103, while a shielding plate 51 and a payment control circuit 54 of a payment control unit 50b are grounded to a wiring board 53. Both wiring boards 103, 53 are grounded through a wiring board 72 of an electric power unit 70, wherein the shielding plate 101 is electrically connected to the shielding plate 51 through a wiring Ls. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a gaming machine, a gaming board thereof, and a control device.
[0002]
[Prior art]
Conventionally, there is a pachinko machine as one of the gaming machines. The pachinko machine includes a pachinko machine main body and a game board detachably attached to the pachinko machine main body. The pachinko machine main body is configured by providing a power supply unit and a plurality of control units and the like on a frame, and the game board is configured by providing a plurality of control units and the like on the game board main body.
[0003]
[Problems to be solved by the invention]
By the way, the pachinko machine having the above configuration is usually divided into a plurality of islands in a pachinko hall and a plurality of pachinko machines are arranged for each island. In the pachinko hall, a large number of pachinko balls supplied from the island facilities are stored for each island in a storage tank for each pachinko machine, and thereafter guided from the storage tank to a guiding gutter located below the storage tank. Then, it is guided to the tray through a guide path extending in the vertical direction.
[0004]
In the process of storing the pachinko balls in the storage tank, the guiding process of the guiding gutter, and the guiding process of the guiding route, the pachinko balls generate static electricity by, for example, frictionally contacting each other and being charged by electrostatic induction. After this occurs, they contact or collide with each other, or come into contact with the inner wall of the storage tank, guide gutter or guide path, causing electrostatic discharge, and at the moment of this discharge, generate electromagnetic noise over a wide frequency band. . Such electromagnetic noise is a major cause of intrusion into each control unit and misoperation of each control unit.
[0005]
For example, when the control unit is a payout control unit, the payout control unit malfunctions due to the intrusion of the electromagnetic noise due to the discharge of the static electricity, and a situation occurs in which the payout ball is paid out in an unnecessarily large number. Sometimes.
[0006]
In order to prevent the above, a metal shield plate is attached to the wiring board of each control unit from the back side thereof, and electromagnetic noise entering each shield plate is reduced by, for example, the shield plate and the power supply. By trying to escape to ground through the ground of the wiring board of the unit, each control unit is trying to improve the shielding performance against electromagnetic noise.
[0007]
However, since the electromagnetic noise due to the electrostatic discharge as described above is generated under a strong electromagnetic field, the electromagnetic noise is an impulse-like or spike-like noise having a high peak level. Such noise cannot be completely shielded by merely providing a shield plate in the control unit, and enters the control unit, so that the malfunction cannot be prevented.
[0008]
On the other hand, the present inventors have made various studies on electromagnetic noise due to static electricity discharge in a pachinko machine, and noticed the following phenomenon. That is, since the generation of the electromagnetic noise due to the discharge of the static electricity occurs at the moment of the discharge, the electromagnetic noise easily enters the shield plate of the control unit located near the position where the electromagnetic noise is generated.
[0009]
Here, in the pachinko machine, when the storage tank, the guide gutter, and the guide path are located along, for example, each control unit of the game board and each control unit of the pachinko machine main body, the electromagnetic noise is generated in the storage tank, the guide gutter. And the electromagnetic noise is generated in the guide route, the electromagnetic noise is likely to mainly enter the shield plate of the control unit near the position where the electromagnetic noise is generated.
[0010]
Under such a phenomenon, it has been found that the peak level of the electromagnetic noise can be greatly reduced if the electromagnetic noise that enters the one shield plate flows into the other shield plate as well as the shield plate.
[0011]
Also, even if the electromagnetic noise enters both of the two shield plates adjacent to each other, or another electromagnetic noise enters the other shield plate simultaneously with the electromagnetic noise entering one of the two shield plates. It has also been found that the peak level of the electromagnetic noise can be significantly reduced by causing the electromagnetic noise entering each of the shield plates to flow into both of the shield plates.
[0012]
Therefore, the present invention, in order to cope with the above, in a gaming machine, its game board and a control device, at least two of the shield members of a plurality of control units constituting the control device are mutually connected. An object of the present invention is to further enhance a shielding property against electromagnetic noise generated by discharging static electricity by electrically connecting.
[0013]
Further, the present invention provides a gaming machine, a game board thereof, and a control device, wherein at least one of the shield members of the plurality of control units constituting the control device and at least one of the storage tank and the medium passage are provided. An object of the present invention is to further improve a shielding property against electromagnetic noise generated by electrostatic discharge by electrically connecting a conductive portion included in at least a part thereof to each other.
[0014]
[Means for Solving the Problems]
In order to solve the above problems, according to the present invention, a gaming machine according to the present invention includes a control circuit (54, 64, 104, 114) and a shield member (51, 61, 101, 101A, 101B, 111, 111). A plurality of control units (50b, 60a, 100, 100A, 100B, 110, 110A, 110B, 140, 150) each having 111A, 111B, 141, 151) are provided.
[0015]
In the gaming machine, at least two of the shield members of the plurality of control units are electrically connected to each other and can be grounded to the ground.
[0016]
The gaming machine having such a configuration is used in a state where it is grounded to the ground by the at least two shield members. Here, the earth to the earth may be grounded to the earth via the power supply circuit and the commercial power supply when the at least two shield members are earthed to the earth via the power supply circuit of the gaming machine. Includes the case where it is directly grounded.
[0017]
Under such an earth, a plurality of charged game media such as game balls collide with each other inside and outside the game machine, for example, so that electromagnetic noise generated by electrostatic discharge causes at least one of the at least two shield members. As the at least two shield members are electrically connected to each other as described above, the electromagnetic noise shunts to the at least two shield members and flows as each noise component. Then, each noise component flowing into each of the at least two shield members flows into the ground in the form of a spike or an impulse while trying to flow into the corresponding control circuit.
[0018]
Here, as described above, the electromagnetic noise is diverted to the at least two shield members, so that the peak level of each noise is significantly reduced as compared with the peak level of the electromagnetic noise flowing into only one shield member. obtain. This means that the shielding effect of the at least two shield members against each electromagnetic noise is greatly improved. Therefore, even if each noise component whose peak level is greatly reduced flows into the corresponding control circuit as described above, each control circuit is affected by the noise component and erroneously runs out. It can operate normally without operation.
[0019]
The electrical connection between the at least two shield members may be performed, for example, by connecting the at least two shield members via a low-impedance wiring (Ls). May be connected.
[0020]
According to the second aspect of the gaming machine according to the present invention,
A storage tank (30) for storing a chargeable game medium,
A plurality of control units (50b, 60a, 100, 100A) each having a control circuit (54, 64, 104, 114) and a shield member (51, 61, 101, 101A, 101B, 111, 111A, 111B, 141, 151). , 100B, 110, 110A, 110B, 140, 150);
A medium passage (40a, 40b) extending from the storage tank;
A receiving tray (Du) that is communicated through the medium passage into the storage tank and that discharges the game medium from the storage tank through the medium passage;
At least one of the storage tank and the medium passage has a conductive portion (30, 41, 42) in at least a part thereof.
[0021]
In the gaming machine, at least one of the shield members of the plurality of control units and the conductive portion are electrically connected to each other and can be grounded to the ground.
[0022]
The gaming machine having such a configuration is used with the at least one shield member and the conductive portion grounded to the ground. Here, the earth to the ground is a case where the at least one shield member and the conductive part are grounded to the earth via a power supply circuit of the gaming machine, or when the earth is grounded to the ground via the power supply circuit and the commercial power supply. In addition, this includes the case where the earth is directly grounded.
[0023]
Under such an earth, a plurality of charged game media such as game balls collide with each other in a process of being stored in a storage tank or in a process of moving in a medium passage, for example. When the noise enters the at least one shield member, the at least one shield member and the conductive portion are electrically connected to each other as described above. And then flows as noise. The noise component flowing into the at least one shield member flows into the ground in a spike shape or an impulse shape while trying to flow into the corresponding control circuit.
[0024]
Here, as described above, since the electromagnetic noise is diverted to the at least one shield member and the conductive portion, the peak level of the noise flowing into the shield member becomes the peak level of the electromagnetic noise flowing into only one shield member. It can be significantly reduced compared to the level.
[0025]
Thus, unlike the first aspect of the present invention, at least one of the storage tank and the medium passage is used to electrically connect the conductive part and the at least one shield member to each other. In this case, substantially the same operation and effect as the first aspect can be achieved.
[0026]
According to a third aspect of the present invention, in the gaming machine according to the first or second aspect, a power supply unit (70) having a power supply circuit (73) grounded to the ground via a commercial power supply (ES). )
The plurality of control units are electrically connected to the corresponding control circuits and power supply circuits via the negative power supply lines (L3, L5, L8) by corresponding shield members for each control unit.
[0027]
According to this, each noise component flowing into each of the at least two shield members in the first aspect of the invention or the noise component flowing into at least one shield member in the second aspect of the invention is a negative power supply While flowing into the ground through the line, the power supply circuit, and the commercial power supply, an attempt is made to flow into the corresponding control circuit through the negative power supply line.
[0028]
Also in such a case, the peak level of each noise flowing into each of the at least two shield members or the noise component flowing into each of the at least one shield member is significantly increased as in the first or second aspect of the present invention. Can be reduced. As a result, the third aspect of the invention can achieve substantially the same effects as those of the first or second aspect.
[0029]
According to a fourth aspect of the present invention, there is provided the gaming machine according to the first aspect, wherein at least two control units of the plurality of control units are mounted side by side at predetermined locations. 91, 91a, 20)
The at least two control units are connected to each other at the facing portions of the respective shield members so as to secure the mutual electrical connection, in accordance with the attachment to the attachment member.
[0030]
According to this, in accordance with the attachment of the at least two control units to the attachment member, the shield members are connected to each other at the opposing portions, thereby securing the mutual electrical connection. In other words, the mutual electrical connection of the shield members can be easily ensured by attaching the at least two control units to the attachment member as described above, so that the mutual electrical connection of the shield members can be secured. There is no need to make a separate connection.
[0031]
According to a fifth aspect of the present invention, there is provided the gaming machine according to the first aspect, wherein at least two of the plurality of control units are mounted side by side at predetermined positions on the mounting member. 91, 91a, 20),
A power supply unit (70) having a power supply circuit (73) grounded to the ground via a commercial power supply (ES);
The plurality of control units are electrically connected to corresponding control circuits and power supply circuits via negative power lines (L3, L5, L8) by corresponding shield members for each control unit.
The at least two control units are connected to each other at the opposed portions of the respective shield members so as to secure the mutual electrical connection, in accordance with the attachment to the attachment member.
[0032]
According to this, in the invention according to claim 1, each noise component flowing into each of the at least two shield members flows into the ground through the negative power supply line, the power supply circuit and the commercial power supply, while the corresponding control circuit Through the negative power line. Also in this case, the peak level of each noise flowing into each of the at least two shield members can be significantly reduced, as in the first aspect of the present invention. Further, the mutual electrical connection between the shield members can be easily ensured by attaching the at least two control units to the attachment member as described above. As a result, according to the fifth aspect of the invention, the effects of the first and fourth aspects of the invention can be synergistically achieved.
[0033]
According to a sixth aspect of the present invention, in the gaming machine according to the first aspect,
A mounting member (90, 91, 91a, 20) provided at a predetermined location for mounting at least two of the plurality of control units side by side, and a longitudinal conductive member (170) provided on the mounting member. prepare for,
The at least two control units are connected to the conductive member so as to secure the mutual electrical connection at the conductive member side ends (141b, 151b) of the shield members with the mounting to the mounting member. It is characterized by being connected.
[0034]
According to this, with the attachment of the at least two control units to the attachment member, each of the shield members is connected to the conductive member at an end thereof, so that the mutual electric connection is performed via the conductive member. Secure connection. In other words, the mutual electrical connection of the shield members can be easily secured via a conductive member by attaching the at least two control units to the attachment member as described above. There is no need to separately make an electrical connection between the two.
[0035]
According to a seventh aspect of the present invention, in the gaming machine according to the first aspect,
At a predetermined position, an attachment member (90, 91, 91a, 20) to which at least two control units of the plurality of control units are attached side by side, and a longitudinal conductive member (170) provided on the attachment member are provided. ,
A power supply unit (70) having a power supply circuit (73) grounded to the ground via a commercial power supply (ES);
The plurality of control units are electrically connected to corresponding control circuits and power supply circuits via negative power lines (L3, L5, L8) by corresponding shield members for each control unit.
The at least two control units are connected to the conductive member so as to secure the mutual electrical connection at the conductive member side ends (141b, 151b) of the shield members with the mounting to the mounting member. It is characterized by being connected.
[0036]
According to this, in the invention according to claim 1, each noise component flowing into each of the at least two shield members flows into the ground through the negative power supply line, the power supply circuit and the commercial power supply, while the corresponding control circuit Through the negative power line. Also in this case, the peak level of each noise flowing into each of the at least two shield members can be significantly reduced, as in the first aspect of the present invention. Further, the mutual electrical connection of the shield members can be easily secured via the conductive member by attaching the at least two control units to the attachment member as described above. As a result, according to the seventh aspect of the invention, the effects of the first and sixth aspects of the invention can be synergistically achieved.
[0037]
According to the eighth aspect of the present invention, a gaming board for a gaming machine according to the present invention has a gaming board body (80), a control box (90) protruding from the back of the gaming board body, and a back face of the control box. A power supply means (70) having a plurality of control units (100, 100A, 100B, 110, 110A, 110B, 140, 150) provided in (91a) and having a groundable wiring board (72) on the ground. , T).
[0038]
In the gaming board, a plurality of control units, for each control unit,
A conductive shield member (101, 101A, 101B, 111, 111A, 111B, 141, 151) provided on the back of the control box, and a wiring board (103, 113) provided in parallel with the shield member on the back side thereof And a control circuit (104, 114) provided on the wiring board.
Each corresponding shield member and control circuit are grounded to the corresponding wiring board, and the corresponding wiring board can be grounded to the wiring board of the power supply means via the negative power line (L3, L5, L8). Has become
At least two of the plurality of shield members are electrically connected to each other.
[0039]
As described above, by electrically connecting at least two of the plurality of shield members among the plurality of shield members in the plurality of control units of the game board for the gaming machine, the operation and effect of the invention described in claim 1 can be achieved. It is possible to provide a game board suitable for use in a game machine. In this case, since the game board is usually a replaceable component in the game machine for maintenance or the like, the game board to which the invention described in claim 8 is applied can be conveniently replaced as a unit.
[0040]
According to a ninth aspect of the present invention, in the game board for a gaming machine according to the eighth aspect, a plurality of control units are provided for each of the control units via the corresponding shield member. An electrically insulating wall member (102a, 112a, 142a, 152a) attached to the back surface, and provided along with the corresponding wall member via the corresponding shield member on the corresponding wiring board;
The at least two shield members are separably connected to each other at their opposing portions in accordance with the attachment of the corresponding wall members so as to secure the mutual electrical connection.
[0041]
According to this structure, not only the operation and effect of the invention according to claim 8 can be achieved, but also the mutual electrical connection of the at least two shield members is controlled by the control box of each corresponding wall member. Since it can be easily achieved by attaching to at least two shield members, it is not necessary to separately connect the at least two shield members to each other. In securing the mutual electrical connection, the opposing portions of the at least two shield members are separably connected to each other, so that in the maintenance of a game board to which the invention according to claim 9 is applied, It is convenient that each control unit having the at least two shield members can be easily separated from the control box.
[0042]
According to a tenth aspect of the present invention, in the game board for a gaming machine according to the eighth aspect, the at least two shield members are provided on the back surface of the control box on the same side of each of the at least two shield members. A longitudinal conductive member (170) provided in parallel to
Each of the plurality of control units includes an electrically insulating wall member (102a, 112a, 142a, 152a) attached to the back surface of the control box via the corresponding shield member for each control unit. The corresponding wall member is provided along with the corresponding shield member,
The at least two shield members are attached to the conductive member at the respective ends (141b, 151b) on the conductive member side with the mounting of the corresponding wall members so as to secure the mutual electrical connection. It is characterized by being separably connected.
[0043]
According to this structure, not only the operation and effect of the invention according to claim 8 can be achieved, but also the mutual electrical connection of the at least two shield members is controlled by the control box of each corresponding wall member. The electrical connection of the at least two shield members to one another does not need to be made separately, since this can easily be achieved with the attachment as described above. In order to secure the mutual electrical connection, since each end of the at least two shield members is separably connected to a conductive member, the maintenance of a game board to which the invention according to claim 10 is applied. In this case, each control unit having the at least two shield members can be easily separated from the control box, which is convenient.
[0044]
According to the eleventh aspect, the gaming machine control device according to the present invention includes a plurality of control units (50b, 60a, 100, 100A, 100B, 110, 110A, 110B, 140, 150). The game machine is provided with power supply means (70, T).
[0045]
In the control device, the power supply means includes a wiring board (72) grounded to the ground,
A plurality of control units, for each control unit,
A conductive shield member (51, 61, 101, 101A, 101B, 111, 111A, 111B, 141, 151), a wiring board (53, 63, 103, 113) provided in parallel with the shield member, and the wiring A control circuit (54, 64, 104, 114) provided on the plate,
Each corresponding shield member and control circuit are grounded to the corresponding wiring board, and the corresponding wiring board can be grounded to the wiring board of the power supply means via the negative power lines (L3, L5, L8). Yes,
At least two of the shield members are electrically connected to each other.
[0046]
With such a configuration, it is possible to provide a control device suitable for adopting a gaming machine that can achieve the same operation and effect as the invention described in claim 1.
[0047]
According to the third and fifth aspects of the present invention, the low-pass filter means (F1, F2) for preventing electromagnetic noise is inserted and connected to the control circuit side power line portion of the negative side power line for each control unit, or In each of the eighth to eleventh aspects of the present invention, the low-pass filter means (F1, F2) for preventing electromagnetic noise is inserted into a ground-side power line portion of the negative-side power line and the wiring board of the control circuit for each control unit. If connected, electromagnetic noise can be prevented from entering the corresponding control circuit by the low-pass filter means. As a result, the invention according to claims 3 and 5 or the invention according to claims 8 to 11 can be achieved. The function and effect can be further improved.
[0048]
In addition, according to a specific example of the invention described in claims 1 to 7, first, the gaming machine described in claim 1 is:
Back set structure having an annular frame (W), an annular set plate (20) provided in the frame, a power supply unit (70) provided on the back of the set plate, and a plurality of control units (50b, 60a) (U) and a gaming machine body (B) comprising:
A game board main body (80) detachably provided in the opening (28) of the set board, a control box (90) protruding from the game board main body to the rear side thereof so as to correspond to the opening of the set board; A game board (P) provided with a plurality of control units (100, 100A, 100B, 110, 110A, 110B, 140, 150) provided on the back surface (91a) of the control box may be provided.
[0049]
In the gaming machine, the power supply unit includes a wiring board (72) that can be directly grounded to the ground or grounded via a commercial power supply.
[0050]
In addition, a plurality of control units of the game board, for each control unit,
A conductive shield plate (101, 101A, 101B, 111, 111A, 111B, 141, 151) provided on the back of the control box, and a wiring board (103, 113) provided on the shield plate in parallel on the back side thereof And control circuits (104, 114) provided on the wiring board.
[0051]
In addition, the plurality of control units of the back set structure include, for each control unit, a conductive shield plate (51, 61) provided on the back surface of the set plate and a wiring board (parallel to the back surface of the shield plate). 53, 63) and control circuits (54, 64) provided on the wiring board.
[0052]
Here, each of the plurality of control units of the game board and the back set structure is grounded to a corresponding wiring board by a corresponding shield plate and control circuit for each control unit, and furthermore, the corresponding wiring The board can be grounded to the wiring board of the power supply unit via the negative power lines (L3, L5, L8). At least two of the shield plates are electrically connected to each other.
[0053]
According to this, in each control unit, when the corresponding wiring board is grounded to the wiring board of the power supply means via the negative power supply line, each corresponding shield plate and control circuit are connected to the corresponding wiring board, the negative side. It is grounded to the ground through the power supply line and the wiring board of the power supply unit. As described above, at least two of the shield plates are electrically connected to each other.
[0054]
In such a configuration, when a plurality of charged game media such as chargeable game balls collide with each other inside and outside the game machine, for example, electromagnetic noise generated by electrostatic discharge is generated by the electrostatic noise of the at least two shield plates. When the electromagnetic noise enters one of the shield plates, the electromagnetic noise splits into the at least two shield plates and flows as each noise component.
[0055]
In this way, each noise component flowing into each shield plate flows in the form of a spike or an impulse into the ground through the corresponding wiring board, the negative power supply line and the wiring board of the power supply unit, while each negative power supply Attempts to flow into each corresponding control circuit via a line.
[0056]
Since the electromagnetic noise is diverted to the corresponding shield plates as described above, the peak level of each noise can be significantly reduced as compared with the peak level of the electromagnetic noise flowing into only one shield plate.
[0057]
Secondly, in the gaming machine according to claim 1, a plurality of control units of the game board are detachably and immovably attached to the back of the control box via the corresponding shield plate for each control unit. An electric insulating box (102, 112, 142, 152) is provided, and the corresponding wiring board is provided on the corresponding shield plate side wall (102a, 112a, 142a, 152a) in the corresponding box. They may be provided together via a shield plate.
[0058]
Here, at least two shield plates of the game board can be separated from each other so as to secure the mutual electrical connection at each of the opposing portions, with the attachment of the corresponding boxes to the back of the control box. Linked to
[0059]
Thirdly, in the configuration of the first or second gaming machine, a plurality of control units of the back-set structure can be detachably attached to the back surface of the set plate via the corresponding shield plate for each control unit. An electrically insulative box (52, 62) which is fixedly and immovably attached to the wall (52a, 62a) on the corresponding shield plate side in the corresponding box. They may be provided together via a shield plate. Here, at least two shield plates of the back set structure are attached to each other so that the mutual electrical connection is ensured at each of the opposing portions with the attachment of the corresponding boxes to the back surface of the control box. They are separably connected.
[0060]
Fourth, in the first gaming machine, a longitudinal conductive member (170) is provided on the back surface of the control box over at least two shield plates of the game board and provided in parallel with these shield plates on each same side thereof. ,
Each of the plurality of control units of the game board includes an electrically insulating box (142, 152) detachably and immovably attached to the back of the control box via the corresponding shield plate for each control unit. In the corresponding box, the corresponding wiring board is provided alongside the corresponding shield plate side wall (142a, 152a) in the corresponding box via the shield plate.
[0061]
Here, at least two shield plates of the game board are connected to the mutual electrical connection at each end (141b, 151b) on the conductive member side with the attachment of the corresponding box to the back of the control box. It is separably connected to the conductive member so as to secure the connection.
[0062]
Fifth, in the above first or fourth gaming machine, at least two shield plates of the back set structure are provided on the back surface of the set plate in parallel with these shield plates on the same side thereof. A conductive member (170);
Each of the plurality of control units of the back-set structure includes a box (142, 152) that is detachably and immovably attached to the rear surface of the set plate via the corresponding shield plate for each of the control units. In the corresponding wiring board, the corresponding shield plate side wall (142a, 152a) may be provided in the corresponding box via the shield plate.
[0063]
Here, at least two shield plates of the back set structure are attached to the conductive member at each end (141b, 151b) on the conductive member side with the attachment of the corresponding box to the back surface of the set plate of each corresponding box. , Are separably connected so as to secure the mutual electrical connection.
[0064]
Sixth, a gaming machine according to claim 2 has an annular frame (W) having a tray (Du), an annular set plate (20) provided in the frame, and a rear surface of the set plate. A storage tank (30) for storing a chargeable game medium, a medium passage (40a, 40b) for communicating the storage tank with the tray so as to pay out the game medium from the storage tank to a tray, and a power supply unit (70) And a back set structure (U) having a plurality of control units (50b, 60a), and a gaming machine body (41) having a conductive portion (41, 42) in at least a part of at least one of a storage tank and a medium passage. B)
A game board main body (80) detachably provided in the opening (28) of the set board, a control box (90) protruding from the game board main body to the rear side thereof so as to correspond to the opening of the set board; A game board (P) including a plurality of control units (100, 100A, 100B, 110, 110A, 110B, 140, 150) provided on the back surface (91a) of the control box may be provided.
[0065]
In the gaming machine, the power supply unit includes a wiring board (72) that can be grounded on the ground, and the storage tank is grounded to the wiring board of the power supply unit.
[0066]
In addition, a plurality of control units of the game board include, for each control unit, a conductive shield plate (101, 101A, 101B, 111, 111A, 111B, 141, 151) provided on the back surface of the control box. A wiring board (103, 113) provided in parallel on the rear side thereof, and a control circuit (104, 114) provided on the wiring board.
[0067]
In addition, the plurality of control units of the back set structure are, for each of the control units, positioned in parallel with the conductive shield plate (51, 61) provided on the back surface of the set plate on the back surface side of the shield plate. A wiring board (53, 63) and a control circuit (54, 64) provided on the wiring board are provided.
[0068]
Here, each of the plurality of control units of the game board and the back set structure is grounded to a corresponding wiring board by a corresponding shield plate and a control circuit for each control unit. And can be grounded to the wiring board of the power supply means via the negative power supply line (L3, L5, L8).
At least one of the shield plates and the storage tank are electrically connected to each other. In the above first to sixth gaming machines, when the shield plate is a container-shaped or box-shaped conductive shield member, a wiring board corresponding to the shield plate is provided inside the shield member. A control circuit corresponding to the wiring board is provided alongside the bottom wall (corresponding to the shield board), and the control circuit corresponding to the wiring board is provided alongside the wiring board in the shield member.
[0069]
In addition, the code | symbol in the parenthesis of each said means shows the correspondence with the concrete means described in embodiment mentioned later.
[0070]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(1st Embodiment)
1 to 7 show a first embodiment in which the present invention is applied to a pachinko machine. This pachinko machine includes a pachinko machine main body B and a game board P, as shown in FIGS. The pachinko machine main body B includes an annular frame W and a back set structure U. As shown in FIGS. 1 and 2, the annular frame W includes a glass frame W1, an inner frame W2, and an outer frame W3. The glass frame W1 is attached to the inner frame W2 from the front side. The inner frame W2 is hinged to the right end of the outer frame W3 from the front side at the right end shown in FIG. The pachinko machine is used standing upright so that the upper and lower portions of the pachinko machine main body B shown in FIG.
[0071]
The back set structure U includes an annular set plate 20, a long storage tank 30, a long guide gutter 40a, and a long guide path 40b. The set plate 20 is interposed between the inner frame W2 and the outer frame W3 at the right end shown in FIG. 1 and is hinged to the inner frame W2 on the right end side. The storage tank 30 is mounted on the upper side of the set plate 20 on the side wall thereof as shown in FIG. 1 from the rear side thereof. A large number of pachinko balls made of metal are supplied and stored so as to be always full.
[0072]
The guide gutter 40a is mounted on the back surface of the set plate 20 so as to extend along the lower side of the bottom wall of the storage tank 30 as shown in FIG. A large number of pachinko balls are discharged together from the discharge port of the storage tank 30 and are guided to the right in FIG. The guide path 40b is mounted vertically along the right end of the set plate 20 in FIG. 1 from the rear side thereof. The guide path 40b is guided under the control of the ball payout control device 50. The pachinko ball guided by the gutter 40a is guided downward.
[0073]
As shown in FIG. 1, the back-set structure U includes a ball payout control device 50. The ball payout control device 50 includes a payout motor 50a and a payout control unit 50b. The payout motor 50a is supported by the set plate 20 in a vertically intermediate portion of the guide path 40b. As shown in FIGS. 1 and 3, the payout control unit 50b is attached to the lower right side of the set plate 20 in the drawing from the back side. As can be seen from FIGS. 3 and 4, the payout control unit 50b includes a rectangular conductive shield plate 51 made of a metal such as copper or aluminum, a conductive resin, and the like, and a box 52 made of an electrically insulating resin having a rectangular parallelepiped shape. , A wiring board 53, and a payout control circuit 54.
[0074]
The shield plate 51 is housed in the right side of the U-shaped concave portion 21 (see the enlarged views of FIGS. 3 and 4) formed at the lower part of the set plate 20 in FIG. The plate thickness is equal to the depth of the recess 21.
[0075]
The box 52 is located on the bottom wall 52 a of the shield plate 51 and the right side of the recess 21 of the set plate 20, and the box 52 is located on the lower flange 52 b of the set plate 20. It is accommodated from the upper end opening thereof in a U-shaped accommodation section 22 formed near the lower right end of the recess 21 on the rear surface. The box 52 is sandwiched between its left and right L-shaped support members 23a and 23b provided on the back surface of the set plate 20 at its upper flange 52c as shown in FIG. It is fixed to the back surface of the set plate 20 by 24. Thereby, the box 52 is immovably attached to the set plate 20 via the shield plate 51 from the rear surface thereof.
[0076]
The L-shaped left and right support members 23a and 23b oppose each other and are fixed to the set plate 20 from the rear side so as to sandwich the upper flange 52c from the left and right. The L-shaped stopper 24 is rotatably supported by a pin 24a on the back surface of the set plate 20 at an intermediate position between the left and right support members 23a and 23b.
[0077]
The wiring board 53 is provided alongside the bottom wall 52 a in the box 52, and the wiring board 53 is used for connection wiring (a power supply line section, an earth line section, and a plurality of signal line sections) with the delivery control circuit 54. Is printed on the surface of a printed circuit board. The payout control circuit 54 is provided on the surface of the wiring board 53 and is electrically connected to the wiring. Here, the power supply terminal, the ground terminal, and the plurality of signal terminals of the payout control circuit 54 are connected to the power supply line portion, the ground line portion, and the plurality of signal line portions of the wiring board 53, respectively.
[0078]
The ball payout control device 50 configured as described above pays out pachinko balls guided from the guiding gutter 40a into the guide route 40b by the payout control circuit 54 under the control of the main control unit 100 described below. The payout motor 50a is driven and controlled based on the conditions and other conditions to pay out the pachinko balls into the upper plate Du.
[0079]
Also, as shown in FIGS. 1 to 4, the back-set structure U includes a sphere launch control device 60, and the sphere launch control device 60 includes a launch control unit 60 a and a launch motor 60 b. I have. The firing control unit 60a is attached to the set plate 20 from the back side adjacent to the left side of the payout control unit 50b. As can be seen from FIGS. 3 and 4, the firing control unit 60 a includes a rectangular shield plate 61 made of the same material as the shield plate 51, a rectangular parallelepiped electrically insulating resin box 62, and a wiring board 63. , A launch control circuit 64.
[0080]
The shield plate 61 is formed with a plate thickness equal to the depth of the U-shaped concave portion 21 of the set plate 20. The shield plate 61 is positioned on the left side of the shield plate 51 so as to be located on the left side of the shield plate 51. Is accommodated in the left side of the U-shaped concave portion 21 of FIG.
[0081]
The box 62 is located on the bottom wall 62a of the shield plate 61 and a portion near the left side of the recess 21 of the set plate 20, and the box 62 is located on the lower flange 62b of the set plate 20. It is accommodated in a U-shaped accommodating section 25 formed near the lower end of the left side of the recess 21 on the back side from the upper end opening. The box 62 is sandwiched between the left and right L-shaped support members 26a and 26b provided on the back surface of the set plate 20 at its upper flange 62c, and the set plate 20 is fixed by the L-shaped stopper 27. Fixed on the back. As a result, the box 62 is attached to the set plate 20 via the shield plate 61 so as to be immovable from the rear surface thereof.
[0082]
The left and right L-shaped support members 26a and 26b are fixed to the set plate 20 from the rear side thereof so as to face each other so as to sandwich the upper flange 62c from the left and right. The L-shaped stopper 27 is rotatably supported on the back surface of the set plate 20 by a pin 27a at an intermediate position between the left and right support members 26a and 26b.
[0083]
The wiring board 63 is provided alongside the bottom wall 62 a in the box 62, and the wiring board 63 is used for connection wiring (a power supply line section, a ground line section, and a plurality of signal line sections) with the emission control circuit 64. Is printed on the surface of a printed circuit board. The firing control circuit 64 is provided on the surface of the wiring board 63 and is electrically connected to the wiring. Here, the power supply terminal, the ground terminal, and the plurality of signal terminals of the emission control circuit 64 are connected to the power supply line portion, the ground line portion, and the plurality of signal line portions of the wiring board 63, respectively.
[0084]
Thus, the firing control unit 60a drives and controls the firing motor 60b by the firing control circuit 64 under the control of the main control unit 100 accompanying the operation of the operation handle H, and fires the pachinko ball from the upper plate Dd. .
[0085]
The back set structure U includes a power supply unit 70 as shown in FIG. The power supply unit 70 includes a rectangular parallelepiped box 71 made of an electrically insulating resin, a wiring board 72, and a power supply circuit 73. The unit is attached from the back.
[0086]
The wiring board 72 is provided alongside the bottom wall in the box 71, and the wiring board 72 provides wiring for connection to the power supply circuit 73 (including the power supply line portion and the ground line portion) on the surface of the printed circuit board. It is composed by printing. Here, the power supply terminal and the ground terminal of the power supply circuit 73 are connected to the power supply line portion and the ground line portion of the wiring board 72. Thus, the power supply unit 70 converts an AC voltage of 24 V (described later) into a DC voltage of, for example, 24 V.
[0087]
The game board P includes a game board body 80 and a control box 90 provided on the game board body 80 from the back side. The game board main body 80 is configured by providing a liquid crystal panel portion at the center of the game area from the front side (front side), and the game board main body 80 includes an opening of the annular frame W and the annular set plate 20. , And faces forward through the opening of the frame W in the game area. Note that a plurality of winning devices, a plurality of lamps, and both speakers are provided in the gaming area.
[0088]
The control box 90 extends from the back of the game board main body 80 through the opening 28 of the set plate 20 to the back side thereof. The control box 90 includes a box 91 made of an electrically insulating resin having a rectangular parallelepiped shape, A control circuit and the like for the liquid crystal panel provided therein are accommodated.
[0089]
As shown in FIGS. 1 and 5, the game board P includes a main control unit 100 and a sound / lamp control unit 110. The main control unit 100 and the sound / lamp control unit 110 The box 90 is disposed on the bottom wall 91a of the box 91 with a space left and right from the back side thereof.
[0090]
As can be seen from FIGS. 5 and 6, the main control unit 100 includes a rectangular shield plate 101 made of the same material as the shield plate 51, a rectangular parallelepiped box 102 made of electrically insulating resin, a wiring board 103, And a main control circuit 104. The shield plate 101 is accommodated in the bottom wall 91a of the box 91 in the right side of the U-shaped recess 91b formed from the back side thereof. In the present embodiment, the shield plate 101 is formed with a plate thickness equal to the depth of the recess 91b and with the same forming material as the shield plate 51.
[0091]
The box 102 is located on the bottom wall 102a of the shield plate 101 and the bottom wall 91a of the box 91 on the vicinity of the right side of the recess 91b, and the lower flange 102b of the box 102 is connected to the bottom wall 91a. Is accommodated from the upper end opening in a U-shaped cross-section accommodating portion 91c formed near the lower right end of the concave portion 91b on the rear surface of the concave portion 91b. The upper flange 102c of the box 102 is sandwiched between left and right L-shaped support members 91d and 91e provided on the back surface of the bottom wall 91a, and is fixed to the back surface of the bottom wall 91a by L-shaped stoppers 91f. Have been. Thus, the box 102 is immovably provided on the bottom wall 91a of the box 91 via the shield plate 101 from the rear side thereof.
[0092]
The left and right L-shaped support members 91d and 91e are fixed to the set plate 20 from the rear side thereof so as to oppose each other so as to sandwich the upper flange 102c from the left and right. The L-shaped stopper 91f is rotatably supported by a pin 91g on the back surface of the bottom wall 91a at an intermediate position between the left and right support members 91d and 91e.
[0093]
The wiring board 103 is provided alongside the bottom wall 102 a in the box 102, and the wiring board 103 is used to connect to the main control circuit 104 (a power supply line section, an earth line section, and a plurality of signal line sections). Is printed on the surface of a printed circuit board. The main control circuit 104 is provided on the surface of the wiring board 103 and is electrically connected to the wiring. Here, the power supply terminal, the ground terminal, and the plurality of signal terminals of the main control circuit 104 are connected to the power supply line portion, the ground line portion, and the plurality of signal line portions of the wiring board 103.
[0094]
The main control unit 100 thus configured controls the payout control unit 50b, the firing control unit 60a, the sound / lamp control unit 110, the control circuit in the control box 90, and the like.
[0095]
As can be seen from FIGS. 5 and 6, the sound / lamp control unit 110 includes a rectangular shield plate 111 made of the same material as the shield plate 51, a rectangular parallelepiped box 112 made of an electrically insulating resin, and a wiring board 113. And a sound / lamp control circuit 114. The shield plate 111 has a plate thickness equal to the depth of the recess 91 b and is housed in the left portion of the recess 91 b of the box 91.
[0096]
The box 112 is located on the bottom wall 112a of the shield plate 111 and a portion near the left side of the recess 91b of the bottom wall 91a of the box 91. The lower flange 112b of the box 112 is It is accommodated in the U-shaped accommodation portion 91h formed near the lower end of the left side portion of the recess 91b on the rear surface from the upper end opening. The upper flange 112c of the box 112 is sandwiched between left and right L-shaped support members 91i and 91j provided on the back surface of the bottom wall 91a, and is fixed to the back surface of the bottom wall 91a by L-shaped stoppers 91k. Have been. As a result, the box 112 is immovably attached to the bottom wall 91a of the box 91 via the shield plate 111.
[0097]
The left and right L-shaped support members 91i and 91j are fixed to the set plate 20 from the rear side thereof so as to face each other so as to sandwich the upper flange 112c from the left and right. The L-shaped stopper 91k is rotatably supported by a pin 91m on the back surface of the bottom wall 91a at an intermediate position between the left and right support members 91i and 91j.
[0098]
The wiring board 113 is provided alongside the bottom wall 112 a in the box 112, and the wiring board 113 is connected to a sound / lamp control circuit 114 (power supply line section, ground line section, and a plurality of signal lines). Part is printed on the surface of the printed circuit board. The sound / lamp control circuit 114 is provided on the surface of the wiring board 113 and is electrically connected to the wiring. Here, the power terminal, the ground terminal, and the plurality of signal terminals of the sound / lamp control circuit 114 are connected to the power line portion, the ground line portion, and the plurality of signal line portions of the wiring board 113. The sound / lamp control unit 110 configured as described above controls the above-mentioned speaker and lamp under the control of the main control unit 100.
[0099]
The lower plate Dd is provided below the pachinko machine main body together with the upper plate Du so as to be located below the upper plate Du, and stores the pachinko balls overflowing with the upper plate Dd. In the first embodiment, the main control unit 100, the sound / lamp control unit 110, the payout control unit 50b, the firing control unit 60a, the control circuit in the control box 90, and the like each have a CPU as a main component. Are included in the control device of the pachinko machine.
[0100]
Next, an electrical connection system of the pachinko machine will be described. In the power supply unit 70, the wiring board 72 is grounded to the ground (see Gs in FIG. 7) at the ground wire portion. The wiring board 72 is connected to the negative terminal of the secondary coil T2 of the transformer T via a negative power supply line L1 at the ground wire portion. , Is connected to the positive terminal of the secondary coil T2 of the transformer T via the positive power line L2. The transformer T is connected to a negative terminal of the commercial AC power supply ES at a negative terminal of the primary coil T1.
[0101]
In the first embodiment, the transformer T is provided at an appropriate position in the pachinko hall where the pachinko machine is installed, and the transformer T converts the 100 V AC voltage applied from the AC power supply ES into the 24 V AC voltage. And the AC voltage is applied to the wiring board 72 from the secondary coil T2 via the negative power line L1 and the positive power line L2. Note that the primary coil T1 and the secondary coil T2 of the transformer T are in a state of floating from the ground in terms of potential. The negative terminal (lower terminal in FIG. 7) of the commercial AC power supply ES is grounded (not shown) to the ground.
[0102]
In the main control unit 100, the main control circuit 104 is connected to the ground wire of the wiring board 103 at the ground terminal (see reference numeral 104a in FIG. 7) as described above. Thus, the main control circuit 104 is grounded to the wiring board 103 (see G1 in FIG. 7).
[0103]
The wiring board 103 is connected at its ground wire to the ground wire of the wiring board 72 of the power supply unit 70 via the negative power supply line L3 for the main control unit. The power supply unit 70 is connected to the power supply line of the wiring board 72 of the power supply unit 70 via the positive power supply line L4 for the main control unit. Accordingly, the main control circuit 104 operates by applying the DC voltage of the power supply circuit 73 via the wiring board 72, the positive and negative power supply lines L4 and L3, and the wiring board 103. In the first embodiment, the shield plate 101 is connected to an intermediate portion of the negative power supply line L3 (see reference numeral a in FIG. 7), and the ground terminal 104a of the main control circuit 104 and the two The same reference potential is maintained with each ground line.
[0104]
In the payout control unit 50b, the payout control circuit 54 is connected to the ground wire of the wiring board 53 at the ground terminal (see reference numeral 54a in FIG. 7) as described above. Thus, the payout control circuit 54 is grounded to the wiring board 53 (see G2 in FIG. 7).
[0105]
The wiring board 53 is connected at its ground line to an intermediate portion of the negative power supply line L3 via the payout control unit negative power supply line L5. The power supply line of the wiring board 53 is connected to the payout control unit. It is connected to an intermediate portion of the positive power supply line L4 via the positive power supply line L6. Thus, the payout control circuit 54 operates by applying the DC voltage of the power supply circuit 73 via the wiring board 72, the negative power supply lines L3 and L5, the positive power supply lines L4 and L6, and the wiring board 53.
[0106]
Further, the shield plate 51 is connected to the shield plate 101 by the wiring Ls. The wiring Ls plays a role of causing the electromagnetic noise flowing into the shield plate 101 due to the intrusion into the shield plate 101 to also flow into the shield plate 51. Here, assuming that the outer dimensions and the forming material of the shield plates 101 and 51 are the same, the impedance of the wiring Ls is substantially equal to the DC component and the frequency component of the electromagnetic noise in the shield plates 101 and 51. It is set low so as to divide evenly without loss.
[0107]
Further, the shield plate 51 is connected to an intermediate portion of the negative power supply line L5 (see reference numeral b in FIG. 7), and is connected to the ground terminal 54a of the dispensing control circuit 54 and the ground wire portions of the wiring boards 53 and 72. Maintain the same reference potential. Note that other control units such as the sound / lamp control unit 110 and the firing control unit 60a are also connected to the power supply unit 70 by the other negative power supply line and positive power supply line (not shown), similarly to the payout control unit 53. It is connected to a negative power supply line L3 and a positive power supply line L4 with the main control unit 110.
[0108]
In the first embodiment configured as above, it is assumed that a large number of the pachinko machines are arranged in a plurality of islands in the pachinko hall. Here, the transformer T receives an AC voltage of 100 V from the AC power supply ES, and converts the AC voltage to an AC voltage of 24 V. Hereinafter, the operation of the pachinko machine of FIG. 1 will be described as an example among many pachinko machines.
[0109]
In the power supply unit 70 of the pachinko machine, when the power supply circuit 73 receives the AC voltage of 24 V from the transformer T and converts it into a DC voltage of 24 V, the DC voltage is converted to the positive and negative power supply lines L4 and L3 and the main control unit 100. Is applied to the main control circuit 104 via the wiring board 103, and is applied to the payout control circuit 54 via both the positive and negative power supply lines L4 and L3, the positive and negative power supply lines L6 and L5, and the wiring board 53 of the payout control unit 53. . As a result, the main control circuit 104 and the payout control circuit 54 are activated. The same applies to other circuits of the pachinko machine.
[0110]
In such a state, when the pachinko balls are supplied from the island facility corresponding to the pachinko machine into the storage tank 30 of the pachinko machine, the pachinko balls are stored so as to fill the storage tank 30. At this time, it is assumed that the ball is discharged from the discharge port of the storage tank 30 through the guiding gutter 40a and the guide path 40b into the upper plate Du under the control of the ball discharging controller 50.
[0111]
Thus, when the pachinko balls in the upper plate Du are sequentially hit into the game area of the game board main body 80 under the control of the ball launch control device 60 based on the operation of the operation handle H, the pachinko balls in the storage tank 30 move as described above. Similarly, it is paid out into the upper plate Dd. In addition, when the pachinko balls are awarded to the prize device in the game area, for example, the pachinko balls in the storage tank 30 are paid out into the upper plate Dd in a number that satisfies the winning condition.
[0112]
By the way, in the process of storing the pachinko balls in the storage tank 30 as described above, the guiding process by the guiding gutter 40a, and the guiding process by the guide path 40b, the respective pachinko balls are charged by electrostatic induction due to, for example, frictional contact with each other. To generate static electricity. After this occurrence, the charged pachinko balls collide with each other or come into contact with the inner wall of the storage tank 30, the guiding gutter 40a or the guide path 40b, and discharge static electricity. Generates electromagnetic noise.
[0113]
Here, each pachinko ball in the storage tank 30 is discharged to the upper plate Du from the outlet of the storage tank 30 through the guide gutter 40a and the guide path 40b as described above. Further, the electromagnetic noise is generated at the moment of discharge of static electricity. Therefore, the electromagnetic noise is instantaneously generated with a time delay sequentially in the order of the storing process in the storage tank 30, the guiding process of the guiding gutter 40a, and the guiding process of the guiding route 40b.
[0114]
Also, since the main control unit 100 is located immediately below the guide gutter 40a and in the vicinity of the upstream of the guide path 40b, the electromagnetic noise generated as described above guides the pachinko ball from the downstream of the guide gutter 40a to the pachinko ball. The electromagnetic noise (refer to the symbol N in FIG. 7) generated in the process and the guidance process of the upstream part of the guidance route 40b mainly enters the main control unit 100.
[0115]
In addition, since the guide gutter 40a and the guide path 40b are located on the front side of the pachinko machine with respect to the shield plate 101 of the main control unit 100, the electromagnetic noise generated in the above guide process and the guide process is transmitted to the shield plate 101 by the front surface thereof. Invade from the side. In addition, the shield plate 101 is electrically connected to the shield plate 111 of the payout control unit 110 by the wiring Ls.
[0116]
Accordingly, the electromagnetic noise that enters the shield plate 101 flows into the shield plate 101 and also flows into the shield plate 51 through the wiring Ls. In other words, since the wiring Ls has a low impedance, the electromagnetic noise generated in the guidance process and the guiding process and entering the shield plate 101 satisfactorily branches into the shield plates 101 and 51 and flows.
[0117]
Thus, of the electromagnetic noise that enters the shield plate 101, the noise component flowing through the shield plate 101 flows into the ground through the negative power line L3 and the ground wire of the shield plate 72 of the power unit 70 in a spike shape. On the other hand, an attempt is made to flow into the main control circuit 104 from the intermediate portion of the negative power supply line L3 (refer to the symbol a in FIG. 7) through the ground wire portion of the wiring board 103 from the ground terminal 104a.
[0118]
However, as described above, since the electromagnetic noise is favorably shunted to both shield plates under the low-impedance wiring Ls as described above, the peak level of the noise is determined when there is no wiring Ls. This is significantly reduced as compared with the peak level of the electromagnetic noise flowing only into the shield plate 101. This means that the shielding effect of the shield plate 101 against electromagnetic noise is greatly improved. Therefore, even if the noise component greatly reduced as described above flows into the main control circuit 104 as described above, the main control circuit 104 may malfunction due to runaway of the CPU or the like under the influence of the noise component. It can work normally without.
[0119]
Incidentally, both the pachinko machine of the first embodiment having the configuration of FIG. 7 and the conventional pachinko machine having the configuration in which the wiring Ls is eliminated in FIG. No), a predetermined voltage pulse is injected into each of the pachinko machines a predetermined number of times from a predetermined site on the premise that environmental conditions such as temperature are the same, and noise generated due to injection of the pulse is generated. By flowing from the shield plate 101 to the main control circuit 104 through the intermediate portion a of the negative power supply line L3, the frequency of occurrence of abnormalities such as runaway of the main control circuit 104 was observed. According to this, it was found that the pachinko machine having the configuration of FIG. 7 is improved about 1.4 times as compared with the conventional pachinko machine having the configuration in which the wiring Ls is eliminated in FIG. Thereby, it was confirmed that the shield effect can be achieved by connecting the two shield plates 101 and 51 with the wiring Ls in the first embodiment described above.
[0120]
As described above, of the electromagnetic noise that enters the shield plate 101, the noise component shunted to the shield plate 51 is transmitted to the negative power line L <b> 5, a part of the negative power line L <b> 3, and the ground wire of the shield plate 72. While flowing into the ground, the ground terminal 54a passes through the ground line portion of the wiring board 51 from the intermediate portion of the negative power line L3 (refer to reference numeral b in FIG. 7) through the negative power line L5 to the discharge control circuit 54. However, the peak level of this noise is greatly reduced in the same manner as the noise flowing through the shield plate 101. This means that the shield effect of the shield plate 51 against electromagnetic noise is greatly improved as in the case of the shield plate 101. Therefore, the payout control circuit 54 can operate normally without malfunction such as runaway due to the influence of the noise.
[0121]
Further, in the first embodiment, the wiring board 72 of the power supply unit 70 is grounded to the ground as described above. However, for example, the shield plate 72 is electrically floating from the ground due to forgetting to ground to the ground. , The ground of the negative terminal of the AC power supply ES to the ground is secured, and since the primary and secondary coils of the transformer T are in the AC coupling state, the negative power supply line L3 The frequency component of the noise component from the shield plate 101 flowing into the ground passes through the ground line portion of the shield plate 72, the negative power supply line L1, the transformer T, and the negative terminal of the AC power supply ES, and flows into the ground. This is the same on the shield plate 51 side. Therefore, the effect obtained by connecting the two shield plates 101 and 51 with the wiring Ls can be substantially achieved even if the wiring board 72 is not grounded to the ground.
[0122]
Here, in main control unit 100, first, shield plate 101 is housed in the right side of recess 91 b of box 91. Next, while the box 102 is housed in the housing portion 91c of the box 91 by its lower flange 102b, the bottom wall 102a of the shield plate 101 and the bottom wall 91a of the box 91 near the right side of the recess 91b. And is fixed by a stopper 91f on a portion near the upper end of the recess 91b in the bottom wall 91a while being sandwiched between the support members 91d and 91e by the upper flange 102c. . Thus, the main control unit 100 can be easily attached to the box 91 in a detachable and immovable manner.
[0123]
Also, the recess 91b is formed in a U-shaped cross section, and the plate thickness of the shield plate 101 is equal to the depth of the recess 91b. Therefore, the shield plate 101 is formed by the bottom wall 102a of the box 102 and the bottom of the recess 91b. It can be immovably pinched between the wall. As a result, the shielding effect against electromagnetic noise by the shield plate 101 of the main control unit 100 can be further improved.
[0124]
In the payout control unit 50b, first, the shield plate 51 is housed in the right side of the recess 21 of the set plate 20. Next, the box 52 is housed in the housing portion 22 of the set plate 20 at its lower flange 52b, and is placed on the bottom wall 52a of the shield plate 51 and the set plate 20 near the right side of the recess 21. And is fixed by a stopper 24 on the upper portion of the set plate 20 near the upper end of the recess 21 while being sandwiched and supported between the two support members 23a and 23b by the upper flange 52c. Thus, the payout control unit 50b is easily attached to the set plate 20 in a detachable and immovable manner.
[0125]
Further, since the recess 21 is formed in a U-shaped cross section and the plate thickness of the shield plate 51 is equal to the depth of the recess 21, the shield plate 51 is formed by the bottom wall 52 a of the box 52 and the bottom of the recess 21. It can be immovably pinched between the wall. As a result, the shield effect against the electromagnetic noise by the shield plate 51 of the payout control unit 50b can be further improved.
[0126]
Since the sound / lamp control unit 110 and the firing control unit 60a have substantially the same configuration as the main control unit 100, the sound / lamp control unit 110 and the firing control unit 60a are connected to the box 91 and the set plate 20 of the main control unit 100. The effect of each support is substantially the same as the effect of support on the bottom wall 91a of the main control unit 100.
[0127]
Further, in the first embodiment, the electromagnetic noise generated in the downstream portion of the guide gutter 40a and the upstream portion of the guide route 40b coincides with the electromagnetic noise generated in the downstream portion of the guide route 40b entering the shield plate 51. When the electromagnetic wave enters the shield plate 101, the electromagnetic noises that enter the shield plates 51 and 101 are both split and flow into the shield plates 51 and 101 via the wiring Ls. Thereby, substantially the same operation and effect can be achieved as when electromagnetic noise enters only the shield plate 101.
(2nd Embodiment)
8 and 9 show a main part of a second embodiment of the present invention. In the second embodiment, a main control unit 100A and a sound / lamp control unit 110A are employed instead of the main control unit 100 and the sound / lamp control unit 110 in the first embodiment.
[0128]
The main control unit 100A has a configuration in which the shield plate 101A made of the same material as the shield plate 101 is used instead of the shield plate 101 in the main control unit 100. This shield plate 101A includes a flat plate-shaped main body 101a and a flange 101b. The plate main body 101a is accommodated in the right side of the recess 91b of the box 91. As can be seen from FIGS. 8 and 9, the flange 101b is cross-sectionally upward in FIG. 9 by the thickness of the plate body 101a from the center in the width direction to the left of the left end of the plate body 101a. It extends like a crank.
[0129]
The sound / lamp control unit 110A has a configuration in which the shield plate 111A made of the same material as the shield plate 111 is used instead of the shield plate 111 in the sound / lamp control unit 110. The shield plate 111A includes a flat plate body 111a and a flange 111b. The plate body 111a is accommodated in the left portion of the recess 91b of the box 91. As shown in FIGS. 8 and 9, the flange 111b extends in a flat shape from the center in the width direction of the right end of the plate body 111a to the right, and the flange 111b of the shield plate 111A and the recess of the box 91 are formed. It is interposed between the bottom wall of 91b. As a result, the shield plate 111A is sandwiched between the flange 101b of the shield plate 101A and the bottom wall of the recess 91b of the box 91 at the flange 111b, and is electrically connected to the shield plate 101A. . Other configurations are the same as those of the first embodiment.
[0130]
In the second embodiment configured as described above, when attaching the main control unit 100A and the sound / lamp control unit 110A to the control box 90, the sound / lamp control unit 110A is attached before the control unit 100A. That is, in the sound / lamp control unit 110A, the shield plate 111A is accommodated in the left portion of the recess 91b of the box 91. This accommodation is performed such that the plate main body 111a of the shield plate 111A is located on the left side of the flange 111b.
[0131]
Next, the box 112 is detachably and immovably attached to the bottom wall 91a of the box 91 in the same manner as described in the first embodiment.
[0132]
After the installation of the sound / lamp control unit 110A is completed as described above, the shield plate 101A is housed in the right part of the recess 91b of the box 91 in the main control unit 100A. This accommodation is performed such that the flange 101b of the shield plate 101A is positioned on the left side of the plate body 101a and overlaps the flange 111b of the shield plate 111A. Next, the box 102 is detachably and immovably attached to the bottom wall 91a of the box 91 as described in the first embodiment.
[0133]
With the installation of the sound / lamp control unit 110A as described above and the subsequent installation of the main control unit 100A, the two shield plates 101A and 111A are separably connected to each other by their respective flanges 101b and 111b. Electrical connection can be secured. Thereby, the mutual electrical connection between the two shield plates 101A and 111A is established by the electrical connection such as the wiring Ls due to the attachment of the sound / lamp control unit 110A and the main control unit 100A to the bottom wall 91a of the box 91. It can be easily achieved without requiring additional members.
[0134]
Here, since the plate thickness of each of the shield plates 111A and 101A is equal to the depth of the concave portion 91b having a U-shaped cross section, the shield plates 111A and 101A are provided at the bottoms of the boxes 112 and 102 in their respective plate bodies. And the bottom wall of the recess 91b. Therefore, the electrical connection between the shield plates 101A and 111A can be satisfactorily secured.
[0135]
After the sound / lamp control unit 110A and the main control unit 100A are attached to each other as described above, in the process of storing a large number of charged pachinko balls in the storage tank 30 from the island facility, the pachinko balls collide with each other. The static electricity is discharged by, for example, instantaneous generation of electromagnetic noise (see reference numeral N in FIG. 8).
[0136]
Here, the sound / lamp control unit 110A is located immediately below the storage tank 30 similarly to the sound / lamp control unit 110. Further, since the storage tank 30 is located on the front side of the pachinko machine relative to the shield plate 111A, the electromagnetic noise generated in the storage process enters the shield plate 111A from the front side. Further, as described above, the shield plate 111A is electrically connected to the shield plate 101A.
[0137]
Therefore, the electromagnetic noise that enters the shield plate 111A flows into the shield plate 111A and also flows into the shield plate 101A through the flange 111b. In other words, the electromagnetic noise generated in the storage process and entering the shield plate 111A is split into and flows into the shield plates 111A and 101A.
[0138]
Thus, of the electromagnetic noise that has entered the shield plate 111A, the noise component flowing through the shield plate 111A is transmitted from the intermediate portion of the negative power line (not shown) for the sound / lamp control unit connected to the shield plate 111A to the wiring board. An attempt is made to flow into the sound / lamp control circuit 114 from the ground terminal through the ground line portion 113. However, the noise component that is going to flow into the shield plate 111A is that the electromagnetic noise is diverted to both the shield plates 111A and 101A as described above, and that both the flanges 111b and 101b have low impedance based on the forming material. Therefore, the peak level of the noise is significantly reduced as compared with the peak level of the electromagnetic noise flowing only into the shield plate 111A. Therefore, even if the noise component thus reduced flows into the sound / lamp control circuit 114 as described above, the sound / lamp control circuit 114 operates normally without malfunction due to the influence of the noise component. I can do it.
[0139]
Here, since the game board P is detachable from the pachinko machine main body B, the game board P having the main control unit 100A and the sound / lamp control unit 110A can be replaced as it is at the time of maintenance or the like. And convenient.
[0140]
As described above, of the electromagnetic noise that enters the shield plate 111A, the noise component flowing through the shield plate 101A passes through the negative power supply line for the main control unit and the negative power supply line for the sound / lamp control unit, and An attempt is made to flow from the ground terminal to the main control circuit 104 through the ground line portion. However, the peak level of the noise is greatly reduced similarly to the noise flowing through the shield plate 111A. It can operate normally without malfunction due to the influence of the noise.
[0141]
Further, in the second embodiment, the electromagnetic noise generated in the storage tank 30 is reduced by the electromagnetic noise generated in the storage tank 30 as the electromagnetic noise generated in the downstream portion of the guide gutter 40a and the upstream portion of the guide path 40b enters the shield plate 101A. When the electromagnetic noise enters the shield plate 101A, the electromagnetic noises entering the shield plates 101A and 111A are both split and flow into the shield plates 101A and 111A via the wiring Ls. Thereby, substantially the same operation and effect as in the case where the electromagnetic noise enters only the shield plate 111A can be achieved.
[0142]
The above-described effects can be similarly achieved even when the wiring board 72 is not grounded to the ground as described in the first embodiment.
(Third embodiment)
10 and 11 show a main part of a third embodiment of the present invention. In the third embodiment, a main control unit 100B and a sound / lamp control unit 110B are used instead of the main control unit 100A and the sound / lamp control unit 110A in the second embodiment, and a stopper 130 is added. It is a configuration that has been adopted.
[0143]
The main control unit 100B has a configuration in which a shield plate 101B made of the same material as the shield plate 101A is employed instead of the shield plate 101A in the main control unit 100A. The shield plate 101B includes a flat plate-shaped main body 101c and a flange 101d. The plate main body 101c is accommodated in the right side of the recess 91b of the box 91. As shown in FIGS. 10 and 11, the flange 101d extends in a flat shape from the center in the width direction to the left of the left end of the plate body 101c.
[0144]
The sound / lamp control unit 110B has a configuration in which the shield plate 111B made of the same material as the shield plate 111A is employed instead of the shield plate 111A in the sound / lamp control unit 110A. The shield plate 111B includes a flat plate main body 111c and a flange 111d. The plate main body 111c is accommodated in the left portion of the recess 91b of the box 91.
[0145]
As shown in FIGS. 10 and 11, the flange 111d extends in a flat plate shape from the center in the width direction of the left end of the plate body 101a to the right. Thus, the shield plate 111B is located on the same plane as the flange 101d of the shield plate 101B at a predetermined interval at the flange 111d, facing the flange 101d.
[0146]
The stopper 130 includes a rotating piece 131, a screw 132, and a boss 133 made of an electrically insulating material. The boss 133 is provided between the flanges 101d and 111d on the bottom wall of the recess 91b as shown in FIG. Is fixed. The turning piece 131 is rotatably supported at the center by a screw 132 at the upper end of the boss 133. The turning piece 131 is turned at both ends by its turning. It is designed to engage with the flanges 101d and 111d from the front side. However, the rotating piece 131 is formed of the same material as the shield plate 101B. Other configurations are the same as those in the second embodiment.
[0147]
In the third embodiment configured as described above, the main control unit 100B and the sound / lamp control unit 110B are attached to the control box 90 as follows. Unlike the second embodiment, the order of attaching the main control unit 100B and the sound / lamp control unit 110B to the control box 90 does not matter.
[0148]
In the sound / lamp control unit 110B, the shield plate 111B is housed in the left part of the recess 91b of the box 91. This accommodation is performed such that the plate main body 111c of the shield plate 111B is located on the left side of the flange 111d. Next, the box 112 is attached to the bottom wall 91a of the box 91 as in the second embodiment.
[0149]
In the main control unit 100B, the shield plate 101B is housed in the right part of the recess 91b of the box 91. In this housing, the flange 101d of the shield plate 101B is positioned on the left side of the plate main body 101c, and faces the flange 111d of the shield plate 111B via the rotating piece 131 of the stopper 130 (shown by a two-dot line in FIG. 10). It is made to let. Next, the box 102 is attached to the bottom wall 91a of the box 91 as in the second embodiment.
[0150]
After such attachment, the turning piece 131 of the stopper 130 is turned with the screw 132 as a reference, so that the turning piece 131 engages both flanges 101d and 111d at both ends thereof from the respective surface sides. I do. Thus, the two shield plates 100B and 110B can be electrically connected by the rotating pieces 131 at the respective flanges 101d and 111d. Therefore, in the third embodiment as well, it is not necessary to employ the wiring Ls as in the second embodiment.
[0151]
Here, the turning piece 131 is formed of a conductive material similarly to the two shield plates 101B and 111B, and is provided between both end portions of the turning piece 131 and the bottom wall of the recess 91b. Since the 101d and 111d are firmly supported, the electrical connection between the two shield plates 101B and 111B via the rotating piece 131 can be sufficiently ensured.
[0152]
Therefore, the electromagnetic noise generated in the process of storing the pachinko balls in the storage tank 30 flows separately to the shield plates 101B and 111B instead of the shield plates 101A and 111A described in the second embodiment. Therefore, also in the third embodiment, the same operation and effect as those in the second embodiment can be achieved.
[0153]
The above-described effects can be similarly achieved even when the wiring board 72 is not grounded to the ground as described in the first embodiment.
(Fourth embodiment)
FIGS. 12 and 13 show a main part of a fourth embodiment of the present invention. In the fourth embodiment, a main control unit 140 and a sound / lamp control unit 150 are used instead of the main control unit 100 and the sound / lamp control unit 110 in the first embodiment, The plate 170 is additionally employed. In the fourth embodiment, instead of the recess 91b described in the first embodiment, both housing portions 91p and 91q are provided on the bottom wall 91a of the box 91 as shown in FIG. The openings are formed so as to face each other and project in a U-shaped cross section.
[0154]
The main control unit 140 employs a shield plate 141 made of the same material as the shield plate 101 and a box 142 made of the same material as the box 102, instead of the shield plate 101 and the box 102 in the main control unit 100. It has a configuration. The shield plate 141 includes a plate body 141a and a flange 141b. The plate body 141a is provided on the right side of the bottom wall 91a of the box 91 from the rear side. The flange 141b extends from the upper end of the plate body 141a to the surface side of the conductive plate 170 and upwards in a crank-shaped cross section by the thickness of the conductive plate 170.
[0155]
The box 142 is provided at the bottom wall 142a of the box body 141a on the right side of the bottom wall 91a via the plate body 141a, and the right flange 142b of the box 142 is accommodated in the accommodation portion 91p from the opening thereof. . Thereby, the flange 142b is sandwiched and supported between the shield plate 141 and the upper wall of the housing portion 91p. The wiring board 103 described in the first embodiment is provided in the box 142 on the bottom wall 142a. The flange 142b extends rightward from the right end of the bottom wall 142a.
[0156]
The left flange 142c extends leftward from the left end of the bottom wall 142a on the same plane as the right flange 142b, and is sandwiched between upper and lower L-shaped support members 91r and 91s as shown in FIG. Supported. The upper and lower support members 91r and 91s are fixed to the bottom wall 91a of the box 91 to face each other so as to sandwich the left flange 142c from above and below.
[0157]
The sound / lamp control unit 150 is different from the sound / lamp control unit 110 in that the shield plate 151 and the box made of the same material as the box 112 are used instead of the shield plate 111 and the box 112. 152 is adopted. The shield plate 151 includes a plate body 151a and a flange 151b. The plate body 151a is provided on the left side of the bottom wall 91a of the box 91 from the back side. The flange 151b extends from the upper end of the plate body 151a to the surface side of the conductive plate 170 by a thickness equal to the thickness of the conductive plate 170 and has a crank-shaped cross section.
[0158]
The box 152 is provided on the left side of the bottom wall 91a via the plate body 151a at the bottom wall 152a, and the left flange 152b of the box 152 is housed in the housing part 91q from its opening. . Thus, the flange 152b is sandwiched and supported between the shield plate 151 and the upper wall of the housing portion 91q. The wiring board 113 described in the first embodiment is provided inside the box 152 on the bottom wall 152a. The flange 152b extends leftward from the left end of the bottom wall 152a.
[0159]
The right flange 152c extends rightward from the right end of the bottom wall 152a on the same plane as the left flange 152b. Thus, the right flange 152c is opposed to the left flange 142c with an interval. As shown in FIG. 12, the right flange 152c is sandwiched between upper and lower L-shaped support members 91t and 91u. The upper and lower supporting members 91t and 91u are fixed to the bottom wall 91a of the box 91 so as to oppose each other so as to sandwich the right flange 152c from above and below.
[0160]
The stopper 160 includes a rotating piece 161, a boss 162, and a screw 163. The boss 162 is provided on the bottom wall 91a of the box 91 between the flanges 142c and 152c as shown in FIGS. It is fixed. The rotating piece 161 is rotatably supported at its center by a screw 163 at the upper end of the boss 162. The rotating piece 161 is rotated at both ends by its rotation. The flanges 142c and 152c are engaged from the front side thereof.
[0161]
The conductive plate 170 is made of the same material as the shield plates 141 and 151. The conductive plate 170 is mounted horizontally on the bottom wall 91a of the box 91 immediately above the boxes 142 and 152. I have. The lower right part of the conductive plate 170 is engaged with the cross-section crank-shaped flange 141b of the shield plate 141 from the front side, and the lower left part of the conductive plate 170 is connected to the crank-shaped flange of the shield plate 151 from the front side. 151b. Thus, the two shield plates 141 and 151 are electrically connected via the conductive plate 170 at the respective flanges 141b and 151b. Other configurations are the same as those of the first embodiment.
[0162]
In the fourth embodiment configured as described above, the main control unit 140 and the sound / lamp control unit 150 are attached to the bottom wall 91a of the box 91 as described above. The flanges 142c and 152c of the boxes 142 and 152 are fixed to the bottom wall 91a by the rotation of the rotation piece 161 by the stopper 160. Thus, the main control unit 140 and the sound / lamp control unit 150 are immovably attached to the control box 90.
[0163]
By such an attachment, the shield plates 141 and 151 can be engaged with the conductive plate 170 at the respective flanges 141b and 151b and can be electrically connected via the conductive plate 170. Therefore, in the fourth embodiment, it is not necessary to employ the wiring Ls as described in the first embodiment.
[0164]
In addition, the electromagnetic noise generated in the process of storing the pachinko balls in the storage tank 30 enters the shield plate 151, and this electromagnetic noise flows into the shield plate 151 and passes through the conduction plate 170 and also to the shield plate 141. Inflow. As described above, the electromagnetic noise is split and flows into the shield plates 151 and 141 in the same manner as the split and flows to the shield plates 101A and 111A described in the second embodiment. Thus, in the fourth embodiment, the same function and effect as those of the second embodiment can be achieved.
[0165]
The above-described effects can be similarly achieved even when the wiring board 72 is not grounded to the ground as described in the first embodiment.
[0166]
Further, in the embodiment of the present invention, unlike the fourth embodiment, the conductive plate 170 may be mounted horizontally on the bottom wall 91a of the box 91 immediately below both the boxes 142 and 152. Along with this, the shield plate 141 extends from the lower end of the plate body 141a through the box 142 to the surface side of the conductive plate 170 and downwards in the shape of a crank at the flange 141b thereof, by the thickness of the conductive plate 170. Is formed so that the flange 151b extends from the lower end of the plate body 151a through the box 152 to the surface side of the conductive plate 170 and downwards in a crank shape in cross section.
[0167]
In the embodiment of the present invention, the configuration of the conductive member 170 and the control unit described in the fourth embodiment may be applied to each control unit of the back-set structure U.
(Fifth embodiment)
FIG. 14 shows a main part of a fifth embodiment of the present invention. In the fifth embodiment, in the first embodiment, the storage tank 30 is electrically connected to the shield plate 101 of the main control unit 100 via the wiring Ls instead of the payout control unit 50b. I have.
[0168]
The storage tank 30 is formed of a conductive resin material, and the storage tank 30 is connected to the wiring board of the power supply unit 70 via a part of the storage tank negative power supply line L7 and the main control unit negative power supply line L3. 72 is connected to the ground wire. In addition, the negative power supply line L7 is connected at one end to an intermediate portion of the negative power supply line L3, and at the other end to a part of the storage tank 30 (see reference numeral c in FIG. 14). . Other configurations are the same as those of the first embodiment.
[0169]
In the fifth embodiment configured as described above, if electromagnetic noise is generated in the process of storing pachinko balls in the storage tank 30 from the island facility in the same manner as described in the second embodiment, the electromagnetic noise is generated at the position where the electromagnetic noise is generated. Mainly penetrates into the peripheral wall and the bottom wall of the storage tank 30 made of the conductive resin material located closest to the storage tank 30.
[0170]
The electromagnetic noise thus entering flows into the peripheral wall and the bottom wall of the storage tank 30 and also flows into the shield plate 101 of the main control unit 100 via the wiring Ls. In other words, the electromagnetic noise splits and flows into both the storage tank 30 and the shield plate 101.
[0171]
Thus, the part of the electromagnetic noise that enters the storage tank 30 and flows through the shield plate 101 from the intermediate portion a of the negative power supply line L3 through the ground wire portion of the wiring board 103 as in the first embodiment. An attempt is made to flow into the control circuit 104 from its ground terminal 104a.
[0172]
However, the noise component flowing into the intermediate portion a of the negative power supply line L3 is, as described above, because the electromagnetic noise is distributed to the storage tank 30 and the shield plate 101 and the wiring Ls has low impedance. The minute peak level is much lower than the peak level of the electromagnetic noise flowing only into the shield plate 101. Therefore, even if the noise component thus reduced flows into the main control circuit 104 as described above, the main control circuit 104 can operate normally without malfunction due to the influence of the noise component.
[0173]
Note that, in principle, the noise component of the storage tank 30 flows to the ground through the ground wire portion of the wiring board 72, but the wiring board 72 is not grounded to the ground as described in the first embodiment. However, since the frequency component of the noise component of the storage tank 30 flows from the negative terminal of the AC power supply ES to the ground, the operation and effect described in the fifth embodiment described above can be achieved.
[0174]
In the embodiment of the present invention, as shown by a two-dot chain line in FIG. 1, the guiding gutter 40a has a conductive portion 41 on its outer wall, and the guide path 40b has a conductive portion at an intermediate portion thereof. For example, the conductive portion 41 or 42 is electrically connected between the negative power supply line L7 and the wiring Ls instead of the storage tank 30 in FIG. Also, the conductive portion 41 or 42 plays a role similar to that of the conductive storage tank 30, so that substantially the same operation and effect as in the fifth embodiment can be achieved. The conductive portions 41 and 42 are formed of, for example, respective plate-shaped current collecting members adhered to respective outer walls of the guide gutter 40a and the guide path 40b.
(Sixth embodiment)
15 and 16 show a main part of a sixth embodiment of the present invention. In the sixth embodiment, in place of the two shield plates 51 and 61 (see FIG. 4) and the wiring Ls (see FIG. 7) in the first embodiment, they are formed of the same material as the shield plates 51 and 61. The configuration employs a common shield plate S.
[0175]
The common shield plate S is housed in the recess 21 of the set plate 20 instead of the shield plates 51 and 61 so as to serve as a shield plate common to the payout control unit 50b and the firing control unit 60a. I have. Accordingly, the box 52 described in the first embodiment is located on the right side of the common shield plate S and the right side of the recess 21 of the set plate 20 on the bottom wall thereof. On the other hand, the box 62 described in the first embodiment is located on the bottom wall on the left side of the common shield plate S and on the set plate 20 near the left side of the recess 12.
[0176]
The firing control unit 60a is connected to the power supply unit 70 instead of the main control unit 100 described in the first embodiment (see FIGS. 7 and 16). That is, in the firing control unit 60a, the firing control circuit 64 is connected to the ground wire of the wiring board 63 at the ground terminal 64a. Thus, the firing control circuit 64 is grounded to the wiring board 63 (see G3 in FIG. 16).
[0177]
The wiring board 63 is connected at its ground wire to the ground wire of the wiring board 72 of the power supply unit 70 via the negative power supply line L8 for the emission control unit. The power supply unit 70 is connected to the power supply line of the wiring board 72 of the power supply unit 70 via the positive power supply line L7. As a result, the firing control circuit 64 operates by applying the DC voltage of the power supply circuit 73 via the wiring board 72, the power lines L7 and L8 on both the positive and negative sides, and the wiring board 63.
[0178]
Here, the common shield plate S is connected to an intermediate portion of the negative power supply line L8 (see reference numeral d in FIG. 16), and the ground terminal 64a of the emission control circuit 64 and each ground wire of both wiring boards 63 and 72 are connected. The same reference potential is maintained with the unit. The payout control unit negative power supply line L5 described in the first embodiment is connected at one end to an intermediate portion of the negative power supply line L8. Is connected to a portion of the common shield plate S corresponding to the payout control unit 50b (a portion corresponding to the shield plate 51) (see reference numeral b in FIG. 16). Other configurations are the same as those of the first embodiment.
[0179]
In the sixth embodiment configured as described above, the payout control unit 50b is located closer to the downstream portion of the guide route 40b than the firing control unit 60a. For this reason, as described in the first embodiment, of the electromagnetic noise generated in the process of guiding the pachinko ball by the guide path 40b, the electromagnetic noise generated in the downstream portion of the guide path 40b is mainly generated by the common shield plate S. Of these, it enters a portion corresponding to the payout control unit 50b.
[0180]
The electromagnetic noise that invades in this manner is transmitted not only to the portion corresponding to the payout control unit 50b but also to the emission control unit 60a of the common shield plate S because the common shield plate S is formed by one shield plate. It also flows into the corresponding site. This means that the electromagnetic noise that enters the portion of the common shield plate S corresponding to the payout control unit 50b is also diverted and flows into the portion of the common shield plate S corresponding to the launch control unit 60a. Means
[0181]
As a result, the peak level of the noise that is going to flow into the payout control circuit 54 is greatly reduced in the same manner as the noise that is going to flow into the main control circuit 104 described in the first embodiment, and the emission is performed. The peak level of the noise that is going to flow into the control circuit 64 is greatly reduced in the same manner as the noise level that is going to flow into the payout control circuit 54 described in the first embodiment. As a result, even if the noise components thus reduced flow into the payout control circuit 54 and the emission control circuit 64, the payout control circuit 54 and the emission control circuit 64 are not affected by the noise components. , Can work normally. Other functions and effects are the same as those of the first embodiment.
(Seventh embodiment)
FIG. 17 shows a main part of a seventh embodiment of the present invention. In the seventh embodiment, the set plate 20 described in the sixth embodiment also serves as the common shield plate S. For this reason, the set plate 20 is formed of a conductive resin material, and the recess 21 of the set plate 20 and the common shield plate S are eliminated. The boxes of the payout control unit 50b and the firing control unit 60a are attached to the back of the set plate 20 below the control box 90 in substantially the same manner as in the sixth embodiment.
[0182]
The negative power line L5 (see FIG. 16) described in the sixth embodiment is electrically connected to one portion of the set plate 20 at an intermediate portion b, and the negative power line L8 (see FIG. 16). 16) is electrically connected to another portion of the set plate 20 at an intermediate portion d. Other configurations are the same as in the sixth embodiment.
[0183]
In the seventh embodiment configured as described above, since the set plate 20 made of the conductive resin material also plays the role of the common shield plate S as described above, the common shield plate S is eliminated. In addition, the same operation and effect as the sixth embodiment can be substantially achieved.
(Eighth embodiment)
FIG. 18 shows a main part of an eighth embodiment of the present invention. In the eighth embodiment, a low-pass filter F1 is additionally employed in the main control unit 100 and a low-pass filter F2 is additionally employed in the payout control unit 50b in the first embodiment. I have.
[0184]
Both low-pass filters F1 and F2 have a configuration mainly including an electromagnetic coil. The low-pass filter F1 is inserted and connected in series to a power supply line portion between the intermediate portion a of the negative power supply line L3 and the ground terminal 104a of the main control circuit 104, and the low-pass filter F1 is connected to the intermediate portion a The terminal on the side is grounded to the wiring board 103 (see G4 in FIG. 18). On the other hand, the low-pass filter F2 is inserted and connected in series to a power supply line portion between the intermediate portion b of the negative power supply line L5 and the ground terminal 54a of the dispensing control circuit 54. The terminal on the part b side is grounded to the wiring board 53 (see G5 in FIG. 18).
[0185]
The low-pass filter F1 plays a role of blocking electromagnetic noise that enters the main control circuit 104 from the intermediate portion a of the negative power line L3 from its ground terminal 104a, and the low-pass filter F2 functions as an intermediate portion of the negative power line L5. It plays a role in blocking electromagnetic noise that enters the dispensing control circuit 54 from the part b from the ground terminal 54a. The impedance of each of the low-pass filters F1 and F2 is selected so as to increase as the frequency of the electromagnetic noise input to each of the low-pass filters increases. Other configurations are the same as those of the first embodiment.
[0186]
In the eighth embodiment configured as described above, despite the use of the wiring Ls, as described in the first embodiment, the noise component flowing into the shield plate 101 due to the shunting is applied to the negative power supply line L3. An attempt is made to flow from the intermediate portion a to the main control circuit 104 side, and as described in the first embodiment, noise flowing into the shield plate 51 due to the shunt is paid out from the intermediate portion b of the negative power supply line L5. Even if it is attempted to flow into the control circuit 54, each of the above-mentioned noise components is significantly reduced as compared with the peak level of the electromagnetic noise that enters the shield plate 101 as described above. Therefore, the inflow of these noises into the main control circuit 104 and the payout control circuit 54 can be reliably prevented by the corresponding low-pass filters F1 and F2. As a result, the operation and effect described in the first embodiment can be further improved.
(Ninth embodiment)
FIG. 19 shows a main part of a ninth embodiment of the present invention. In the ninth embodiment, in the main control unit 100 described in the eighth embodiment, the power supply line portion between the intermediate part a of the negative power supply line L3 and the intermediate part a side terminal of the low-pass filter F1. Are constituted by an earth plate 105 as shown in FIG.
[0187]
The ground plate 105 is fastened to the lower left corner of the wiring board 103 in FIG. 19 by screws 105 a, and the ground plate 105 is electrically connected to the ground wire of the wiring board 103. Have been.
[0188]
In the ninth embodiment, both connectors 106 and 107 are employed. The connector 106 is disposed at the center of the left end of the wiring board 103, and the connector 106 electrically connects the intermediate portion a of the negative power line L3 to a part 105 b of the ground plate 105. Further, the connector 107 is provided on the wiring board 103 via the center of the ground plate 105, and the wiring Ls is electrically connected to the center of the ground plate 105 at one end by the connector 107. I have. Note that a terminal t provided at the other end of the wiring Ls is electrically connected to an engaging portion 51a formed by cutting out an end of the shield plate 51 of the payout control unit 50b. Other configurations are the same as in the eighth embodiment.
[0189]
According to the ninth embodiment configured as described above, the connection between the negative power supply line L3 and the low-pass filter F1 and the both shield plates of the wiring Ls are achieved by employing the ground plate 105, the connectors 106 and 107, and the terminal t. The same operation and effect as those of the eighth embodiment can be achieved while the connection between 101 and 51 is easily performed.
[0190]
In the embodiment of the present invention, unlike the above embodiments, the annular frame W may be connected to the inner frame W2 by detachably fixing the set plate 20 to the inner frame W2 with a stopper. The game board main body 80 may be configured to be supported by a support frame detachably or integrally provided from the rear side of the frame W2, and the set plate 20 may be hinged to the support frame.
[0191]
Further, in implementing the present invention, in the gaming board P, unlike the above embodiments, the gaming board body 80 may be provided in the opening portion 28 of the set plate 20 so as to be detachable from the back side thereof.
[0192]
In the embodiment of the present invention, the recesses 21 of the set plate 20 or the recesses 91b of the box 91 described in the first embodiment are eliminated, and the shield plates 51 and 61 are provided on the flat back surface of the set plate 20. Alternatively, the shield plates 101 and 111 may be fixed to the flat back surface of the bottom wall 91a of the box 91. In this case, in order to support the upper flange of the box 52, the thickness of the left and right L-shaped support members 23 a and 23 b and the interval between the back surface of the fastener 24 and the back surface of the set plate 20 are set by the plate thickness of the shield plate 51. What is necessary is just to increase. This is substantially the same for the upper flanges of the boxes 62, 102, and 112, and is also substantially the same in the second, third, and sixth embodiments.
[0193]
Further, in practicing the present invention, the shield plate described in each of the above embodiments may be in a container shape or a box shape. In other words, a plate-shaped, container-shaped, or box-shaped conductive shield member may be employed instead of the shield plate. Here, for example, when the shield member of the main control unit has a container shape or a box shape, the wiring board of the main control unit is provided along with the bottom wall in the shield member of the main control unit, The main control circuit of the main control unit is provided on the wiring board within the shield member of the main control unit. Note that such a configuration is substantially the same even when the shield member of the payout control unit, the launch control unit, or the sound / lamp control unit is in a container shape or a box shape.
[0194]
In practicing the present invention, each of the boxes 52, 62, 102, 112 may be replaced by an electrically insulating wall member corresponding to the bottom wall 52a, 62a, 102a, 112a.
[0195]
In practicing the present invention, the shield plate or the negative terminal of the secondary coil T2 of the transformer T may be grounded instead of grounding the wiring board 72 of the power supply unit 70 to ground.
[0196]
Further, in implementing the present invention, in each of the above embodiments, even if a dummy conductive shield plate is employed as the shield plate on the side where electromagnetic noise enters, the same operational effects as those of the above embodiments can be achieved.
[0197]
Further, in the implementation of the present invention, even if the player attempts to cause the main control unit to malfunction due to illegal electromagnetic noise using an electromagnetic noise source, the shielding effect against the illegal electromagnetic noise is the same as in each of the above embodiments. Can be secured.
[0198]
Further, in the practice of the present invention, the pachinko ball is not limited to being made of metal, and may be made of a conductive resin. Generally, any game ball that can be charged may be used.
[0199]
Further, in the implementation of the present invention, without being limited to pachinko machines, the present invention is applied to a slot machine or an arrangement ball machine that plays with a chargeable game medium such as a chargeable game ball or a metal coin, and the present invention is implemented. Is also good.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram showing a first embodiment of a pachinko machine according to the present invention as viewed from the back of a back-set structure.
FIG. 2 is a side view of the pachinko machine.
FIG. 3 is a partially broken enlarged view of the back set structure of FIG. 1;
FIG. 4 is a sectional view of a principal part taken along line 4-4 in FIG.
FIG. 5 is a partially cutaway enlarged view of a main control unit and a sound / lamp control unit as viewed from the back side of the control box of FIG. 1;
FIG. 6 is a cross-sectional view of a main part along line 6-6 in FIG.
FIG. 7 is an electric circuit diagram for a main control unit and a payout control unit in the first embodiment.
FIG. 8 is a rear view showing a main part of a second embodiment of the present invention.
9 is a cross-sectional view of a main part along line 9-9 in FIG.
FIG. 10 is a rear view showing a main part of a third embodiment of the present invention.
FIG. 11 is a cross-sectional view of a main part along line 11-11 in FIG. 10;
FIG. 12 is a partially broken rear view showing a main part of a fourth embodiment of the present invention.
13 is a partially cutaway sectional view taken along line 13-13 in FIG.
FIG. 14 is an electric circuit diagram showing a main part of a fifth embodiment of the present invention.
FIG. 15 is a partially broken rear view showing a main part of a sixth embodiment of the present invention.
FIG. 16 is a wiring diagram of an electric circuit system according to the sixth embodiment.
FIG. 17 is a partially broken rear view showing a main part of a seventh embodiment of the present invention.
FIG. 18 is an electric circuit diagram showing a main part of an eighth embodiment of the present invention.
FIG. 19 is an electric circuit diagram showing a main part of a ninth embodiment of the present invention.
[Explanation of symbols]
B: gaming machine body, Du: upper plate, ES: commercial power supply, Ls: wiring,
L3, L5, L8: negative power line, P: game board, T: transformer, U: back set structure,
W: annular frame, 20: set plate, 21, 91b: recess, 30: storage tank,
40a: guide gutter, 40b: guide route, 41, 42: conductive part,
50b ... payout control unit,
51, 61, 101, 101A, 101B, 111, 111A, 111B, 141, 151 ... shield plate,
52, 62, 91, 102, 112, 142, 152 ... box,
53, 63, 72, 103, 113: wiring board, 54: payout control circuit,
60a: launch control unit, 64: launch control circuit, 70: power supply unit,
73: power supply circuit, 80: game board main body, 90: control box, 91a: rear surface,
100, 100A, 100B, 140: Main control unit, 102a, 112a, 142a, 152a: Bottom wall, 104: Main control circuit
110, 110A, 110B, 150 ... Sound / lamp control unit,
114: sound / lamp control circuit, 141b, 151b: end,
170 ... Long conductive member.

Claims (11)

In a gaming machine including a plurality of control units each having a control circuit and a shield member,
A gaming machine, wherein at least two of the shield members of the plurality of control units are electrically connected to each other and can be grounded to the ground. A storage tank for storing a chargeable game medium,
A plurality of control units each having a control circuit and a shield member,
A medium passage extending from the storage tank;
A receiving tray that is communicated with the storage tank through the medium passage, and that discharges the game medium from the storage tank through the medium passage.
At least one of the storage tank and the medium passage, at least in part, in a gaming machine having a conductive portion,
A gaming machine, wherein at least one of the shield members of the plurality of control units and the conductive portion are electrically connected to each other and can be grounded to the ground. A power supply unit having a power supply circuit grounded to the ground via a commercial power supply,
3. The control unit according to claim 1, wherein each of the plurality of control units is electrically connected to the corresponding control circuit and the power supply circuit via a negative power supply line by the corresponding shield member for each control unit. The described gaming machine. The gaming machine according to claim 1, further comprising an attachment member at a predetermined position, at least two control units of the plurality of control units being attached side by side,
The at least two control units are connected to each other so as to secure the mutual electrical connection at opposing portions of the respective shield members in accordance with the attachment to the attachment member. . The gaming machine according to claim 1, further comprising an attachment member at a predetermined location, at least two control units of the plurality of control units being attached side by side,
A power supply unit having a power supply circuit grounded to the ground via a commercial power supply;
The plurality of control units, for each control unit, at the corresponding shield member, is electrically connected to the corresponding control circuit and the power supply circuit via a negative power supply line,
The at least two control units are connected to each other so as to secure the mutual electrical connection at opposing portions of the respective shield members in accordance with the attachment to the attachment member. . 2. The gaming machine according to claim 1, further comprising: a mounting member provided at a predetermined position of said plurality of control units for mounting side by side at least two of said plurality of control units; and a longitudinal conductive member provided on said mounting member. hand,
The at least two control units are connected to the conductive member so as to secure the mutual electrical connection at an end of the shield member on the conductive member side along with the mounting to the mounting member. A gaming machine characterized by the following. The gaming machine according to claim 1, further comprising, at a predetermined position, a mounting member to which at least two control units of the plurality of control units are mounted side by side, and a longitudinal conductive member provided on the mounting member,
A power supply unit having a power supply circuit grounded to the ground via a commercial power supply;
The plurality of control units, for each control unit, at the corresponding shield member, is electrically connected to the corresponding control circuit and the power supply circuit via a negative power supply line,
The at least two control units are connected to the conductive member so as to secure the mutual electrical connection at an end of the shield member on the conductive member side along with the mounting to the mounting member. A gaming machine characterized by the following. Power supply means having a game board body, a control box protruding from the back of the game board body, and a plurality of control units provided on the back of the control box, and having a groundable wiring board on the ground is provided. A game board provided in a gaming machine,
The plurality of control units, for each control unit,
A conductive shield member provided on the back of the control box, a wiring board provided in parallel on the back side of the shield member, and a control circuit provided on the wiring board,
The corresponding shield member and the control circuit are grounded to the corresponding wiring board, and the corresponding wiring board can be grounded to the wiring board of the power supply means via a negative power supply line. ,
A game board for a gaming machine, wherein at least two of the plurality of shield members are electrically connected to each other. The plurality of control units include, for each of the control units, an electrically insulating wall member attached to a back surface of the control box via the corresponding shield member. It is provided along with the corresponding shield member on the wall member,
The at least two shield members are separably connected to each other at their opposed portions along with the attachment of the corresponding wall members so as to secure the mutual electrical connection. A gaming board for a gaming machine according to claim 8. A longitudinal conductive member provided in parallel with the shield members on the same side of the at least two shield members on the back surface of the control box,
The plurality of control units include, for each of the control units, an electrically insulating wall member attached to a back surface of the control box via the corresponding shield member. It is provided along with the corresponding shield member on the wall member,
The at least two shield members are separable to the conductive member so as to secure the mutual electrical connection at each end on the conductive member side with the attachment of the corresponding wall member. The gaming board for a gaming machine according to claim 8, wherein the gaming board is connected. A control device comprising a plurality of control units and provided with a power supply means in the gaming machine,
The power supply means includes a groundable wiring board on the ground,
The plurality of control units, for each control unit,
A conductive shield member, a wiring board provided in parallel with the shield member, and a control circuit provided on the wiring board,
The corresponding shield member and the control circuit are grounded to the corresponding wiring board by the control circuit, and the corresponding wiring board can be grounded to the wiring board of the power supply means via a negative power supply line,
A gaming machine control device wherein at least two of the shield members are electrically connected to each other.

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