JP3583855B2 - Electrostatic shield structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a static electricity preventive structure in which appearance of a cabinet is not deteriorated, and in which installation workability is favorable. SOLUTION: A cabinet 1 is provided with a changing switch 6 inside, and an operation button 3 to operate the changing switch 6. For a conductive piece 4 disposed between the changing switch 6 and the inside of the cabinet 1, one end part of it is fixed to the cabinet 1, and it is provided with an elastic piece 40 connected to the operation button 3, and a contact piece 41 formed continuous with a tip part of the elastic piece 40 and curved as its swollen side directed toward a shield plate 2 as a grounding body. By flexure deformation of the elastic piece 40 by push pressure of the operation button 3, the contact piece 41 slides as it is in contact with the shield plate 2 under pressure.

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electrostatic shield structure for protecting an operation changeover switch in a cabinet from external static electricity in a magnetic recording and reproducing apparatus such as a video camera.
[0002]
[Prior art]
In a magnetic recording / reproducing apparatus such as a video camera, as shown in FIG. 10, operation buttons (3) and (3) corresponding to operation modes such as recording / reproduction are provided on a cabinet (1) so as to be freely retractable. A changeover switch (6) operated by each operation button (3) is provided in the cabinet (1).
However, static electricity may enter the cabinet (1) from the outside of the cabinet (1) through the gap between the operation button (3) and the cabinet (1). This static electricity is often generated from the user's fingertip, but the static electricity may cause the changeover switch (6) to malfunction.
Therefore, various types of electrostatic shield structures for protecting the changeover switch (6) from static electricity have been conventionally proposed, for example, those shown in FIGS.
[0003]
In FIG. 8, a rib (10) is provided inside the cabinet (1), and a changeover switch (6) is mounted on the relay board (60) on the rib (10). One end of a conductive plate (8) that is elastically deformable and extends so as to cover the changeover switch (6) is fixed to the inner surface of the outer wall of the cabinet (1), and the conductive plate (8) corresponding to the changeover switch (6) is fixed. The operation button (3) is arranged at the upper position. The upper end of the operation button (3) projects to the upper surface of the cabinet (1) so as to be able to protrude and retract from an opening (12) opened in the cabinet (1).
The other end of the conductive plate (8) is screwed to a positioning boss (11) projecting from a rib (10) together with a metal plate chassis (7) of a well-known mechanism deck for recording and reproducing via a magnetic tape. It is fixed at. The screw (14) is screwed into the positioning boss (11) through a window (13) opened in the cabinet (1).
[0004]
The static electricity that has entered the inside of the cabinet (1) through the gap between the opening (12) and the operation button (3) flows through the conductive plate (8) and flows to the chassis (7). The chassis (7) is a grounding body for static electricity. When the conductive plate (8) is grounded to the chassis (7), static electricity does not reach the changeover switch (6), and malfunction of the changeover switch (6) is prevented. Have been. If the chassis (7) and the conductive plate (8) cannot be screwed in due to the arrangement of the mechanism deck and the operation buttons (3), the conductive plate (8) and the chassis (7) are mounted as shown in FIG. And the electric wire (9) to protect the changeover switch (6) from static electricity. This is because the chassis (7) and the conductive plate (8) are connected in advance by an electric wire (9), and the electric wire (9) is stored between the cabinet (1) and the chassis (7) while the chassis (7) is housed. In the cabinet (1).
[0005]
[Problems to be solved by the invention]
In the antistatic structure shown in FIG. 8, since the window (13) is opened on the cabinet (1), the appearance may be impaired in the design of the external appearance. Further, the conductive plate (8) is corroded due to long-term use, the contact resistance with the chassis (7) is increased, and the conduction between the conductive plate (8) and the chassis (7) may be deteriorated. .
Further, as shown in FIG. 9, when the conductive plate (8) and the chassis (7) are connected by the electric wire (9), the electric wire (9) is stored between the cabinet (1) and the chassis (7). The work of mounting the chassis (7) in the cabinet (1) is complicated.
SUMMARY OF THE INVENTION An object of the present invention is to provide an antistatic structure which does not impair the aesthetics of a cabinet, has good mounting workability, and prevents deterioration of conduction with a grounding body.
[0006]
[Means for solving the problem]
An operation button (3) for operating the changeover switch (6) is provided on the cabinet (1) having a changeover switch (6) therein so as to be freely retractable. A conductive plate disposed between the changeover switch (6) and the inside of the cabinet (1) and connected to a grounding body in the cabinet (1) includes an elastic piece (40) having one end fixed to the cabinet (1). ) And a contact piece (41) formed at the tip of the elastic piece (40) and curved toward the grounding body. The operation button (3) is attached to the elastic piece (40), and the contact piece (41) slides while pressing against the grounding body with the bending deformation of the elastic piece (40) due to the pressing of the operation button (3). The contact piece (41) has a different portion in contact with the grounding body before and when the operation button ( 3 ) is pressed.
[0007]
[Action and effect]
The ground connection of the conductive member to the grounding body can be performed by simply bringing the conductive member mounted in the cabinet (1) into contact with the grounding body when mounting the grounding body in the cabinet (1). Therefore, mounting workability is improved as compared with the conventional configuration in which the cabinet (1) and the grounding body are connected by the conductive plate (8) or the electric wire (9).
In addition, there is no need to open a window (13) in the cabinet (1) for mounting the conductive piece (4), and the appearance of the cabinet (1) is not spoiled.
Further, with the pressing of the operation button (3), the contact piece (41) slides while pressing on the grounding body, that is, the contacting piece (41) slides while generating friction with the grounding body. Therefore, even if the contact portion between the contact piece (41) and the grounding body is corroded at first, the corroded portion is peeled off by friction. Therefore, deterioration of conduction of the conductive member due to corrosion can be prevented, and the changeover switch (6) is reliably protected.
[0008]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an example of the present invention will be described in detail with reference to the drawings. Note that the same reference numerals are used for the same configurations as those in the related art.
As shown in FIG. 1, inside the cabinet (1), a circuit board (5) having a shield plate (2) on the upper surface and a phosphor bronze or the like facing the upper surface of the shield plate (2). A conductive piece (4) is provided. The circuit board (5) is grounded to the mechanism deck.
The shield plate (2) is formed by bending a tin plate or the like to prevent high frequency noise from jumping into the circuit board (5), and is a grounding body that comes into contact with the conductive piece (4) as described later. . In this example, the shield plate (2) is used as a grounding body in accordance with the content that the applicant is considering implementing. However, as in the conventional case, the grounding body is required for the chassis (7) of the mechanism deck. Is also good.
[0009]
One end of the conductive piece (4) is fixed to the inside of the cabinet (1), and the elastic piece (40) having the operation button (3) mounted on the upper surface; And a contact piece (41) curved toward the shield plate (2). The lower end of the contact piece (41) is in contact with the upper surface of the shield plate (2).
An operation button (3) is attached to a central portion in the longitudinal direction of the elastic piece (40), and an upper end of the operation button (3) is freely exposed and retracted through an opening (12) opened in the cabinet (1). Put out. On the circuit board (5), on a transition path of the operation button (3), a changeover switch (6) pushed by the operation button (3) is provided. The changeover switch (6) is for switching the running mode of the mechanism deck, as in the prior art, and is turned on when pushed.
[0010]
To bring the conductive piece (4) into contact with the shield plate (2), the conductive piece (4) is mounted in the cabinet (1) in advance, and the circuit board (5) is mounted in the cabinet (1) in this state. I do. The contact piece (41) of the conductive piece (4) is pressed against the upper surface of the shield plate (2) by the elastic force of the elastic piece (40), so that the conductive piece (4) and the shield plate (2) are electrically connected. Connected to.
When a user's finger touches the operation button (3), a minute level of static electricity may enter the cabinet (1) from a gap between the opening (12) of the cabinet (1) and the operation button (3). . In this case, the static electricity flows through the conductive piece (4) and flows to the shield plate (2). The changeover switch (6) is not affected by static electricity, and the malfunction of the changeover switch (6) is prevented.
[0011]
As shown in FIG. 3, when the user pushes the operation button (3) into the cabinet (1), the elastic piece (40) rotates clockwise around the fixing portion with the inner surface of the cabinet (1), and the contact is made. The piece (41) is further pressed against the shield plate (2). At this time, as shown in an enlarged manner in FIG. 2B, the contact portion between the contact piece (41) and the shield plate (2) is shifted from the initial contact position b to a position a on the contact piece (41). That is, the contact piece (41) rotates counterclockwise from the state shown in FIG. 2A while pressing against the shield plate (2) with the bending deformation of the elastic piece (40).
[0012]
Since the conductive piece (4) is formed of phosphor bronze, the surface may corrode for a long period of time to form patina. In this case, the contact resistance with the shield plate (2) increases, and the static electricity transmitted through the conductive piece (4) is not completely transmitted to the shield plate (2). (6) may not be sufficiently protected.
In the conductive piece (4) of the present embodiment, the contact piece (41) slides with friction between the shield and the shield plate (2) with the pressing of the operation button (3). Even if the contact portion between 41) and the shield plate (2) is corroded, the corroded portion is peeled off by friction. Accordingly, the contact resistance between the shield plate (2) and the conductive piece (4) does not increase, and deterioration of conduction of the conductive piece (4) is prevented.
[0013]
In this example, the circuit board (5) is mounted in the cabinet (1), and the conductive piece (4) mounted in the cabinet (1) is brought into contact with the shield plate (2). Since the static electricity jumping toward the housing can be shielded, the mounting workability is better than that of the conventional case where the cabinet (1) and the grounding body are connected by the conductive plate (8) or the electric wire (9).
In addition, there is no need to open a window (13) in the cabinet (1) for mounting the conductive piece (4), and the appearance of the cabinet (1) is not spoiled.
[0014]
FIG. 4 is a diagram showing another example of the conductive piece (4). The contact piece (41) faces the side surface of the shield plate (2), and the operation button (3) is mounted on the elastic piece (40). When the operation button (3) is pressed, the contact portion of the contact piece (41) with the shield plate (2) moves from position b to position a (see FIGS. 5A and 5B). Thereby, even if the initial contact portion between the contact piece (41) and the shield plate (2) is corroded, the corroded portion is peeled off by friction.
As shown in FIGS. 7 and 8, the conductive piece (4) may be T-shaped, and may have two contact pieces (41) (41) at both ends. In this case, as the operation button (3) is pressed, each contact piece (41) comes into press contact with the corresponding shield plate (2).
[0015]
The description of the above embodiments is intended to explain the present invention, and should not be construed as limiting the invention described in the claims or reducing the scope thereof. Further, the configuration of each part of the present invention is not limited to the above-described embodiment, and it is needless to say that various modifications can be made within the technical scope described in the claims.
For example, in this embodiment, the shield plate (2) is made of a tin material, but may be made of another material having good conductivity.
[Brief description of the drawings]
FIG. 1 is a side view in which a part of a cabinet is cut away.
2A is an enlarged view of a contact piece in a state where an operation button is not operated, and FIG. 2B is an enlarged view of a contact piece in a state where an operation button is pressed.
FIG. 3 is a side view showing a state in which an operation button is pushed in with a part of a cabinet cut away.
FIG. 4 is a side view showing a conductive piece in another example with a cabinet cut away.
5A is an enlarged view of the contact piece in a state where the operation button in FIG. 4 is not operated, and FIG. 5B is an enlarged view of the contact piece in a state where the operation button is pressed.
FIG. 6 is a plan view of a conductive piece in another example.
FIG. 7 is a side view showing the conductive piece of FIG. 6 by breaking a cabinet.
FIG. 8 is a side view showing a conventional electrostatic shield structure with a part of a cabinet cut away.
FIG. 9 is a side view showing another conventional electrostatic shield structure in which a part of a cabinet is cut away.
FIG. 10 is a perspective view of a cabinet.
[Explanation of symbols]
(1) Cabinet (3) Operation button (6) Changeover switch (40) Elastic piece (41) Contact piece

Claims (1)

An operation button (3) for operating the changeover switch (6) is provided on the cabinet (1) provided with a changeover switch (6) therein so as to be able to come and go from the cabinet (1), and the changeover switch (6) and the cabinet (1) are provided. ) A conductive plate arranged between the inside and the inside is connected to a grounding body provided in the cabinet (1) to protect the changeover switch (6) from static electricity entering from the outside of the cabinet (1). In the electric shield structure,
The conductive plate is composed of an elastic piece (40) having one end fixed to the cabinet (1) and a contact piece (41) formed at the tip of the elastic piece (40) and curved toward the ground. The operation button (3) is attached to the elastic piece (40), and the contact piece (41) is pressed against the ground body with the bending deformation of the elastic piece (40) due to the pressing of the operation button (3). An electrostatic shield structure characterized in that the contact piece (41) slides and the contact portion of the contact piece (41) with the grounding body before and after the operation button ( 3 ) is pressed is different .

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