JP2582086Y2 - Shield structure of CRT display device - Google Patents

Description

[Detailed description of the invention]

[0001]

The present invention relates to a CRT (cathode ray)
The present invention relates to a shield structure of a display device, and more specifically, to a shield structure for reducing a leakage electric field from a CRT display device.

[0002]

2. Description of the Related Art FIG. 6 is an explanatory diagram for explaining a state in which an electric field is generated. (61) is a power source of P (v),
(62) and (63) are plate-shaped conductors connected to both poles of the power supply (61). In this case, the conductors (62), (6)
The electric field E generated during 3) is due to both conductors (62),
It is calculated from the potential difference P (V) between (63) and the distance d (m) (electric field E (v / m) = P / d (Equation 1)).

Here, when the power supply (61) fluctuates with time, the electric field E also changes with time. The electric field at this time is called an alternating electric field. The process of generating an alternating electric field in a CRT display device can be classified into the following three cases.

[0004] When the problem occurs due to a power supply circuit and a power supply cable of the CRT display device. In this case, the frequency of the alternating electric field is 50/60 Hz. If a switching power supply is used in the power supply circuit, the frequency includes 20 to 100 KHz.

[0005] When it is caused by a circuit for deflecting an electron beam in a CRT in a vertical direction. In this case, 50 ~
An alternating electric field of 120 Hz is generated.

[0006] When it is caused by a horizontal deflection circuit or a circuit that generates a voltage necessary for performing scanning. The alternating electric field frequency at this time is 2 KHz to 400 KHz.

In recent years, attention has been paid to the influence of the alternating electric field (which is a so-called leakage electromagnetic field) on the body of people working in connection with a VDT (visual display terminal) or the like. That is, when the conductors (62) and (63) are replaced with an electric field source and a human body, the distance d between the electric field source and the human body
(M) and the electric field E (v / m) due to the voltage P (v) affect the human body. In Sweden, 1990
In 2015, the standard for leakage electromagnetic fields (MPR-II) was enacted, and this movement has spread worldwide.

This standard is based on the BANDI
(5KHz to 2KHz) and BANDII (2KHz to 40KHz)
0 KHz). Where BAND
The electric field in the frequency band corresponding to II is mainly generated by the switching power supply, the horizontal deflection circuit, and the high voltage generation circuit as described above. Since these circuits generate a high voltage in circuit operation, the voltage p (V) becomes a relatively large value with respect to the distance d (m) to the human body, and the electric field is generated even when the VDT is relatively far from the human body. The effect of E (v / m) on the human body cannot be ignored.

Conventionally, a method as shown in FIG. 7 has been employed to reduce such a leakage electric field. FIG. 7 is an external view showing a shield structure of a conventional CRT display device. (71), (72), (73), and (74) denote grounding (GND) and deflection circuits of a CRT by using a conductive metal plate. , Is connected to the ground via a power cord of an AC mains power supply, and shields the leaked electric field from the left, right side, back and top surfaces of the CRT display device. The metal plate (71) is usually provided with a small hole in a punching shape in order to consider the heat radiation inside the device.

As described above, when the entire rear portion of the apparatus is shielded by the metal plate connected to the ground, the electric field outside the apparatus is not generated by the voltage generated by the horizontal deflection circuit and the high voltage generation circuit, but by the metal plate (71). ), (72), (73),
It occurs between the voltage applied to (74) and
Since the potential of the metal plate (71) and the like is ground, the leakage electric field to the outside of the device can be greatly reduced as a result.

[0011]

The method of shielding the entire rear portion of the apparatus with a metal plate as described above is effective against a leaked electric field, but has a disadvantage that the weight of the apparatus is greatly increased by the metal plate. . In addition, since the set cannot be repaired without removing the metal plate, there is a problem in terms of serviceability.

SUMMARY OF THE INVENTION The present invention has been made in view of such circumstances, and has as its object to realize a shield structure of a CRT display device that is lightweight and has good serviceability.

[0013]

SUMMARY OF THE INVENTION A shield structure of a CRT display device according to the present invention is a shield structure of a CRT display device for reducing a leakage electric field radiated from the CRT display device.
A deflection yoke attached to the periphery of the neck, a strip-shaped conductive band formed to have a width substantially equal to the side width L of the deflection yoke, and a chassis frame grounded to ground. The deflection yoke is attached to the chassis frame at a position that covers the side surface of the deflection yoke when viewed from the left or right side surface or the upper surface of the CRT display device.

[0014]

Since the voltage generating circuit has a structure in which the voltage generating circuit is locally shielded by the conductive belt, the CRT display device can be lightly shielded, and the serviceability can be improved.

[0015]

1 is an external view showing an embodiment of a shield structure of a CRT display device according to the present invention. In the figure,
(1) is a CRT, (2) is DY (deflection yoke: deflecti)
(3) is a strip-shaped conductive sheet for preventing a leaked electric field, (5) is a strip-shaped metal plate for preventing a leaked electric field, and the widths of (3) and (5) are the left side surfaces in FIG. As shown in the drawing, the width is substantially the same as the width (L) of DY (2). (6), (7) and (8) are chassis frames,
(9) is a ground lead included in the power cord,
The ground lead (9) is electrically connected to the chassis frame (8). Also, the chassis frame (6),
Since (7) is electrically connected to the chassis frame (8), the chassis frames (6) and (7) are also grounded via the ground lead wire (9). Although not shown, the secondary-side ground foil of the printed circuit board (circuit board) is electrically connected to the chassis frames (6), (7), (8), and the secondary-side ground foil is a ground lead. Grounded via line (9).

The strip-shaped conductive sheet (3) has a structure as shown in FIG. In the figure, reference numeral (31) denotes an electrically insulating sheet such as polycarbonate, and a metal foil (32) described later.
And a part of DY (2) to prevent electrical contact. (32) is a metal foil, and the metal foil (32) is preferably an aluminum foil (AL) in order to reduce the magnetic influence on the DY (2). Reference numeral (33) denotes a hole for attaching the conductive sheet (3) with screws or the like. When the conductive sheet (3) is attached, the metal foil (32) and the screws are electrically connected to each other.

The mounting of the conductive sheet (3) is performed as shown in FIGS. 5 (A) and 5 (B). That is,
The conductive sheet (3) is sandwiched between the chassis frame (6) and the metal plate (5), and is attached by a conductive screw (10) so as to be electrically connected to each other. The conductive sheet (3) is attached at a position that covers the DY (2) body as viewed from the side as shown in the left side view of FIG. 4, and the metal plate (5) is perpendicular to the DY (2). DY when viewed from the bottom right below
(2) Attach to the position where the main body is covered.

Since the grounded conductive sheet (3) and the metal plate (5) are arranged so as to surround the outer periphery of the DY (2), the electric field leaking from the DY (2) can be extremely reduced. Can be reduced to a small value. However, it is not necessary to attach the conductive sheet (3) and the metal plate (5) at the same time, and the object can be achieved by only one of them according to the level of the leakage electric field.

FIG. 2 is an external view showing another embodiment of the shield structure of the invented CRT display device. In the figure, (4) is a strip-shaped metal plate also serving as a chassis for preventing a leakage electric field, and its width is substantially the same as the width of DY (2). The leak electric field can be reduced by attaching to a similar position.

Further, even if a flat cable is used instead of the conductive sheet (3) or the metal plate (4), the leakage electric field can be reduced. According to the flat cable,
It is also possible to adopt a structure in which it is mounted on a printed circuit board with a connector or the like, and it is possible to more easily reduce the leakage electric field. In this case, the connector may be connected to a ground foil.

If necessary, a conductive sheet (3) may be provided around the flyback transformer (FBT).
It is possible to shield the leakage electric field at a higher level.

The distance between the anode terminal of the CRT and the ground is 3
By adding a capacitor of about 000 (PF), it is possible to reduce the leaked electric field especially on the CRT tube side, and it is possible to further reduce the leaked electric field by adopting a combination if necessary. It is.

[0023]

[Table 1]

Table 1 shows the leakage electric field data of the 14-inch CRT display device.
90 ° shows the measurement data on the flyback transformer side (left side direction), 180 ° shows the measurement data on the CRT neck side (back side direction), and 270 ° shows the power supply side (right side direction). . Thus, by implementing the shield structure of the CRT display device of the present invention, the level of the leaked electric field can be set within the MPR-II standard (2.5 (v / m)).

In this embodiment, the shield structure has been described by taking DY as an example of the source of the leakage electric field.
Other sources of the leakage electric field, for example, a switching power supply, a flyback transformer (FBT), and the like can be shielded by the same concept.

Since the present invention is configured as described above, the leakage electric field can be reduced, and in particular, D which is a source of the leakage electric field in the BANDII frequency band of the MPR-II standard.
A shield such as Y can be enabled.

Further, since the structure is such that the shield is locally formed, the air permeability is good, the temperature rise in the device can be reduced, and the reliability of the circuit components can be improved.

[0028]

According to the shield structure of the CRT display device of the present invention, the shield structure of the CRT display device which is lightweight and has good serviceability can be realized.

[Brief description of the drawings]

FIG. 1 is an external view showing an embodiment of a shield structure of a CRT display device of the present invention.

FIG. 2 is an external view showing another embodiment of the shield structure of the CRT display device of the present invention.

FIG. 3 is an overall configuration diagram of a conductive sheet (3).

FIG. 4 is a left side view of the shield structure of the CRT display device of the present invention.

FIG. 5 is an explanatory view of a mounting structure of a conductive sheet (3).

FIG. 6 is an explanatory diagram for explaining generation of an electric field E.

FIG. 7 is an external view of a shield structure of a conventional CRT display device.

[Description of Signs] 1 CRT 2 DY 3 Conductive sheet 4 Metal plate 5 Metal plate 6 Chassis frame 7 Chassis frame 8 Chassis frame 9 Ground lead wire 10 Conductive screw 31 Electrical insulating sheet 32 Metal foil 33 Mounting hole 61 Power supply 62 conductor 63 conductor

Claims (1)

(57) [Scope of request for utility model registration] A shield structure of a CRT display device for reducing a leakage electric field radiated from the CRT display device , wherein the shield structure is attached to a CRT and a portion around a neck of the CRT.
Deflection yoke and a width substantially equal to the side width L of the deflection yoke.
The formed strip-shaped conductive strip and the grounded ground
And a conductive frame, the conductive yoke being connected to the deflection yoke.
Outer periphery of the left and right sides of the CRT display device
Or at a position covering the side surface of the deflection yoke as viewed from above.
CRT mounted on a chassis frame
Display device shield structure.