KR20050027826A - Electromagnetic waves reducing method and electromagnetic waves reducing apparatus - Google Patents

Abstract

A method for attenuating electromagnetic waves and an electromagnetic wave attenuating device are provided to reduce an amount of pass of electromagnetic waves without reducing the size of a pierced hole, thereby increasing an SAR(Specific Absorption Rate) while reducing a manufacturing cost by relatively simplifying a processing step during a burring operation. A passing path(t+h) of electromagnetic waves passing through a pierced hole(1a) is extended by making thickness around the pierced hole(1a) larger as much as height(h) while including thickness(t) of an electromagnetic wave shielding plate(1), in order to increase an SAR of the electromagnetic waves absorbed into the electromagnetic wave shielding plate(1) while passing through the pierced hole(1a) even though size of the pierced hole(1a) is not reduced.

Description

Electromagnetic Wave Reduction Method and Electromagnetic Wave Reduction Apparatus

The present invention relates to an electromagnetic wave attenuation method and an electromagnetic wave attenuation device, and more particularly, to an electromagnetic wave attenuation method and an electromagnetic wave attenuation device that can be applied even when the area of the through hole through which electromagnetic waves pass cannot be reduced.

In general, electromagnetic waves generated from various electronic devices such as computers, monitors, and various motors generate deadly electromagnetic waves that may interfere with normal functions of other electronic devices.

Accordingly, various electronic devices used in homes and businesses are subject to the electromagnetic wave regulation legislation, certification bodies, and certification systems that can be applied to all electronic devices worldwide so that electromagnetic waves generated from such electronic devices do not interfere with other electronic devices. Is being applied.

Meanwhile, with the recent reports of adverse effects or damages to the human body, consumers' interest in electromagnetic waves is increasing. Recently, the electromagnetic wave attenuation problem of electronic product manufacturers in Korea and around the world is an important task due to the high performance of electronic products. It is emerging.

At this point, the conventional method for attenuating electromagnetic waves is very simple. As shown in FIG. 1, the electromagnetic wave generation source has a predetermined diameter (t) to prevent electromagnetic waves from passing through by absorbing the electromagnetic wave λ into a structure made of a conductive material. In order to reduce the material cost of the blocking plate 1, a through hole 1a through which a small amount of electromagnetic waves λ can pass through the blocking plate 1 is provided in the blocking plate 1 so as to reduce the material cost of the blocking plate 1. It is a method of forming a plurality.

In this case, the through hole 1a is generated inside the electronic product because the electromagnetic wave generation source that the blocking plate 1 surrounds is a heating source of the electronic product, in addition to the purpose of reducing the material cost of the blocking plate 1. In some cases, the object of the present invention is to replace the role of the vent so that heat is easily released to the outside.

Therefore, in the manufacture of electronic products, the diameter d of the through hole 1a is determined in consideration of the electromagnetic wave allowance, the air flow rate, the material cost, the characteristics of the product, the structure of the blocking plate, and the like. .

However, in the case where the diameter d of the through hole 1a can no longer be reduced by design, i.e., in the case of many electronic products employing a natural air-cooled cooling method instead of a noiseless computer or a separate forced cooling method, the minimum ventilation holes In order to ensure the capacity, the diameter d of the through hole 1a can no longer be increased due to the additional leakage of electromagnetic waves, and the amount of passage of the electromagnetic waves can no longer be increased. There was a problem that could not be reduced.

That is, in the conventional electromagnetic wave attenuation method, since there is no other method that can reduce the amount of passage of electromagnetic waves other than reducing the diameter (area) of the through hole 1a, the airflow is increased or a new wire is applied to the blocking plate 1. It was difficult to form a new through hole, there was a problem that causes a lot of restrictions in design.

In addition, in the conventional electromagnetic wave attenuation method, since the thickness t of the blocking plate 1 is relatively thin, when the path of the electromagnetic wave λ passing through the through hole 1a is short, that is, the larger the corner angle, the more severely generated wavelength Due to the diffraction phenomenon, the electromagnetic wave λ passing through the through hole 1a is diffracted and spreads widely, causing interference and the like, and this frequency interference causes more influence on other electronic products.

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems is to provide an electromagnetic wave attenuation method and an electromagnetic wave attenuation apparatus that can increase the electromagnetic wave absorption rate by reducing the amount of electromagnetic wave passing through without reducing the diameter (area) of the through hole.

In addition, another object of the present invention, in the case of the burring operation during the penetration of the through-hole, the manufacturing process is relatively simple to reduce the manufacturing cost, when adding a separate plate, it is applied to the existing through-hole The present invention provides an electromagnetic wave attenuation method and an electromagnetic wave attenuation device that can further attenuate electromagnetic waves.

In addition, another object of the present invention, the electromagnetic wave attenuation method and the electromagnetic wave to control the electromagnetic wave direction by preventing the diffraction phenomenon of the electromagnetic wave due to the long passage path of the electromagnetic wave, and to reduce the influence on the electronic product by reducing the electromagnetic interference phenomenon An attenuation device is provided.

In the electromagnetic wave damping method of the present invention for achieving the above object, in the electromagnetic wave damping method of the electromagnetic wave shielding plate having a through hole penetrating a predetermined area such as a wire through hole or a ventilation window through which electromagnetic waves can leak, the area of the through hole is reduced. The thickness of the periphery of the through hole of the electromagnetic wave blocking plate is increased so as to increase the absorption rate of the electromagnetic wave absorbed by the electromagnetic wave blocking plate while passing through the through hole. do.

On the other hand, the electromagnetic wave attenuating device of the present invention for achieving the above object, in the electromagnetic wave attenuating device of the electromagnetic wave shielding plate having a through hole penetrating a predetermined area such as a wire through hole or a ventilation window through which electromagnetic waves can leak, the area of the through hole Even if not reduced, the bending of the blocking plate around the through hole in order to increase the thickness of the around the through hole of the electromagnetic wave blocking plate to increase the absorption rate of the electromagnetic wave absorbed by the electromagnetic wave blocking plate while passing through the burring (Burring) It is characterized in that it comprises a processed stepped portion.

In addition, the electromagnetic wave attenuating device of the present invention for achieving the above object, in the electromagnetic wave attenuating device of the electromagnetic wave shielding plate having a through hole penetrating a predetermined area such as a wire through hole or a ventilation window through which electromagnetic waves can leak, the area of the through hole It is installed around the through hole to thicken the thickness around the through hole of the electromagnetic wave blocking plate so as to increase the absorption rate of the electromagnetic wave absorbed by the electromagnetic wave blocking plate while passing through the through hole, Is connected to, characterized in that it comprises a cover plate of a shape corresponding to the through-hole.

In addition, the cover plate is welded or screwed to the blocking plate so that it can be electrically connected, and the height (thickness) is formed to be higher (thick) as the amount of electromagnetic wave is increased according to the allowance of electromagnetic waves or the area and shape of the through hole. It is desirable to.

Hereinafter, an electromagnetic wave damping method and an electromagnetic wave damping apparatus according to various embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, as shown in FIGS. 2 and 3, the electromagnetic wave attenuation method of the present invention includes an electromagnetic wave shielding plate having a through hole 1a penetrated to a predetermined area such as a wire through hole or a ventilation window through which an electromagnetic wave λ may leak. An electromagnetic wave attenuation method according to (1), wherein the absorption rate of the electromagnetic wave λ absorbed by the electromagnetic wave blocking plate 1 is increased while passing through the through hole 1a without reducing the area of the through hole 1a. The passage path t + h of the electromagnetic wave λ passing through the through hole 1a is increased by increasing the thickness around the through hole 1a by the height h, including the thickness t of the electromagnetic wave shielding plate 1. Is long.

That is, in the preferred embodiment of the electromagnetic wave damping apparatus manufactured according to the electromagnetic wave damping method of the present invention, as shown in FIG. 2, the through hole 1a is not reduced even if the area of the through hole 1a is not reduced. To thicken the thickness t around the through hole 1a of the electromagnetic wave blocking plate 1 to (t + h) so as to increase the absorption rate of the electromagnetic wave λ absorbed by the electromagnetic wave blocking plate 1 while passing. And a stepped portion 2 made of the same conductive material as that of the blocking plate 1 which is bent by the height h by bending the blocking plate 1 around the through hole 1a.

This burring process (processing to protrude through the periphery of the through hole) is a mold having a space (cavity) in which the stepped portion 2 can be bent during the punching operation of forming the through hole 1a in the blocking plate 1. As the stepped portion 2 is formed by pressing on the surface, the drilling time and cost can be greatly reduced because it is made simultaneously with the drilling.

Therefore, as shown in FIG. 2, the electromagnetic wave λ is absorbed by the inner diameter surface of the stepped portion 2 while passing through the through hole 1a, thereby reducing the amount of passage of the electromagnetic wave λ, Even in the case of the electromagnetic wave λ, the corner angle is increased to reduce the diffraction rate, thereby minimizing the interference caused by the disturbance of the electromagnetic wave.

On the other hand, the electromagnetic wave damping device according to another embodiment of the present invention, as shown in Figure 3, the electromagnetic wave blocking plate (1) to increase the absorption rate of the electromagnetic wave (λ) absorbed by the electromagnetic wave blocking plate (1) In order to thicken the thickness t of the periphery of the through hole 1a to (t + h), it is installed around the through hole 1a and electrically connected to the blocking plate 1, and the through hole 1a It comprises a plate 3 of the shape corresponding to).

That is, the cover plate 3 is attached to the through hole 1a that requires electromagnetic wave attenuation, and is closely attached to the blocking plate 1 so as to be electrically connected by welding or screwing and passing through the electromagnetic wave λ. According to the allowable value or the area and shape of the through hole 1a, the height h (thickness) is increased (thick) as the amount of electromagnetic wave is increased.

Therefore, as shown in FIG. 3, while the electromagnetic wave λ passes through the through hole 1a, the electromagnetic wave λ is absorbed by the inner diameter surface of the plate 3 to reduce the amount of passage of the electromagnetic wave λ, and the cover plate The electromagnetic wave absorbed by (3) can be transmitted to the fraud blocking plate 1 again and grounded, and even the passed electromagnetic wave (λ) increases the corner angle to reduce the diffraction rate, thereby minimizing interference due to electromagnetic disturbance. It is.

The electromagnetic wave attenuation method and the electromagnetic wave attenuation apparatus of the present invention can be applied to all of the through holes 1a of various forms. As an example, as shown in FIG. 4, the electromagnetic wave shield plate 1 is The heat dissipation case 10 of the completely noiseless computer capable of heat dissipation to naturally discharge heat generated from the inside to the outside, and as shown in FIG. 5, the through hole 1a is the heat dissipation case 10. It is installed in the vortex groove (10a) that can play a role of ventilation and at the same time can play a role of fixing the wire in the vortex shape from the outside to the center, as shown in Figure 6, the cover plate (3), A vortex groove 30a having a shape corresponding to the vortex groove 10a is formed, and is electrically screwed with the heat dissipating case 10 to absorb the electromagnetic wave, and is predetermined in consideration of the electromagnetic wave absorption rate. That the spiral deotpan 30 formed to a (t) are possible.

At this time, the cover plate 3 has a shape corresponding to the through-hole 1a, the screw hole 30b is formed for electrical contact, and is installed inside the heat dissipation case 10 so as not to be exposed to the outside aesthetically. It is added in the form of reinforcing the existing through-hole (1a) so as not to exceed the allowable electromagnetic wave.

Therefore, as shown in FIG. 5, the blocking plate 1 has a width (a) of 400 mm as a whole, and is formed in the vortex groove (10a) is formed on the left and right edges spaced apart by a 40 mm interval (b), respectively. When the plate of the present invention is not attached, the graph showing the amount of electromagnetic waves emitted according to the frequency measured in the electromagnetic wave measuring room in which the four sides are sealed and the plurality of electromagnetic wave sensors are installed in various directions, as shown in FIG. Although the highest value of the irregular waveform exceeds the allowable value (a thick line in the center starting at the value 40 of the level), the circumferential groove 10a of the blocking plate 1 shown in FIG. 6, the inlet width s of the vortex groove 30a of FIG. 6 is 7.5 mm, the wound vortex width l is 4 mm, and the total length w is 161 mm so as to correspond to the vortex groove 10a. 4, the thickness (t In the case where a plate having a height of 15 mm is attached, the graph showing the amount of emitted electromagnetic waves according to the frequencies measured in the same electromagnetic wave measuring room is the maximum value of the irregular waveform representing the amount of emitted electromagnetic waves as shown in FIG. 8. It is possible to obtain a remarkable electromagnetic wave attenuation effect since the electromagnetic wave emission value is low as a whole without exceeding the center thick line starting at 40).

In addition, the electromagnetic wave attenuation method and the electromagnetic wave attenuation apparatus of the present invention can be applied to through holes of various forms and types that may be outlets of electromagnetic waves, and the present invention is not limited to the above-described embodiments. It is a matter of course that modifications can be made by those skilled in the art within a range that does not harm.

For example, in the embodiment of the present invention shown in the drawings, the through hole is limited to being applied to the vortex groove, etc. In addition, it is possible to be applied to various vents or wire through holes.

Therefore, the scope of the claims in the present invention will not be defined within the scope of the detailed description, but will be defined by the following claims and the technical spirit thereof.

As described above, according to the electromagnetic wave attenuation method and the electromagnetic wave attenuation apparatus of the present invention, the electromagnetic wave absorption rate can be increased by reducing the amount of electromagnetic wave passing through without reducing the diameter (area) of the through hole, and a burring operation is performed during the penetration of the through hole. In this case, the manufacturing process is relatively simple, which can reduce the manufacturing cost, and if a separate plate is added, it can be applied to the existing through hole to further attenuate the electromagnetic wave, and the passage path of the electromagnetic wave is long, resulting in the diffraction phenomenon of the electromagnetic wave. By controlling the direction of electromagnetic wave influence by blocking, it is possible to reduce the effect on electronic products.

1 is a conceptual diagram illustrating a conventional electromagnetic wave attenuation method.

2 is a conceptual diagram illustrating an electromagnetic wave attenuation method and an electromagnetic wave attenuation device according to an exemplary embodiment of the present invention.

3 is a conceptual diagram illustrating an electromagnetic wave attenuation method and an electromagnetic wave attenuation device according to another exemplary embodiment of the present invention.

4 is a use state diagram illustrating a state in which the electromagnetic wave attenuating device of FIG. 3 is installed in upper and lower plate through holes of a noiseless computer case.

FIG. 5 is a diagram illustrating an example of an upper (lower) plate of the noiseless computer case of FIG. 4.

6 is a diagram illustrating an example of the plate of FIG. 4.

FIG. 7 is a graph showing the amount of electromagnetic waves emitted according to a frequency measured in an electromagnetic wave measuring room when the plate of FIG. 4 is not attached, that is, in the conventional case.

8 is a graph showing the amount of electromagnetic radiation emitted according to the frequency measured in the electromagnetic wave measuring room when the plate is attached to the through hole of FIG.

Claims (5)

In the electromagnetic wave damping method of the electromagnetic wave shielding plate having a through hole penetrating a predetermined area such as a wire through hole or a ventilation window through which electromagnetic waves can leak, Even if the area of the through hole is not reduced, the passage path of the electromagnetic wave passing through the through hole is made thick by increasing the thickness around the through hole of the electromagnetic wave blocking plate so as to increase the absorption rate of the electromagnetic wave absorbed by the electromagnetic wave blocking plate while passing through the through hole. Electromagnetic attenuation method characterized in that to lengthen. In the electromagnetic wave damping device of the electromagnetic wave shielding plate having a through hole penetrating a predetermined area such as a wire through hole or a ventilation window through which electromagnetic waves can leak, Even if the area of the through hole is not reduced, the blocking plate around the through hole is bent in order to thicken the thickness around the through hole of the electromagnetic wave blocking plate so as to increase the absorption rate of the electromagnetic wave absorbed by the electromagnetic wave blocking plate while passing through the through hole. Electromagnetic wave damping apparatus comprising a stepped portion is formed by burring. In the electromagnetic wave damping device of the electromagnetic wave shielding plate having a through hole penetrating a predetermined area such as a wire through hole or a ventilation window through which electromagnetic waves can leak, Even if the area of the through hole is not reduced, it is installed around the through hole so as to thicken the thickness around the through hole of the electromagnetic wave blocking plate so as to increase the absorption rate of the electromagnetic wave absorbed by the electromagnetic wave blocking plate while passing through the through hole. The electromagnetic wave attenuating device is electrically connected to the blocking plate and comprises an overplate having a shape corresponding to the through hole. The method of claim 3, wherein The cover plate is welded or screwed to the blocking plate so as to be electrically connected to each other, and the height (thickness) is increased to increase (thickness) as the amount of electromagnetic wave is increased according to the allowance of electromagnetic waves or the area and shape of the through hole. Electromagnetic wave attenuation device characterized in that. The method of claim 3, wherein The electromagnetic shielding plate is a heat-dissipating case of a completely noiseless computer capable of dissipating heat to naturally discharge heat generated therein to the outside, The through hole is installed in the heat dissipation case is a vortex groove that can play a role of ventilation and the role that can be fixed by plugging the wire from the outside into a vortex shape, The cover plate is formed of a vortex groove corresponding to the vortex groove, the screw is electrically connected to the heat dissipation case so as to absorb the electromagnetic wave, the spiral shape is formed at a predetermined height (thickness) in consideration of the electromagnetic wave absorption rate Electromagnetic wave damping device characterized in that the plate.