KR200143483Y1 - Hall charge construction of electro magnetic wave for wave absorption room - Google Patents

Abstract

The present invention relates to a hole charging structure of a radio wave absorber for a radio darkroom, and more specifically, to measure the noise of the electromagnetic wave or to analyze the characteristics of the antenna in order to analyze the characteristics of the antenna by removing the interference of the electromagnetic wave A hole filling structure of an electromagnetic wave absorber for a radio wave darkroom for filling a hole formed to assemble a radio wave absorber attached to a wall, a ceiling, or the like of a radio wave dark room to be blocked, and a shielding surface with an assembly member.

Description

Hall filling structure of electric wave absorber for electric wave dark room

1 is a perspective view of a ferrite radio wave absorber for a radio dark room,

(a) is a lattice shape (b) is a tile shape (c) is a tile shape with a hole formed.

2 is a perspective view in a state where the ferrite radio wave absorber for radio wave darkroom is bonded to a metal plate.

3 is a perspective view according to the present invention.

* Explanation of symbols for main parts of the drawings

1: lattice type ferrite (FERRITE) 2: tile type ferrite (FERRITE)

3: tile-shaped ferrite with holes 4: hole (HOLE)

5: conductive plate 6: ferrite for charging (FERRITE)

7: shielding surface 8: square hole

The present invention relates to a hole filling structure of a radio wave absorber for a radio darkroom, and more specifically, to measure the noise of a radio wave or to analyze the characteristics of an antenna by artificially eliminating the interference of electromagnetic waves by an artificial method. A hole filling structure of an electromagnetic wave absorber for a radio wave darkroom for filling a hole formed to assemble a radio wave absorber attached to a wall, a ceiling, or the like of a radio wave dark room to be blocked, and a shielding surface with an assembly member.

In recent years, due to the trend of electronic devices that are multi-functional and light and short, the use of radio waves is expanding and the radio environment is significantly deteriorated. Such deterioration of the electromagnetic environment causes radio reception problems and malfunction of electronic equipment. Or, there is a problem to install a separate shielding device or provide a shielding space to interfere with the interaction between the devices with the harmful radiation of harmful electromagnetic waves to the human body.

Therefore, countries around the world measure legislation that restricts the use of electronic devices or products that exceed certain thresholds by measuring harmful electromagnetic waves. It is used as a means.

The method of measuring the noise of the electromagnetic wave (NIOSE) is to exclude the electromagnetic interference, and to measure the open field of the remote area without the electromagnetic interference (Open Field) and a certain free space in an environment free from artificial radio interference (hereinafter, The method of making and measuring radio wave darkrooms is optionally used. The outdoor measurement method is difficult to select a place and to measure the harmful electromagnetic waves, and nowadays, the electromagnetic wave is mostly measured in the radio dark room. It absorbs electromagnetic waves and absorbs radio waves by designing the reflection coefficient to have a value below a specific value, and is composed of a conductive loss material, a dielectric loss material, a magnetic loss material, and the like.

Among them, the ferrite radio wave absorber using the magnetic loss material is excellent in its performance and is widely used to construct a radio wave darkroom.

The ferrite electromagnetic wave absorber is installed in the shield space of the radio darkroom, and variously modified the shape of the electromagnetic wave absorber to satisfy the 30 MHz to several GHz band. Referring to c) as follows.

1 is a perspective view of a ferrite radio wave absorber for a radio darkroom, (a) lattice shape, (b) tile shape, and (c) tile shape with holes formed.

The lattice-type ferrite 1 has a number of square holes 8 formed in a horizontal and vertical direction, and thus has excellent radio wave absorption characteristics in a wide band.

The laminated ferrite is a structure in which a ferrite layer and a dielectric layer are laminated, and have excellent radio wave absorption characteristics, but have disadvantages in that the manufacturing process is complicated and difficult, and a thickness is required to obtain an area of an effective radio dark room.

The tile-like ferrite 2 is manufactured in the form of a tile and applied to a wall surface of a radio wave darkroom, and the tile-like ferrite 3 having a hole 4 is used to assemble the shielding surface of the radio wave darkroom into an assembly member.

Radio wave absorbers for radio darkroom for testing electromagnetic interference (EMI) phenomenon or electromagnetic sensitivity (EMS) of electronic equipment and analyzing antenna characteristics should absorb electromagnetic waves from 30MHz to 18GHz, and for radio darkroom only for EMI / EMS test The wave absorber must absorb electromagnetic waves in the 30 MHz to 1 GHz band.

Tile ferrites (2) and lattice-type ferrites (1) are widely used as radio wave absorbers for EMI / EMS tests in the 30 MHz to 1 GHz band. A pyramidal absorber is laminated and used on the lattice type ferrite 1.

As such, the ferrite radio absorber for radio wave darkroom has excellent radio wave absorption performance and is widely used in radio wave darkrooms for various uses. Among these, tile type ferrites (2) have excellent radio wave absorption characteristics and are inexpensive. It is used.

In general, when attaching a radio wave absorber to a radio darkroom, a conductive plate is formed on a wall or the like, and then tile-like ferrites (2) or lattice-type ferrites (1) are attached one by one onto the conductive plate using an adhesive. Although the method is used, such a construction method has a disadvantage of requiring a lot of manpower and manual work, and high adhesive defect rate.

In order to compensate for these disadvantages, the tile-like ferrite (2) is adhered to the conductive plate (5) by 9, 16, 25, and 36 pieces in a predetermined size, and then, such as a screw on the shielding surface (7) of the radio darkroom. In order to assemble the assembly member, a hole 4 is used to assemble the assembly member, and a ferrite 3 having a hole is used in this part, and the tile-shaped ferrite 3 having the hole is propagated in a dark room. After assembling the shielding surface 7 with the screw, the method of mixing and filling the conductive powder and the organic material in the hole 4 has been used, but this is also because of the hole 4 or the mixing of the conductive powder and the organic material. Due to the inconsistent electromagnetic characteristics with the ferrite radio absorber, the radio wave absorption performance is poor and the manufacturing process that requires the mixing of the conductive powder and the organic material is not only necessary, but also the mass production. There are disadvantages in that the radio wave absorption performance varies according to the difficulty of acid and the mixing ratio of the conductive powder and the organic material, and there is a problem in appearance.

The present invention has been made in view of the above-mentioned problems, and the main object thereof is to provide a hole-filling structure of a radio wave absorber for a radio darkroom which is excellent in radio wave absorption performance and suitable for mass production.

Another object of the present invention is to provide a hole-filling structure of a radio wave absorber for radio darkroom which is excellent in workability and clean in appearance.

In order to achieve the above object, the present invention is assembled through a conductive plate, a tile-type ferrite in which a plurality of tile-like ferrites and holes are bonded to the conductive plate by an adhesive, and holes formed in the tile-type ferrite in which the holes are formed. Provided is a hole filling structure of a radio wave absorber for a radio darkroom comprising a shielding surface coupled to a tile-like ferrite formed by a member, and a filled ferrite having the same shape as the hole inserted into the hole and fixed by an adhesive. .

Hereinafter, the present invention will be described in detail with reference to FIGS. 2 and 3 of the accompanying drawings.

2 is a perspective view in a state where the ferrite radio wave absorber for radio wave darkroom is adhered to a metal plate, and FIG. 3 is a perspective view according to the present invention.

First, looking at the configuration of the present invention, a conductive plate (5), a plurality of tile-like ferrite (2) and a tile-like ferrite (3) formed with a hole adhered to the conductive plate (5) by the adhesive, and the hole The shielding surface 7 which is coupled to the tiled ferrite 3 in which the hole is formed by the assembling member through the hole 4 formed in the formed tiled ferrite 3, and inserted into the hole 4 by an adhesive. It comprises a filled ferrite 6 of the same shape as the hole 4 is fixed.

Looking at the embodiment, the tile-type ferrite (2) and the tile-type ferrite (3) formed with holes are arranged in nine, sixteen, twenty-five, 36 sheets depending on the size of the radio darkroom and the position where the conductive plate (5) is installed. After bonding to the conductive plate 5 with an adhesive with a size, and assembling it with a screw-like assembly member on the shielding surface 7 of the radio wave darkroom, the cylindrical hole 4 to be assembled with the shielding surface 7 and the assembly member. In this part, a tiled ferrite 3 having holes is used.

At this time, a hole (not shown) is also formed in the cylindrical hole 4 formed in the tile-shaped ferrite 3 on which the hole is formed, and the conductive plate 5 bonded thereto, so that the hole is formed through the formed cylindrical hole 4 and the hole. The formed tiled ferrite 3 is assembled and joined to the shielding surface 7 by an assembly member such as a screw.

Thereafter, the cylindrical filling type ferrite 6 which has undergone a separate manufacturing process in the same shape as the cylindrical hole 4 may be fixed by using an adhesive when inserted into the cylindrical hole 4.

According to another embodiment of the present invention, in the shape of the hole 4 and the filling ferrite 6, rectangular hexagonal octagons, etc., in addition to the cylindrical shape, may be formed according to the shape of the hole 4 which is conveniently perforated for construction on walls, ceilings, etc. of the radio darkroom. The shape may be changed, and thus, the efficiency of absorbing radio waves corresponding to the angle of incident electromagnetic waves may be further improved.

In still another embodiment of the present invention, a filler mixed with an organic material by producing a ferrite powder of a material such as a tile-type ferrite (2) or a tile-type ferrite (3) having holes formed in place of the filling ferrite (6), The hole 4 is filled.

For example, the embodiments of the present invention have been described, but those skilled in the art will be able to various modifications and applications not illustrated above.

As described above, the present invention can easily produce a filling ferrite, easy to mass production, excellent productivity, very high workability, and also has a good aesthetic appearance and tile-shaped ferrite or a hole formed tile When the filling ferrite is made of the same material as the type ferrite and charged, the electromagnetic characteristics of the ferrites coincide with each other, so that the radio wave absorption performance is excellent. Furthermore, the filling ferrite is changed into a hole-like shape. It is a very useful design that the efficiency of absorbing radio waves corresponding to the angle of the electromagnetic wave is further enhanced.

Claims (2)

A conductive plate 5, a plurality of tile-like ferrites 2 and a tile-like ferrite 3, in which holes are formed, and a tile-like ferrite 3, in which the holes are formed. A shielding surface 7 coupled with the tiled ferrite 3 in which the hole is formed by the assembly member through the formed hole 4, the hole 4 inserted into the hole 4 and fixed by an adhesive agent; The hole-filling structure of the radio wave absorber for radio wave dark rooms containing the same type of filled ferrite 6. A conductive plate 5, a plurality of tile-like ferrites 2 and a tile-like ferrite 3, in which holes are formed, and a tile-like ferrite 3, in which the holes are formed. A material such as a shield surface 7 coupled to the tiled ferrite 3 in which the hole is formed by the assembly member through the formed hole 4, and the tile ferrite 2 or the tiled ferrite 3 in which the hole is formed. The hole-filling structure of the radio wave absorber for radio wave darkroom containing the ferrite powder which is mixed with an organic substance, and is filled in the said hole (4).