KR101413491B1 - Door for Protection against Electromagnetic Wave and Radioactivity - Google Patents

Abstract

The present invention provides a door device comprising: a door body having a space therein and having a hinge portion on one side; An electromagnetic wave shielding part formed of an electrically conductive material and installed in multiple inside the door body at a predetermined interval; And a radiation shielding portion formed of lead and installed in the interior of the door body.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a door for electromagnetic wave and radioactive shielding,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a door for electromagnetic wave and radiation shielding, and more particularly, to an electromagnetic wave and radiation shielding door capable of performing electromagnetic wave shielding as well as a radiation shielding function.

Typically, most businesses and households use a variety of electronic products, and most of their business is handled by business or personal computers.

In addition, countries, military, financial institutions, etc. use various kinds of electronic equipments, communication equipments, financial systems, etc., and most tasks are processed by using computers.

However, various electronic equipments, communication equipments, financial systems and the like as described above are very sensitive or vulnerable to electromagnetic pulses or classical magnetic pulses called EMP or HEMP.

Also, Emphy (EMP) or HEMP (HEMP) occurs when a nuclear bomb or an electronic bomb explodes.

In order to solve such conventional problems, Korean Patent Registration No. 10-1083284 (registered on November 8, 2011) discloses a technique relating to a double door for EMC protection.

However, in the above-mentioned registered patent, there is a problem that the protection function that meets only one purpose of EM protection is rich.

In addition, in the case of ENP, radioactivity is generated not only by an electromagnetic wave due to a nuclear explosion, but also by the conventional door, there is a problem that the radiation shielding problem can not be solved.

An object of the present invention is to provide an electromagnetic wave shielding and radiation shielding door capable of effectively shielding radioactivity including electromagnetic waves due to electromagnetic wave shielding and nuclear explosion by attack of electromagnetic wave shielding.

In one aspect, the present invention provides a door comprising: a door body having a space therein and having a hinge on one side; An electromagnetic wave shielding part formed of an electrically conductive material and installed in multiple inside the door body at a predetermined interval; And a radiation shielding portion formed of lead and installed in the interior of the door body.

The door body includes an outer frame having a latching protrusion formed along a rim, a seating plate spaced apart from the latching jaw by a predetermined distance and having a seating groove formed in a front surface thereof, A hinge frame having the hinge part formed on one side surface thereof, and a door plate coupled to the outer frame.

It is preferable that the radiation shielding portion is disposed inside the hinge frame and is located in the seating groove, and the electromagnetic wave shielding portion is disposed in a space between the holding jaw and the rim of the seating plate.

It is preferable that the electromagnetic wave shielding portion is formed of two pairs and is formed of a material containing Be and Cu, and is formed into a frame shape in which a central portion is opened.

It is preferable that the two pairs of electromagnetic wave shielding portions are arranged to form two layers along the outer side of the outer frame of the hinge frame.

In addition, a first fork having a 'C' shape is formed at a rim of the hinge frame, a second fork having a 'C' shape in which the first fork is inserted into a hook of the outer frame, And a third fork having a 'C' shape in which the first fork is inserted inward.

It is preferable that each of the electromagnetic wave shielding parts is a fingerer spring which is located in a space between the second fork and the third fork and is supported by the end of the first fork.

The radiation shielding portion may be formed to have a predetermined thickness and be divided into a plurality of gratings.

It is preferable that a conductive silicone gasket is further provided on the rim of the outer frame, and the conductive silicone gasket is hermetically sealed between the outer frame and the hinge frame.

Here, a gasket mounting groove on which the conductive silicone gasket is seated is formed at the rim of the outer frame.

The conductive silicone gasket is formed into a hollow gasket body, and one side of the gasket body is formed to be convex along the outer side.

Preferably, the convexly formed portion protrudes from the gasket mounting groove and contacts the one surface of the hinge frame.

INDUSTRIAL APPLICABILITY The present invention has an effect of effectively shielding radioactivity including electromagnetic waves due to electromagnetic wave shielding and nuclear explosion due to attack of electromagnetic wave guns.

Further, according to the present invention, the conductive silicone gasket is hermetically sealed between the door plate and the outer frame, so that it is possible to achieve moisture-proofing together with electromagnetic wave shielding.

1 is an exploded perspective view showing the electromagnetic wave and radiation shielding door of the present invention.
2 is a partially cutaway perspective view showing a coupling structure of the electromagnetic wave shielding portion of FIG.
3 is a partial cross-sectional view showing the electromagnetic wave and radiation shielding door of the present invention.
4 is a perspective view showing a conductive silicone gasket according to the present invention.
5 is a cross-sectional view of the conductive silicon gasket of FIG.
6 is a view showing an example in which an electromagnetic wave shielding portion is further added to the radiation shielding portion according to the present invention.
7 is a view showing an example in which an electromagnetic wave shielding portion is further added to the front surface of the radiation shielding portion according to the present invention.
8 is a view showing an example in which an electromagnetic wave shielding portion is further added to the inner edge of the door plate according to the present invention.

Hereinafter, the electromagnetic wave and radiation shielding door of the present invention will be described with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows the electromagnetic wave and radiation shielding door of the present invention.

The electromagnetic wave and radiation shielding door of the present invention can largely shield electromagnetic waves and radiation.

The construction of the door of the present invention will be described as follows.

Referring to FIG. 1, the door includes a door body 100, an electromagnetic wave shielding unit 200, and a radiation shielding unit 300.

The door body 100 includes an outer frame 110, a seating plate 120, a hinge frame 130, and a door plate 140.

Here, the outer frame 110 is formed as a frame having a central opening, and the door plate 140 is configured to be coupled to the outer frame 110.

The outer frame 110 and the door plate 140 may be coupled to each other through coupling means such as bolts and nuts.

Therefore, a certain space may be formed inside the outer frame 110 and the door plate 140.

More specifically, referring to FIGS. 2 and 3, the inner frame of the outer frame 110 has a multi-stepped jaw.

The jaws 111 and the jaws 112 are connected to the jaws 111. The other jaw 112 is formed with a gasket mounting groove 112a to be described later.

The seating plate 120 is installed at a front end of the outer plate 110.

The rim of the seating plate 120 is bent into a blade shape and a seating groove 121a having a certain depth is formed in a central portion surrounded by a rim and a seating portion 121 protruding rearward is formed.

The seating plate 120 is coupled with the outer frame 110 and the seating part 121 having the seating groove 121a may be inserted into the center of the outer frame 110.

The hinge frame 130 may be disposed at the front end of the seating plate 120 and the outer edge of the hinge frame 130 may be disposed to face the inner edge of the seating frame 120.

Here, the outer frame of the hinge frame 130 is formed in a shape corresponding to the multi-stepped jaws of the inner frame of the outer frame 110. This shape is ?? Lt; / RTI >

The outer edge of the hinge frame 130 is spaced apart from the inner edge of the outer frame 110 by a predetermined distance.

Here, the electromagnetic wave shielding part 200 according to the present invention is disposed in the spaced apart space.

In addition, the hinge frame 130 is filled with lead 130a.

A hinge part 131 is formed on one side surface of the hinge frame 130 at a plurality of positions along the vertical direction. The hinge portion 131 may protrude from one side of the door body 100.

The door plate 140 may be engaged with the rim of the outer frame 110 in a state where the door plate 140 is disposed at the front end of the hinge frame 130.

Meanwhile, the electromagnetic wave shielding part 200 according to the present invention is installed in the inner space of the door body 100.

The electromagnetic wave shielding unit 200 is installed in the door body 100 in multiple ways.

Preferably, the electromagnetic wave shielding part 200 includes an inner electromagnetic wave shielding part 210 and an outer electromagnetic wave shielding part 220, and is formed as a pair.

The inner electromagnetic wave shielding part 210 and the outer electromagnetic wave shielding part 220 are formed of Be and Cu and are formed into a frame shape.

The inner electromagnetic wave shielding part 210 and the outer electromagnetic wave shielding part 220 are formed by forming two layers along the outer side in a space between the outer edge of the hinge frame 130 and the inner edge of the outer frame 110 do.

Also, a first fork F1 having a 'C' shape is formed on the rim of the hinge frame 130. [ A second fork F2 having a shape of 'c' in which the first fork F1 is inserted is provided in the latching protrusion 111 of the outer frame 110 and a second fork F2 disposed inside the second fork F2 And a third fork F3 having a 'C' shape in which the first fork F1 is inserted inward.

In particular, each of the electromagnetic wave shielding parts 200 is composed of a fingerer spring which is located in the space between the second fork F2 and the third fork F3 and is supported by the end of the first fork F1 do.

Therefore, in the present invention, electromagnetic waves can be easily shielded by forming two layers along the inside from the outside of the door.

That is, the inner electromagnetic wave shielding part 210 is disposed to surround the seating part 121 of the seating plate 120, and is formed of a conductive material to block electromagnetic waves generated from the outside.

Meanwhile, the seating plate 120 is engaged with the hinge frame 130.

Therefore, the outer electromagnetic wave shielding part 220 may be installed between the frame of the seating plate 120 and the hinge frame 130.

In addition, the circumference of the inner electromagnetic wave shielding part 210 and the outer electromagnetic wave shielding part 220 may be located around the outer frame 110 and the door plate 140, which are coupled to each other.

In addition, the radiation shielding unit 300 according to the present invention is installed between the door plate 140, which is the front plate, and the seating plate 120, which is the rear plate, in the inner space of the door body 100 according to the present invention.

The radiation shielding part 300 is formed of lead and has a thickness of 10 centimeters.

The radioactive shielding part 300 may be installed to be seated in the seating groove 121a of the seating plate 120 by using a pontoon nail.

At this time, the depth of the seating groove 121a may be smaller than the thickness of the radiation shielding part 300. [

Therefore, the radioactive shielding part 300 may partially protrude forward in a state where the radioactive shielding part 300 is fitted in the seating groove 121a.

At this time, the partially protruding radiation shielding part 300 is positioned at the center opening of the hinge frame 130 coupled with the seating plate 120.

The outer electromagnetic wave shielding part 220 provided between the seating plate 120 and the hinge frame 130 may surround the periphery of the radiation shielding part 300 protruding from the seating groove 121a have.

That is, the inner electromagnetic wave shielding part 210 according to the present invention is installed so as to surround the periphery of the seating part 121, thereby covering the periphery of the radiation shielding part 300 of the part to be fitted and seated in the seating groove 121a.

The outer electromagnetic wave shielding part 220 may cover the periphery of the radiation shielding part 300 projecting from the seating groove 121a as described above.

When the installation of the radiation shielding unit 300 is completed, the door plate 140 is installed at the front end of the radiation shielding unit 300.

Here, the door plate 140 may be bolted to the rim of the outer frame 130 described above.

Here, the radiation shielding part 300 according to the present invention may be formed by dividing the radiation shielding part 300 in a plurality of lattice forms.

Therefore, in the present invention, the standard size of the lead board of the radiation shielding unit 300 itself can be sufficiently taken into consideration.

Also, although not shown in the drawing, the radiation shielding part 300 may be constructed by joining a first lead plate divided into a second lead plate formed of one plate. Of course, the number of the first and second plates is not limited.

The electromagnetic wave shielding part 200 and the radiation shielding part 300 according to the present invention are installed inside the door body 100.

Particularly, the electromagnetic wave shielding part 200 may be provided in multiple along the thickness direction of the door body 100, and the radiation shielding part 300 may be covered with the electromagnetic wave shielding part 200 in multiple perimeters.

Accordingly, the embodiment of the present invention can efficiently shield radioactivity including electromagnetic waves due to electromagnetic wave shielding and nuclear explosion due to attack of electromagnetic wave guns.

In addition, in the present invention, a conductive silicone gasket 400 may be further provided on the rim of the outer frame 110, as shown in FIG.

Therefore, the conductive silicone gasket 400 can easily provide airtightness between the outer frame 110 and the hinge frame 130, thereby achieving moisture-proof and soundproofing effects.

As described above, the gasket mounting groove 112a on which the conductive silicone gasket 400 is seated is formed at the outer frame 110 's edge.

The conductive silicone gasket 400 is installed in the gasket installation groove 112a.

The conductive silicone gasket 400 is a gasket body formed in a hollow shape.

One side of the gasket body is formed to be convex along the outer side.

Preferably, the convex portion is protruded from the gasket mounting groove 112a and is in contact with one surface of the hinge frame 130.

Further, as shown in FIG. 5, the conductive silicon gasket 400 is formed of a plurality of different materials.

The layers are formed by forming a conductive acrylic adhesive layer 420 on the release film layer 410 and forming a conductive nonwoven fabric layer 430 on the conductive acrylic adhesive layer 420, A conductive silicon pressure-sensitive adhesive layer 440 is formed.

The conductive double-sided tape 450 may be selectively attached to the lower end surface of the gasket 400.

According to the present invention, in the present invention, the electromagnetic wave shielding part 200 including the finger spring and the pockets of the conductive material on the inner side of the door body 100 and the outer side frame 110 is composed of two or more rows, Shielding performance of 80 dB or more, and a silicone gasket (400) is added to the outside of the door body (100) to provide a moisture-proof function and a further electromagnetic wave shielding performance.

In addition, at the inner side of the door body 100, the radioactive shielding part 300 formed of a soft plate having a thickness of 10 cm can be filled to function as a radioactive shielding.

Accordingly, the present invention can effectively shield the EMP phenomenon, which occurs in nuclear attack, as well as the radiation effect, while shielding the electromagnetic wave against the enemy EMP shot attack.

It also minimizes the exposure of radioactive exposure to people working inside the EMP area and may protect critical facilities from electromagnetic attack.

Fig. 6 shows an example in which an electromagnetic wave shielding portion is further added to the radiation shielding portion according to the present invention.

Referring to FIG. 6, an electromagnetic wave shielding unit 201 may be installed at the edge of the unit body 311 of the radiation shielding unit 301 according to the present invention.

The electromagnetic wave shielding unit 201 may be substantially the same as the electromagnetic wave shielding unit 200 according to the present invention.

Although not shown in the drawings, the electromagnetic wave shielding part 200 may be fitted in a groove formed around the radiation shielding part 300. [

3 shows an example in which an electromagnetic wave shielding portion is additionally provided on the front face of the radiation shielding portion according to the present invention.

7, the electromagnetic wave shielding unit 202 may be formed in a plate shape on the front surface of the unit body 311 of the radiation shielding unit 302. [

The electromagnetic wave shielding unit 202 may be installed in the front surface of the radiation shielding unit 302 by a separate groove, or may be installed through a coupling unit such as a bolt.

This configuration can prevent the electromagnetic wave shielding unit 202 from being displaced in advance when an impact is applied to the door body 100 from the outside due to a nuclear attack, Function can be performed.

8 is a view showing an example in which an electromagnetic wave shielding portion is further added to the inner edge of the door plate according to the present invention.

Referring to FIG. 8, a separate electromagnetic wave shielding unit 203 may be installed on the inner or outer frame of the door plate 140 according to the present invention.

Accordingly, the present invention can have the effect of forming multiple electromagnetic wave shielding.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

100: door body 110: outer frame
120: seat plate 130: hinge frame
140: Door plate 200: Electromagnetic wave shielding part
210: inner electromagnetic wave shielding part 220: outer electromagnetic wave shielding part
300: radiation shielding part 400: conductive silicone gasket

Claims (8)

A door body having a space formed therein and having a hinge portion on one side;
An electromagnetic wave shielding part formed of an electrically conductive material and installed in multiple inside the door body at a predetermined interval; And
And a radiation shield formed in the interior of the door body,
The door body includes an outer frame having a latching protrusion formed along a rim, a seating plate spaced apart from the latching jaw by a predetermined distance and having a seating groove formed in a front surface thereof, A hinge frame having a hinge part formed on one side surface thereof, and a door plate coupled to the outer frame,
Wherein the radiation shielding portion is disposed inside the hinge frame and is located in the seating groove, and the electromagnetic wave shielding portion is disposed in a space between the engagement protrusion and the rim of the seating plate.
delete The method according to claim 1,
The electromagnetic wave shielding unit is composed of two pairs,
Be, and Cu, and is formed into a frame shape having a central opening.
The method of claim 3,
Wherein the two pairs of electromagnetic wave shielding parts comprise:
Wherein the hinge frame is disposed so as to form two layers along the outer side of the outer frame of the hinge frame.
5. The method of claim 4,
A first fork of the 'C' shape is formed at the rim of the hinge frame,
A second fork having a shape of 'c' into which the first fork is inserted, and a third fork, which is provided inside the second fork and into which the first fork is inserted inward, However,
Wherein each of the electromagnetic wave shielding portions comprises:
Wherein the door is a pincher spring located in a space between the second fork and the third fork and supported by an end of the first fork.
The method according to claim 1,
The radioactive-
Wherein the electromagnetic wave shielding layer is formed by dividing the electromagnetic wave shielding layer into a plurality of gratings.
The method according to claim 1,
A conductive silicone gasket is further provided on the rim of the outer frame,
Wherein the conductive silicone gasket seals between the outer frame and the hinge frame.
8. The method of claim 7,
A gasket mounting groove on which the conductive silicon gasket is mounted is formed at an edge of the outer frame,
The conductive silicone gasket may include:
A gasket body formed into a hollow shape,
One side of the gasket body is formed to be convex along the outside,
Wherein the convexly formed portion protrudes from the gasket mounting groove and contacts one surface of the hinge frame.

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