KR101506081B1 - Electromagnetic pulse protecting cabinet - Google Patents

Abstract

The present invention provides a vacuum cleaner comprising: a frame portion having an exhaust module; A door portion having a shielding door rotatably opened and closed at both side portions of the frame portion; A side portion shielding portion detachably attached to the other side portions of the frame portion; Upper and lower shields provided at upper and lower ends of the frame portion; And a ventilation part formed at the upper and lower end shielding parts.

Description

[0001] ELECTROMAGNETIC PULSE PROTECTING CABINET [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic pulse protection cabinet, and more particularly, to an electromagnetic pulse protection cabinet that can protect an electromagnetic pulse and conveniently exchange or replace the equipment housed therein.

Typically, electromagnetic waves refer to the wavelengths generated by the interaction of electricity and magnetism, and occur naturally in all electromagnetic products, from electrical home appliances around us to civilization, such as telecommunication equipment.

The above electromagnetic waves have been continuously raised on the harmful and harmlessness of human body according to their strengths, and technologies for blocking them and absorbing technologies have been continuously studied and developed.

Electromagnetic Pulse (EMP) refers to a large energy that occurs naturally or artificially. A natural EMP can be a lightning stroke, and an artificial EMP can pulse a strong energy generated when a nuclear bomb or an electronic bomb explodes. .

As described above, the electronic devices exposed to the EMP can be seriously damaged by malfunction or damage due to the influence of a large energy pulse. In order to protect the electronic equipment functioning as an important task from the unexpected EMP It is urgent to take measures.

The present invention is intended to provide a cabinet in which electronic components and equipment can be conveniently exchanged and replaced and which can be protected against electromagnetic pulses.

An object of the present invention is to provide an electromagnetic pulse protection cabinet which can protect the equipment housed inside from an EMP attack and easily replace or replace the equipment housed therein.

The present invention provides a vacuum cleaner comprising: a frame portion having an exhaust module; A door portion having a shielding door rotatably opened and closed at both side portions of the frame portion; A side portion shielding portion detachably attached to the other side portions of the frame portion; Upper and lower shields provided at upper and lower ends of the frame portion; And a ventilation part formed at the upper and lower end shielding parts.

It is preferable that the side shields include a plurality of unit shield panels arranged to form a lattice shape with each other, and gaskets arranged in the area between the plurality of unit shield panels and made of a mesh.

The ventilating unit includes a ventilating frame which is disposed in an installation groove cut at a central portion of the upper and lower end shielding portions and is bolted to the vicinity of the installation grooves and a ventilating portion vertically installed at a central portion of the ventilating portion rim, And a ventilation panel having ventilation holes formed therein.

Preferably, the door portion includes a door frame, and the shielding door is hingedly connected to the door frame to be opened and closed.

Here, a door gasket formed of a mesh is preferably provided between the door frame and the side shield.

It is preferable that an electromagnetic wave pulse protection filter having a steel pipe is provided in the side shield portion.

Here, a steel pipe pipe for guiding the steel pipe to pass through both sides of the side shield may be installed.

The present invention has the effect of protecting electromagnetic pulses due to electromagnetic waves and nuclear explosions caused by an attack of electromagnetic waves, and conveniently replacing or exchanging equipment stored therein.

1 is an exploded perspective view showing an electromagnetic wave pulse protection cabinet according to the present invention.
2 and 3 are views showing a frame part according to the present invention.
4 is a view showing an exhaust module according to the present invention.
5 and 6 are views showing a side shield according to the present invention.
FIGS. 7 and 8 are views showing the combined state of the unit shield panels according to the present invention.
9 is a view showing a side shield according to the present invention.
10A to 10C are views showing a door part according to the present invention.
11 is a view showing a connector according to the present invention.
12 is a view showing an electromagnetic wave pulse protection filter according to the present invention.
13 is a view showing a steel pipe pipe according to the present invention.
Fig. 14 is a view showing a configuration for grounding the cabinet of the present invention. Fig.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an electromagnetic wave pulse protection cabinet according to the present invention will be described with reference to the accompanying drawings.

FIGS. 1 to 4 are views showing a configuration of a cabinet for protecting an electromagnetic pulse pulse according to the present invention.

1 to 4, the electromagnetic wave pulse protection cabinet of the present invention includes a frame 100, a door 200, a side shield 300, upper and lower shields 400, (500).

The frame unit 100 includes two pairs of vertical frames 110, an upper frame 120, and a lower frame 130.

The two pairs of vertical frames 110 are composed of four while maintaining a standing state.

The upper frame 120 is installed to connect the upper ends of the four vertical frames 110.

In addition, the lower frame 130 is installed to connect the lower ends of the four vertical frames 110.

The vertical frame 110, the upper frame 120, and the lower frame 130 are in a state in which conductive galvanizing is completed.

In addition, the frames 110, 120, and 130 are made of a steel sheet having a thickness of 3.0 mm or more.

Accordingly, the vertical frames 110 and the upper and lower frames 120 and 130 are coupled to each other to form a skeleton that forms a storage space therein.

The vertical frames 110 are provided with a frame mount 140 having an adjustable front and rear spacing.

Here, the frame mount 140 may be mounted with electronic equipment (not shown) including various IT equipment.

The mounting method uses an M6 gauge nut and a bolt to fix the electronic equipment to the frame mount 140. [

Here, the unit of the unit is preferably displayed on the frame mount 140.

Cable ducts 150 are formed on both sides of the lower frame 130 to form cable holes 151 for exposing a power cable or a data cable to the outside.

Therefore, since a plurality of cables connecting the electronic equipment and the outside can be housed in the cable duct 150, it is possible to collect only the cables and efficiently arrange them.

In addition, an exhaust module 190 is installed in the upper frame 120.

The exhaust module 190 includes a fixing plate 191 fixed to the upper frame 120 and a plurality of blowing fans 192 installed at a plurality of positions of the fixing plate 191.

The plurality of blowing fans 192 exhaust the heat generated by the operation of the electronic equipment to the outside, thereby efficiently controlling the internal temperature of the storage space.

Next, the configuration of the side shielding portion will be described.

Figures 5 and 6 show the construction of a side shield according to the invention.

Referring to FIGS. 5 and 6, the side shield 300 is coupled to both sides of the vertical frame 110.

Accordingly, the side shields 300 are configured as a pair.

Each side shield 300 is comprised of four unit shield panels 310 and gaskets 320.

The four unit shielding panels 310 are arranged to form a lattice shape. Of course, the unit shielding panel 310 in the present invention may be formed of four or less or more.

Each unit shielding panel 310 is composed of a panel body 311 and an edge panel body 312.

Each of the unit shielding panels 310 is formed of a galvanized steel plate.

The edge panel body 312 is formed to be bent at a right angle from the rim of the panel body 311.

Here, the edge panel body 312 is formed with a plurality of bolt fastening holes 312a.

As shown in FIGS. 7 and 8, the four unit shielding panels 310 are arranged in a lattice shape.

At this time, the edge panel bodies 312 of the unit shielding panels 310 may be adjacent to each other.

A gasket is disposed between the unit shielding panels 310 arranged to form the lattice.

The gasket 320 is formed of a steel wire mesh made of copper coated with iron on its outer surface.

The combination of the plurality of unit shield panels 310 is as follows.

And the bolt fastening holes 312a are made to penetrate through the galvanized fastening bolts 314 with conductivity.

A fastening washer 315 is inserted into a fastening bolt 314 passing through the bolt fastening hole 312a and the fastening nut 313 is fastened to the end of the fastening bolt 314.

Here, the conductivity can be improved by the gasket 320 installed in the area between the unit shielding panels 310.

The fastening washer 315 and the fastening nut 314 may also be galvanized.

As described above, the four unit shielding panels 310 and the gasket 320 are combined to complete one side shielding part 300.

The two side shields 300 thus coupled are bolted to both sides of the frame 100.

Figs. 7 and 8 are views showing the coupling relationship between unit shielding panels in the side shield. Fig.

Referring to FIG. 7, the edge panel bodies 312 of the respective unit shield panels 310 are disposed to face each other. Here, the edge panel body 312 is formed with a bolt fastening hole 312a.

A gasket 320 is positioned between the edge panel bodies 312 of the unit shield panels 310.

The fastening bolts 314 penetrate the bolt fastening holes 312a of the two edge panel bodies 312 and the fastening bolts 314 penetrating the bolt fastening holes 312a have fastening nuts 313 And a fastening nut is fastened to an end portion of the protruding fastening bolt 314.

Therefore, as shown in FIGS. 7 and 8, a plurality of unit shielding panels 310 can be coupled to each other.

Therefore, since the side shield 300 according to the present invention is manufactured by combining a plurality of unit shield panels 310, it is possible to easily separate the side shield 300, There is also an advantage in size adjustment.

Although the lattice-shaped side shield 300 is described as a representative example in the present invention, it is also possible to adjust the size by slidingly protruding and inserting the side shield into one side.

Referring to FIG. 1, the ventilation part 500 includes a ventilation part frame (not shown) and a ventilation panel (not shown).

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The ventilation rim is disposed in the installation groove cut at the center of the upper and lower end shielding parts 400 and bolted to the vicinity of the installation groove.

Here, the bolt is galvanized with a conductive property, and bolt holes (not shown) through which the bolt passes are formed in the ventilation rim.

The ventilation panel is installed at a central portion of the ventilation rim, and has ventilation holes (not shown) formed in a plurality of hexagonal shapes passing through upper and lower portions.

Although the ventilation holes are not shown in the drawings, it is preferable that the hexagonal body and the six ribs protruding from the hexagonal portion are connected to each other.

A vent line gasket (not shown), which is galvanized by a conductive wire, is installed between the rim of the ventilation portion and the vicinity of the installation groove.

Here, the ventilation gasket is substantially the same as the above-described gasket.

In addition, the ventilation portion rim is formed of a cold-rolled steel sheet.

In addition, a filter (not shown) may be installed at the upper or lower end of the ventilation panel to filter dust.

The ventilation part 500 according to the present invention can guide the heat of the electronic equipment exhausted from the exhaust module 190 to efficiently exhaust the outside.

On the other hand, door portions 200 are respectively installed on the opposite sides of the shield according to the present invention.

10A to 10C show a door part according to the present invention.

10A and 10B, the door unit 200 according to the present invention includes a door frame 210 and a shielding door 220 hingedly connected to the door frame 210 to be opened and closed.

The door frame 210 is bolted to the rim of the side shield 300.

A door gasket (not shown) is installed between the door frame 210 and the side shield 300.

Here, the door gasket is made of a copper material coated with iron on its outer surface and is made of a steel wire mesh.

The door portion 200 according to the present invention is installed on the other side portions of the frame portion 100 and is coupled through bolts and nuts so that the door portion 200 can be easily assembled and easily accommodated in many directions .

11 shows a connector according to the present invention.

Referring to FIG. 11, the side shield 300 according to the present invention further includes a connector portion 700.

The connector 700 includes a connector panel 710, a BC connector 720, and an optical cable connector 730.

The connector panel 710 is formed of a brass plate and is positioned in a cutout hole cut into the side shield 300 and bolted to a region near the cutout hole.

The BCC connector 720 is formed in a plurality of protrusions on both sides of the connector panel 710.

The optical cable connector 730 includes an optical cable tube 731 and a pair of fixing members 732.

The optical cable pipe-making pipe 731 is installed to pass through both side portions of the connector panel 710.

The pair of fixing members 732 are installed to be fitted into the optical cable tube allowing tube 731 and are coupled at both sides of the connector panel 710 to connect the optical cable tube tube 731 to the connector panel 710 ).

Fig. 12 shows a filter for protecting an electromagnetic wave pulse.

Referring to FIG. 12, the side shield 300 is provided with an electromagnetic wave pulse protection filter 600 having a steel pipe 610.

The steel pipe pipe 620 is punched to fit the diameter of the steel pipe 610 so as to pass through both side portions of the side portion shielding part 300.

Next, the gasket 630 is fixed between the side shielding plate 300 and the contact surface of the steel pipe pipe 620.

Further, when the end of the steel pipe pipe 620 is tightened using the hexagonal nut 640, the conductivity between the filter 600 and the side shield 300 is improved.

13 shows a steel pipe pipe according to the present invention.

The steel pipe pipe 620 is arranged to pass through both side portions of the side shield plate 300.

A hexagonal nut 640 is coupled to both ends of the steel pipe pipe 620, and a gasket 630 is installed therebetween.

Therefore, by tightening the hexagonal nut 640, each gasket 630 is brought into close contact with the outer surface of the side shielding plate 300.

Therefore, the conductivity between the side shield 300 and the steel pipe pipe 620 can be improved.

In the case of the steel pipe pipe 620, that is, when the length of the steel pipe pipe 620 is five times or more the diameter of the steel pipe pipe 620, a pulse can not be input. The diameter of the steel pipe pipe 620 may be 12 to 24 mm and the length may be 600 to 1200 mm.

Also, although not shown in the drawings, the steel pipe pipe 620 may be composed of unit pipes connected in multiple stages, and a gasket (not shown) having high conductivity may be further provided therebetween.

Further, the lengths of the unit tubes may be the same or different from each other.

Therefore, the length of the steel pipe pipe 620 according to the diameter can be variably controlled.

Figure 14 shows a ground cable and a bus bar according to the invention.

Referring to FIG. 14, a grounding ring terminal 810 is formed at both ends of the grounding cable 800.

The copper bus bar 900 forms a predetermined length, and ground holes 910 are formed.

The other end of the ground cable 800 is connected to the bus bar 900. The other end of the ground cable 800 is connected to the other end of the ground cable 800 by a bolt, Lt; / RTI >

Therefore, the embodiment of the present invention has an advantage in that it can protect electromagnetic pulses due to electromagnetic wave shielding and nuclear explosion due to the attack of electromagnetic waves, and can replace or replace the equipment stored therein.

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.

10: twin-cutter 100: frame part
110: vertical frame 120: upper frame
130: lower frame 140: mount frame part
150: Cable duct 151: Cable hole
190: exhaust module 200: door part
210: Door frame 220: Shielding door
300: side shielding part 310: unit shielding panel
311: Panel body 312: Edge panel body
312a: bolt fastening hole 313: fastening bolt
314 fastening washer 320 gasket
400: upper and lower end shielding part 500: ventilation part
600: Electromagnetic wave protection filter
610: Steel pipe 620: Steel pipe pipe clearance
700: connector portion 710: connector panel
720: BNC connector 730: Optical cable connector
731: optical cable pipe tube 732: fixing member
800: Grounding cable 900: Copper bus bar

Claims (5)

A frame portion having an exhaust module;
A door portion having a shielding door rotatably opened and closed at both sides of the frame portion;
A side shield which is detachably attached to the other side portions of the frame portion;
Upper and lower shields provided at upper and lower ends of the frame portion; And
And a ventilation part formed in the upper and lower end shielding parts,
Wherein the side shields comprise a plurality of unit shielding panels disposed and joined to form a lattice shape with each other, and a steel wire mesh disposed on an area between the plurality of unit shielding panels and including copper and having an outer surface coated with a steel wire mesh And a gasket
Wherein each of the plurality of unit shielding panels comprises:
And an edge panel body extending perpendicular to the edge of the panel body and having a plurality of bolt fastening holes,
Wherein edge panel bodies of each of the plurality of unit shield panels are adjacent to each other, a conductive zinc-plated fastening bolt penetrates through the bolt fastening holes, a fastening washer is inserted into the fastening bolts penetrating the fastening bolts, A fastening nut is coupled,
Wherein the fastening washer and the fastening nut are galvanized,
Wherein the side shield comprises a connector,
Wherein the connector portion comprises a connector panel, a BCC connector, and an optical cable connector,
The connector panel is formed of a brass plate, is positioned in a cut-out hole in the side shield and bolted to a region near the cut-out hole,
Wherein the plurality of the BCC connectors are formed to protrude from both sides of the connector panel,
Wherein the optical cable connector is composed of an optical cable pipe and a pair of fixing members,
Wherein the optical cable pipe-through pipe is installed so as to penetrate both side portions of the connector panel,
Wherein the pair of fixing members are installed to be fitted into the optical cable tube clearance, the optical cable tube is fixed to the connector panel by being coupled at both sides of the connector panel,
Wherein the side shielding portion is provided with a filter for electromagnetic wave pulse protection having a steel pipe and a steel pipe pipe for guiding the steel pipe to pass through both side portions of the side shield portion,
Wherein the steel pipe pipe is composed of unit pipes connected in multiple stages.
delete The method according to claim 1,
Wherein the ventilating portion comprises:
A ventilation frame which is disposed in an installation groove cut at a central portion of the upper and lower end shielding portions and is bolted to the vicinity of the installation groove,
And a ventilation panel installed at a central portion of the ventilating frame and having ventilation holes formed in a plurality of hexagonal shapes passing through upper and lower portions thereof.
The method according to claim 1,
The door portion
A door frame,
The door being hinged to the door frame to be opened and closed,
And a door gasket formed of a mesh is installed between the door frame and the side shield.
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