KR101346770B1 - Ventilation apparatus for shielding electromagnetic wave - Google Patents

Abstract

The present invention accommodates the shield, and is connected to the shield receiving frame, the shield receiving frame and the shield receiving frame formed with a shielding room fastening hole so that the fastening bolt is inserted and connected to one side of the edge of the shield room vent opening, Ventilation connecting part and fastening hole receiving frame formed with fastening hole includes a gasket for blocking the electromagnetic waves flowing into or out of the coupling gap when combined with the shielding board's edge shield plate, the shield is made of a hexagonal honeycomb structure Provided is a ventilation device for shielding electromagnetic waves.
According to the present invention, while shielding the electromagnetic waves at the same time through the air to the shield room for cooling or heating, and can be easily coupled to one side of the shielding plate edge of the shield through the bolt coupling when installing the ventilation device in the ventilation opening have.

Description

Ventilation device shielding electromagnetic waves {VENTILATION APPARATUS FOR SHIELDING ELECTROMAGNETIC WAVE}

The present invention relates to a ventilator, and more particularly, to let air for cooling or heating in a shield room to which electromagnetic waves must be blocked, and at the same time, inflow of electromagnetic waves from the outside or outflow of electromagnetic waves from the shield room to the outside. It relates to a ventilation device that shields electromagnetic waves that can be prevented.

From satellite communications to cell phones, computers and microwave ovens, modern people are surrounded by various electromagnetic waves. With the rapid development of IT technology, the current electromagnetic wave is a new environmental problem that causes various obstacles such as malfunction of equipment and crosstalk.

Electromagnetic shielding refers to blocking noise generated inside an electronic device from outside of the case and blocking noise from invading from the outside. Electromagnetic shielded room (hereinafter referred to as 'shield room') to protect certain spaces (hospital diagnostic rooms or company's electromagnetic shielding laboratories) from the external radio wave environment or to prevent electromagnetic waves from any specific facility from leaking to the outside. There is'). For example, a shield room is a place for precise measurement of electromagnetic waves of a specific electronic device or a test of the immunity of electromagnetic waves. A shield room is provided with a ventilation device for ventilation with outside air for cooling or heating the shield room.

The ventilation device connected to the shield room has a problem of not only inflow of air for cooling or heating, but also an electromagnetic wave from the outside through the ventilation device to the shield room, causing distortion in electromagnetic wave measurement of a specific electronic device.

As a prior art for preventing the inflow or outflow of electromagnetic waves through the ventilation device is the Republic of Korea Utility Model Registration No. 034086 'Honeycomb air vent device'. The prior art is plastic processing of a metal plate of a certain shape by using a forming roller or a press, and repeatedly forming the molded metal plate to be turned upside down to form a honeycomb honeycomb form, the honeycomb at a constant pressure It relates to a honeycomb air vent device characterized in that the compression is formed by the bonding and fixed to the outer case there is only a description that the honeycomb air vent is fixed to the outer case without a specific substrate connected to the vent of the shield room.

Another prior art is the Republic of Korea Registration No. 0910784 '915MHZ industrial microwave electromagnetic shielding device'. The prior art is a panel-shaped rectangular frame 20 having a portion fixed to the open surface of the cavity 10 protruding in and out of the cavity 10, the main panel is provided with a shielding net (31-1) in the center 31, a first vertical portion extending from the main panel 31 as bent from the end of the main panel 31 a plurality of times, a first horizontal portion extending from the first vertical portion, and the first vertical portion extending from the first vertical portion; The second vertical portion 32-1 extending from the horizontal portion and the second horizontal portion 32-2 extending from the second vertical portion 32-1 are provided to have a plurality of hexahedral shapes arranged at regular intervals. The main panel 31 and the second horizontal portion 32-2 are composed of a choke 32, the inner cover 30 having a height difference and a distance d1, and one surface of the square frame 20. It is fixed in contact with the other side, the other side is formed with a fitting groove having the same width as the width (d2) of the second horizontal portion (32-2) at its central portion and both ends Legs having the same width as the separation distance d1 of the main panel 31 and the second horizontal portion 32-2 are formed in the rectangular frame 20 and the second horizontal portion 32-2. As it is disposed, the choke cover 40, a viewing window 51 is provided at the center of the choke cover 40 to form a distance difference (L) between the rectangular frame 20 and the inner cover 30, the outside of the choke cover 40 The 915MHZ industrial microwave electromagnetic shielding device is inserted along the side and comprises an outer cover 50 provided with a hinge connected to the square frame 20 on an outer circumferential surface to be rotatable in one direction. In order to connect to the cavity has a complicated structure consisting of a square frame, the inner cover, the choke cover and the outer cover.

1 is a view for explaining a conventional shield is coupled to the frame by soldering. As shown in FIG. 1, when the electromagnetic shield 20 is connected to the frame 10 for coupling to the vent of the shield room, the shield 30 is generally soldered to the edge 30 to which the shield is coupled, but the shield is honeycombed. Due to the structure, it is not easy to lead the solder, there is a problem that the operation is complicated and inconvenient in installing the ventilation device.

The present invention has been made to solve the above problems, an object of the present invention is to shield the electromagnetic waves at the same time through the air for cooling or heating in the shield room, it is possible to easily install a ventilator in the vent of the shield room It is to provide a ventilation device for shielding electromagnetic waves.

In order to solve the above problems, the ventilation device for shielding electromagnetic waves in one embodiment of the present invention accommodates the shielding body, the shielding body accommodating the shielding room fastening hole is formed so that the fastening bolt is inserted to connect to the edge surface of the shield room vents It is formed integrally with the frame, the shield receiving frame in the 'c' shape, and the ventilation pipe connecting part and the shield receiving frame are formed in the shield room vent to connect the ventilation pipe connected to the external air conditioner or heater. It includes a gasket for blocking the electromagnetic waves flowing into or out of the coupling gap when combined with the edge shield plate, the shield is composed of a hexagonal honeycomb structure, the ventilation pipe connecting portion of the ventilation pipe connected to the external air conditioner or heater. Rubber packing for vibration prevention and insulation when connecting by side and fastening bolt Is inserted.

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According to the present invention as described above, while shielding the electromagnetic waves at the same time through the air to the shield room for cooling or heating, when installing the ventilator in the ventilating through the bolted coupling of the shield plate ventilating port on one side of the edge Can be combined.

In addition, when one side of the shield plate vent of the shield room vent and the ventilator are bolted together, a gasket for blocking the electromagnetic wave is inserted between the honeycomb shield and the shield of the shield vent vent to completely block the electromagnetic waves flowing into or out of the coupling gap. There is an advantage.

In addition, one side can be easily connected to the shield room vent shield plate by bolting, while the other side can be easily connected to the external ventilation pipe for cooling or heating through bolting, so that the ventilation system can be more efficiently than conventional soldering. Can be installed.

1 is a view for explaining a conventional shield is coupled to the frame by soldering.
2 is a perspective view of the ventilation device viewed from the ventilation pipe side according to an embodiment of the present invention.
3 is a perspective view of the ventilation device viewed from the shield room side according to an embodiment of the present invention.
FIG. 4 illustrates a gasket inserted between a shield and one edge of a shield room vent according to an exemplary embodiment of the present invention.
5 illustrates a shield of a honeycomb structure according to an embodiment of the present invention.
Figure 6 is an installation cross-sectional view for explaining that the ventilator is coupled to the shielding room and the vent pipe according to an embodiment of the present invention by the fastening bolt.

The following detailed description is only illustrative, and merely illustrates embodiments of the present invention. In addition, the principles and concepts of the present invention are provided for the purpose of explanation and most useful.

Accordingly, various forms that can be implemented by those of ordinary skill in the art, as well as not intended to provide a detailed structure beyond the basic understanding of the present invention through the drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view of the ventilation device viewed from the ventilation pipe side according to an embodiment of the present invention, Figure 3 is a perspective view of the ventilation device viewed from the shield room side according to an embodiment of the present invention.

As shown in FIGS. 2 and 3, the ventilation device for shielding electromagnetic waves accommodates the electromagnetic shielding body 300 therein, and a shielding room fastening hole 110 is formed to couple the ventilation device to the ventilation hole of the shield room. It includes a shield receiving frame 100, a ventilation pipe connecting portion 200 is formed with a fastening pipe fastening hole 210 for connecting the one side of the ventilation pipe and the wind blower by a fastening bolt. Here, the shield receiving frame 100 or the ventilation pipe connection part 200 may have various shapes such as a square and a circle according to the shape of the shield room vent to be coupled or the shape of the external ventilation pipe for heating or cooling. The form of the 300 may also be made in various forms accordingly.

The shield accommodating frame 100 has a space for accommodating the shield 300 that can shield electromagnetic waves therein, and serves to fix the shield inserted in the space so as not to move. Meanwhile, the shield receiving frame 100 may protect a specific space (such as a hospital's diagnosis room or an industrial electromagnetic wave test lab) from an external radio wave environment, or may prevent the electromagnetic waves from a specific facility from leaking to the outside. A shield room fastening hole 110 for coupling the ventilation device to one surface of the edge shield of the ventilation hole (see FIG. 6) is formed. Ventilation pipe connection part 200 is coupled to the shield receiving frame 100, the ventilation pipe fastening hole 210 is formed to be connected by using one side and the bolt of the ventilation pipe. Packing (600, Fig. 6) for the ventilation pipe connection part 200 does not transmit the vibration of the ventilation pipe connected to the external heater or air conditioner to the shield room when the ventilation pipe connection part 200 is connected to one side of the ventilation pipe by the fastening bolt and not pass electricity. Can be inserted). Here, the packing 600 (refer to FIG. 6) may be a rubber material or a silicon material having ductility. An embodiment in which the ventilator is connected to the shield room vent side and the external vent side will be described in detail with reference to FIG. 6.

Referring to FIG. 5, the electromagnetic shield 300 inserted into the shield accommodating frame 100 includes a hexagonal honeycomb structure 310 having a predetermined diameter and length for shielding air in the shield room for cooling or heating. It may be introduced through the 300, the electric wave can be shielded by the loss through mutual interference of the electromagnetic waves introduced into the honeycomb structure.

Therefore, the shield for cooling or heating at the same time blocking the electromagnetic wave flowing in from the outside or the electromagnetic wave flowing out of the shield room through the electromagnetic shield 300 having a honeycomb structure accommodated in the shield receiving frame 100. The air can be passed through the room, and one side can be easily connected with the shield room vent shield plate and bolted, while the other side can be easily connected with the external ventilation pipe side for cooling or heating by bolting. Installation is simpler than it is and ventilation can be installed efficiently.

FIG. 4 illustrates a gasket inserted between a shield and one edge of a shield room vent according to an exemplary embodiment of the present invention.

As shown in FIG. 4, the gasket 400 capable of blocking electromagnetic waves is formed along the edge of the electromagnetic shield 300, and is introduced into the coupling gap when the shielding plate and the fastening bolt are connected at the edge of the shield room vent. In order to block the leaked electromagnetic wave, the outer end portion 401a and the inner end portion 401b may be formed around the fastening region 402 in which the gasket fastening hole 410 is formed (see AA 'section). As the ventilator is connected to the shield plate of the shielded vent vent edge and the shield 300 of the ventilator through a fastening bolt, a coupling gap may occur in a continuous contact surface. Therefore, the gasket 400 is inserted between the shielding body 300 and the shielding plate at the edge of the shield room vent and is coupled to the gasket fastening hole 410 on the fastening area 402 through the fastening bolt. 401b) may block the inflow or outflow of electromagnetic waves by physically filling the coupling gap.

The gasket 400 may be formed of a metal material that shields electromagnetic waves, and the width of the gasket 400 may be determined to correspond to an area overlapping the shielding plate 300 and the shielding plate at the edge of the shield room vent.

6 is a cross-sectional view illustrating the ventilation device coupled to the shield room according to the embodiment of the present invention by a fastening bolt.

As shown in Figure 6, one side of the ventilation device for blocking electromagnetic waves may be installed in the shield room side and the other side is connected to the external ventilation pipe side. First, one side of the ventilator is a fastening bolt 120 is a connection hole of the shield room shielding plate 500, the gasket fastening hole of the gasket 400, the shielding body 300 and the shield receiving frame ( Through the shield room fastening holes of 100) in sequence can be coupled to the shield room side by screwing. Here, the ventilation hole of the shield room is ventilated with the outside ventilation pipe side by the shielding body 300 having a honeycomb structure that can block the electromagnetic waves while passing air, and the operator can simply and the shielding room fastening hole of the shield receiving frame 100 Equipment and installations that have been put in place than when installed by conventional soldering by simply coupling the respective fastening holes of the shield 300, the gasket 400, and the shield room shielding plate 500 which are aligned and formed using the fastening bolts 120. In terms of time, it is possible to efficiently install the ventilation device in which the electromagnetic shielding body is accommodated.

On the other hand, the other side of the ventilating device penetrates the connection hole formed in one side 51 of the ventilation pipe fastening hole 210 of the ventilation pipe connection part 200 and the ventilation pipe 50 connected to the heater or the cooler. The screw can be connected to the external ventilation pipes easily. On the other hand, when the external ventilation pipe 50 and the shield room are connected through a ventilation device, in order to prevent the mechanical vibration or current transmitted through the ventilation pipe connected to the external heater or the cooler from being transmitted to the shield room side. A packing 600 made of rubber or silicon material having flexibility and insulation may be inserted between the one side 51 of the ventilation pipe 50 and the ventilation pipe connecting part 200. Meanwhile, when the ventilation device is connected to the shield room side and the external ventilation pipe side, the shield receiving frame 100 and the ventilation pipe connecting part 200 are connected to each other in a 'c' shape, and the fastening bolt is installed when the ventilation device is installed using the fastening bolt. Installation work can be performed efficiently by minimizing the space required.

Therefore, the shield room can pass the air through the ventilation device including the electromagnetic shield 300 and the gasket 400, but can block the electromagnetic waves, and can be easily installed by using the fastening bolt at the same time by the packing 600 By preventing vibrations and currents transmitted along the air duct from the outside, a space completely independent from the external electromagnetic environment or the like can be completed.

The present invention has been described in detail with reference to exemplary embodiments, but those skilled in the art to which the present invention pertains can make various modifications without departing from the scope of the present invention. Will understand.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

100: shielding body accommodating frame 110: shield room fastening hole
200: Tungbang pipe connecting portion 210: Ventilation pipe fastening hole
300: shield 400: gasket
401a: outer end 401b: inner end
402: fastening area 410: gasket fastening hole
500: shield plate

Claims (3)

A shield accommodating frame accommodating the shield and having a shield room fastening hole formed therein so that a fastening bolt is inserted to connect to one side of an edge of the shield room vent;
Ventilation pipe connecting portion is formed integrally with the shield receiving frame in the 'c' shape, the ventilation pipe connecting hole is formed to connect to the ventilation pipe connected to the external air conditioner or heater and
The shield receiving frame includes a gasket for blocking the electromagnetic wave flowing into or out of the coupling gap when combined with the edge shield plate of the shield room vents,
The shield consists of a hexagonal honeycomb structure,
Ventilation pipe connection is a ventilation device for shielding electromagnetic waves, characterized in that the rubber packing is inserted to prevent vibration and insulation when connecting the one side of the ventilation pipe connected to the external air conditioner or the heater and the fastening bolt. delete delete

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