KR101159718B1 - Electromagnetic pulse protection apparatus - Google Patents

Abstract

PURPOSE: An electromagnetic wave protecting apparatus is provided to protect a load facility from EMP(Electromagnetic Pulse), EMI(Electromagnetic Interference), and lightning surge. CONSTITUTION: An electromagnetic wave protecting apparatus comprises an input side excessive phenomenon suppressing part(110), an input side wave filter(120), a common mode rejection transformer(130), an output side wave filter(140), and an output side excessive phenomenon suppressing part(150). The input side excessive phenomenon suppressing part is connected to a power source and a load facility in parallel and restricts excessive voltage and excessive current provided from the power source. The input side wave filter is serially connected between the power source and the load facility and filters high frequency output from the input side excessive phenomenon suppressing part. The common mode rejection transformer is serially connected between the power source and the load facility and removes a common portion of electromagnetic waves generated in a power line and a neutral line from the input side wave filter. The output side wave filter is serially connected between the power source and the load facility and filters high frequency output from the common mode rejection transformer. The output side excessive phenomenon suppressing part is connected between the power source and the load facility in parallel and restricts excessive voltage and current provided from the output side wave filter to the load facility.

Description

Electromagnetic wave protection device {ELECTROMAGNETIC PULSE PROTECTION APPARATUS}

The present invention relates to an electromagnetic wave protection device, and more particularly, to an electromagnetic wave protection device installed between a power supply and a load facility to protect a load facility from electromagnetic pulse (EMP), electromagnetic interference (EMI) and lightning surge (Lightning surge). It is about.

Electromagnetic pulse (EMP) bombs are also called E-bombs, and the threat is very serious when such EMP weapons are used on the battlefield.

The future war is being developed as an information-driven warfare concept that paralyzes the enemy's warfare function by destroying enemy command control and information system, the center of warfare, and EMP weapons use electricity by generating electromagnetic waves of tremendous power like nuclear explosions. It is very dangerous in that almost all load equipments, for example, advanced electronic communication information equipments, various control measuring equipments, automobiles, electronic clocks, etc. can be made obsolete, which can cause economic turmoil near disaster.

The general electric field of EMP is 200 은 / m, nuclear electromagnetic wave (Nuclear EMP) is 50㎸ / m @ 500km, and the analytical expression shows that the field of HEMP (High-Altitude EMP) is the electric field intensity E (V / m) of time t. It is expressed by the following equation (1) as a function of (s).

In addition, the magnetic field H (A / m) is time t It is expressed as Equation 2 as a function of.

Plotting the HEMP waveform results in a waveform having a 90% rise time of 5 ms, a peak value of 50 ms / m, and a time span of 0.2 ms of half the peak value at a pulse value of 10%.

Here, Equation 1 is the basis of the threat waveform in designing the protection, and the energy density w is expressed by the following Equation 3.

When the above equations 1 and 2 are applied, the energy density w is 0.9 J / m ² .

This results in a physical analysis that results in an energy pulse of 0.9J when a loop antenna with a cross-sectional area of 1 m ² is placed perpendicular to the direction of EMP propagation, which is enough energy to destroy most small signal high-frequency TRs or ICs.

Such EMP bombs can generate high-energy electromagnetic pulses, which can completely disable electronic systems in large areas, and have a huge impact on electronic equipment on the ground and underground, causing various loads to be incapacitated, causing great confusion and danger. have. Along with these EMP bombs, the electromagnetic effects of microwave explosions and microwave weapons are high-frequency characteristics. Therefore, it is necessary to provide an EMP-protective system that is suitable for the high-frequency characteristics of EMPs.

Background art of the present invention is disclosed in the 'EMP protective cabinet' of Republic of Korea Patent Registration 10-0990828 (2010.10.22).

The present invention was created to improve the above-mentioned problems, and is installed between the power supply and the load facility to protect the load facility by blocking and eliminating electromagnetic pulse (EMP), electromagnetic interference (EMI), and lightning surge (Lightning surge). The purpose is to provide an electromagnetic wave protection device.

Electromagnetic wave protection device according to an aspect of the present invention is connected to the power supply and load equipment in parallel to the input side transient suppression unit for suppressing the overvoltage and overcurrent supplied from the power source; An input side filter unit connected in series between the power supply and the load facility to filter a high frequency output from the input side transient suppressing unit; An in-phase elimination transformer unit connected in series between the power supply and the load facility to remove an in-phase portion of a signal waveform of electromagnetic waves generated at each of the power line and the neutral line from the input side filter unit; An output side filter unit connected in series between the power supply and the load facility to filter a high frequency output from the in-phase elimination transformer unit; And an output transient suppression unit connected in parallel with the power supply and the load facility to suppress overvoltage and overcurrent supplied from the output side filter unit to the load facility.

The apparatus may further include an enclosure for protecting the input transient suppression unit, the input side filter unit, the in-phase elimination transformer unit, the output side filter unit and the output side transient suppression unit from magnetic induction.

The input side transient suppression unit of the present invention is a constant voltage unit for blocking the overvoltage; A switch to cut off the electrical system when the constant voltage unit is short-circuited to generate an overcurrent; And a magnetic body protecting the constant voltage unit and the switch from magnetic induction, wherein the constant voltage unit and the switch are connected in series with each other and are connected between a power line and a ground, and a neutral line and a ground, respectively.

The input filter unit of the present invention, the feed-through filter is provided on each of the power line and the neutral line; A shunt resistor having one side connected to a ground terminal of each of the feedthrough filters and the other side connected to the power line and the neutral line respectively connecting the feedthrough filter and the load facility; And an input side filter housing for protecting the feedthrough filter and the shunt resistor from magnetic induction.

The in-phase removal transformer unit of the present invention is installed on the power line and the neutral wire in-phase removal transformer for removing the in-phase components generated in the power line and the neutral wire; And a pair of capacitors installed at both sides of the in-phase elimination transformer.

The output side filter unit of the present invention, the feed-through filter is provided on each of the power line and the neutral line; A shunt resistor having one side connected to a ground terminal of each of the feedthrough filters and the other side connected to the power line and the neutral line respectively connecting the feedthrough filter and the power source; And an output side filter housing for protecting the feedthrough filter and the shunt resistor from magnetic induction.

The output side transient suppression unit of the present invention is a constant voltage unit for blocking the overvoltage; A switch to cut off the electrical system when the constant voltage unit is short-circuited to generate an overcurrent; And a magnetic body protecting the constant voltage unit and the switch from magnetic induction, wherein the constant voltage unit and the switch are connected in series with each other and are connected between a power line and a ground, and a neutral line and a ground, respectively.

The present invention prevents malfunction and damage of the load facility by protecting electromagnetic waves such as electromagnetic pulse (EMP), electromagnetic interference (EMI) and lightning surge (Lightning surge) in the power supply or electronic equipment, thereby operating the load equipment Reduce cost

In addition, the present invention can reduce the manpower for operating the load facility by protecting the EMP and EMI and lightning surge.

1 is a block diagram of an electromagnetic wave protection device according to an embodiment of the present invention.
2 is a circuit diagram of an electromagnetic wave protection device applied to a one-phase two-wire power supply system according to an embodiment of the present invention.
3 is a circuit diagram of an electromagnetic wave protection device applied to a three-phase four-wire power supply system according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, an electromagnetic wave protection device according to an embodiment of the present invention will be described in detail. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

1 is a block diagram of an electromagnetic wave protection device of the power supply method according to an embodiment of the present invention, Figure 2 is a circuit diagram of the electromagnetic wave protection device applied to a one-phase two-wire power supply system according to an embodiment of the present invention, 3 is a circuit diagram of an electromagnetic wave protection device applied to a three-phase four-wire power supply system according to an embodiment of the present invention.

As shown in FIGS. 1 and 2, an electromagnetic wave protection device of a one-phase two-wire power supply system according to an embodiment of the present invention includes an input transient suppression unit 110, an input side filter unit 120, and an in-phase elimination transformer. The unit 130, an output side filter unit 140, an output side transient suppression unit 150, and an enclosure 160.

The electromagnetic wave protection device protects the load facility 200 from an external strong electromagnetic field caused by an EMP (Electromagnetic pulse) bomb or the like, and over current, overvoltage, noise, etc. induced between the power source 300 and the load facility 200.

To this end, the input side transient suppression unit 110, the input side filter unit 120, the in-phase elimination transformer unit 130, the output side filter unit 140 and the output side transient suppression unit 150 is a power supply 300 and load It is installed between the facility 200, the input transient suppression unit 110 is connected in parallel to the power supply 300 and the load facility 200, the input side filter unit 120 is the power supply 300 and the load facility 200 Is connected in series, the in-phase removal transformer unit 130 is connected in series to the power supply 300 and the load facility 200, the output side filter unit 140 is connected in series to the power supply 300 and the load facility (200) The output transient suppression unit 150 is connected in parallel to the power supply 300 and the load facility 200.

The electromagnetic wave protection device may be employed in both the 1-phase 2-wire power supply system and the 3-phase 4-wire power supply system.

Here, the load facility 200 includes all facilities that use electricity, such as electrical and electronic equipment, information and communication equipment, signal control equipment, broadcast fire fighting equipment. Therefore, it can be used in various fields such as defense electronic warfare weapon system.

The electromagnetic wave protection device of the present invention can be applied to the above-described one-phase two-wire power system, but can also be applied to the three-phase four-wire power system. An electromagnetic wave protection device of a three-phase four-wire power supply method will be described in detail with reference to FIG. 3.

First, the electromagnetic wave protection device applied to the one-phase two-wire power supply method according to an embodiment of the present invention is the input transient suppression unit 110, the input side filter unit 120, the in-phase removal transformer unit 130, the output side filter Base 140, the output side transient suppression unit 150 and the enclosure 160.

The input transient suppression unit 110 suppresses and blocks overvoltages and overcurrents such as transients and lightning surges of electromagnetic waves such as EMP (Electromagnetic pulse) and EMI (Electromagnetic Interference).

To this end, the input transient suppression unit 110 is connected in parallel between the power supply 300 and the load facility 200, the switch (111a, 111b) and the constant voltage element (112a, 112b) and the input side transient suppression unit enclosure (113).

The switches 111a and 111b and the constant voltage elements 112a and 112b are disposed in series with each other and connected between the power supply line L and the ground GND, and the neutral line N and the ground GND, respectively.

That is, the switch 111a and the constant voltage element 112a are connected between the power line L and the ground GND, and the switch 111b and the constant voltage element 112b are disposed between the neutral line N and the ground GND. Connected. Therefore, when the constant voltage elements 112a and 112b are shorted and an overcurrent occurs, the switches 111a and 111b are switched to cut off the electrical system.

Here, the switches 111a and 111b may employ a thermally sensitive fuse or an overcurrent breaker.

The constant voltage elements 112a and 112b include a gas discharge tube (GDT), a metal oxide varistor (MOV), a zener diode, a silicon controlled rectifier (SCR), and a varistor (varistor). Varistor, Triac and Arrester may be employed.

The input side transient suppressing unit enclosure 113 is installed outside the switches 111a and 111b and the constant voltage elements 112a and 112b so that the switches 111a and 111b and the constant voltage elements 112a and 112b are prevented from mechanical shock or magnetic induction. Protect. To this end, the input transient suppression unit enclosure 113 is formed of any one or more of a nickel alloy (permalloy), iron, silicon steel, which is a strong magnetic material for magnetic shielding.

The input filter 120 filters high frequencies due to transients and lightning surges of electromagnetic waves, such as electromagnetic pulse (EMP) and electromagnetic interference (EMI).

To this end, the input side filter unit 120 includes feedthrough filters 121a and 121b, shunt resistors 122a and 122b, and the input side filter unit enclosure 123.

Feedthrough filters 121a and 121b are provided on the power line L and the neutral line N, respectively.

That is, the feed-through filter 121a is installed at the power line L, one side of which is connected to the power source 300 side, the other side of which is connected to the load facility 200 side, and the ground terminal is connected to the ground GND.

Feed-through filter 121b is installed in the neutral wire (N), one side is connected to the power supply 300 side, the other side is connected to the load facility 200 side and the ground end is connected to the ground (GND).

The shunt resistors 122a and 122b are provided between the ground terminals of the feedthrough filters 121a and 121b and the power supply line L and the neutral line N, respectively.

That is, one side of the shunt resistor 122a is connected to the ground terminal of the feedthrough filter 121a, and the other side thereof is connected to the power supply line L between the feedthrough filter 121a and the load facility 200.

One side of the shunt resistor 122b is connected to the ground terminal of the filter 121b, and the other side of the shunt resistor 122b is connected to the neutral line N between the feedthrough filter 121b and the load facility 200. Therefore, the impedance of each phase is matched to transfer the input signal to ground (GND).

The input side filter housing 123 protects the feed-through filters 121a and 121b and the shunt resistors 122a and 122b from external mechanical shocks and strong magnetic fields. To this end, the input side filter housing 123 is formed of at least one of nickel alloy (permalloy), iron, and silicon steel, which are strong magnetic materials for magnetic shielding.

The in-phase removal transformer unit 130 removes in-phase portions of signal waveforms of electromagnetic waves generated in the power line L and the neutral line N. The in-phase removal transformers 131a and 131b, the capacitor 132a, and the same phase are removed. And a phase elimination transformer compartment 133.

The in-phase elimination transformers 131a and 131b are formed of a ferrite core of a troidal type and are installed on the power line L and the neutral line N, respectively.

The capacitor 132a has one side connected to the power line L and the other side connected to the neutral line N. The capacitor 132a is installed in pairs on both sides of the in-phase elimination transformers 131a and 131b.

In this way, the in-phase elimination transformers 131a and 131b are provided at the power supply line L and the neutral line N, respectively, and a pair of capacitors 132a are arranged on both sides of the in-phase elimination transformers 131a and 131b. By being installed between the power line (L) and the neutral (N), it operates as a common mode rejection transformer for removing the in-phase of the EMP, EMI and lightning surge.

The in-phase elimination transformer unit housing 133 is installed outside the in-phase elimination transformers 131a and 131b and the capacitor 132a to remove the in-phase elimination transformers 131a and 131b and the capacitor 132a from mechanical shocks and external electric fields. Protect. The in-phase elimination modified base portion enclosure 133 is formed of a nonmagnetic material, and the nonmagnetic material includes any one or more of copper, aluminum, and stainless steel.

The output side filter unit 140 is formed symmetrically with the input side filter unit 120.

The output side filter unit 140 filters the high frequency of the signal output from the in-phase elimination transformer unit 130 by the transient phenomenon and the lightning surge of electromagnetic waves such as EMP and EMI.

To this end, the output side filter unit 140 includes feedthrough filters 141a and 141b and shunt resistors 142a and 142b and an output side filter unit enclosure 143.

The feed-through filters 141a and 141b are provided on the power supply line L and the neutral line N, respectively.

That is, the feed-through filter 141a is installed in the power line L, one side is connected to the power supply 300 side, the other side is connected to the load facility 200 side, and the ground end is connected to the ground (GND).

The feed-through filter 141b is installed in the neutral line N, one side of which is connected to the power supply 300 side, the other side of which is connected to the load facility 200 side, and the ground terminal is connected to the ground GND.

The shunt resistors 142a and 142b are provided between the ground terminals of the feedthrough filters 141a and 141b and the power supply line L and the neutral line N, respectively.

That is, one side of the shunt resistor 142a is connected to the ground terminal of the feedthrough filter 141a, and the other side thereof is connected to the power supply line L between the feedthrough filter 141a and the power supply 300. One side of the shunt resistor 142b is connected to the ground terminal of the feedthrough filter 141b, and the other side of the shunt resistor 142b is connected to the neutral line N between the feedthrough filter 141a and the power supply 300. Therefore, the impedance of each phase is matched to transfer the input signal to ground (GND).

The output side filter housing 143 protects the feed-through filters 121a and 121b and the shunt resistors 142a and 142b from external mechanical shocks and strong magnetic fields. To this end, the output side filter unit enclosure 143 is formed of at least one of nickel alloy (permalloy), iron, and silicon steel, which are strong magnetic materials for magnetic shielding.

The output transient suppression unit 150 is formed symmetrically with the input transient suppression unit 110.

The output transient suppression unit 150 suppresses transients caused by overvoltage and overcurrent supplied from the output filter unit 140 to the load facility 200 by EMP, EMI, and lightning surge.

To this end, the output transient suppression unit 150 is connected in parallel between the power supply 300 and the load facility 200, the switch (151a, 151b) and the constant voltage device (152a, 152b) and the output transient suppression unit enclosure 153.

The switches 151a and 151b and the constant voltage elements 152a and 152b are connected in series to each other and are connected between the power supply line L and the ground GND, and the neutral line N and the ground GND, respectively.

That is, the switch 151a and the constant voltage element 152a are connected between the power line L and the ground GND, and the switch 151b and the constant voltage element 152b are disposed between the neutral line N and the ground GND. Connected. Therefore, when the constant voltage elements 152a and 152b are shorted and an overcurrent occurs, the switches 151a and 151b are switched to cut off the electrical system.

Here, the switches 151a and 151b may employ a thermally sensitive fuse or an overcurrent breaker.

The constant voltage elements 152a and 152b include a gas discharge tube (GDT), a metal oxide varistor (MOV), a zener diode, a silicon controlled rectifier (SCR), and a varistor (varistor). Varistor, Triac and Arrester may be employed.

The output side transient suppressing unit housing 153 is installed outside the switches 151a and 151b and the constant voltage elements 152a and 152b, so that the switches 151a and 151b and the constant voltage elements 152a and 152b are not subjected to mechanical shock or strong external force. Protect from magnetic fields To this end, the output transient suppression unit enclosure 153 is formed of any one or more of a strong magnetic material of nickel alloy (permalloy), iron, silicon steel for magnetic shielding.

Enclosure 160 protects the input transient suppression unit 110, the input side filter unit 120, the in-phase elimination transformer unit 130, the output side filter unit 140 and the output side transient suppression unit 150 as This includes both magnetic materials for magnetic shielding and nonmagnetic materials for electrostatic shielding.

Here, the magnetic material includes at least one of nickel alloy (permalloy), iron, and silicon steel, and the nonmagnetic material includes at least one of copper, aluminium, and stainless steel.

In the above embodiment, an example in which the electromagnetic wave protection device is applied to the 1-phase 2-wire power system has been described. The electromagnetic wave protection device can also be applied to a three-phase four-wire power system. This will be described with reference to FIG. 3.

As shown in FIG. 3, the electromagnetic wave protection device applied to the three-phase four-wire power system includes an input transient suppression unit 210, an input side filter unit 220, an in-phase elimination transformer unit 230, and an output side filter unit 240. ), The output transient suppression unit 250 and the enclosure 260.

In the electromagnetic wave protection device applied to the three-phase four-wire power supply system, the operation and installation structure of the one-phase two-wire power supply system are the same. That is, the transient suppression unit 210, the input side filter unit 220, the in-phase elimination transformer unit 230, the output side filter unit 240, and the output side transient suppression unit 250 are each power line L1, L2, It is installed corresponding to L3). This installation structure is outlined.

The input transient suppression unit 210 includes switches 211a, 211b, 211c, and 211d, constant voltage elements 212a, 212b, 212c and 212d, and an input side transient suppression unit enclosure 213 formed of a magnetic material, and includes a switch. The 211a, 211b, 211c and 211d and the constant voltage elements 212a, 212b, 212c and 212d are connected in series with each other to connect the power lines L1, L2, L3, the neutral line N and the ground GND, respectively. Connected.

Input side filter unit 220 is a feed-through filter (221a, 221b, 221c, 221d), a shunt resistor (222a, 222b, 222c, 222d) and a magnetic body on each of the power lines (L1, L2, L3) and the neutral (N). And an input side filter housing 223 formed therein.

The feed-through filters 221a, 221b, 221c, and 221d are installed on the power lines L1, L2, L3 and the neutral wire N, respectively, one side of which is connected to the power source 300 side and the other side of the load facility 200. ) And the ground terminal is connected to ground (GND).

One side of the shunt resistors 222a, 222b, 222c, and 222d is connected to the ground terminal of the feedthrough filters 221a, 221b, 221c, and 221d, and the other side is connected to the feedthrough filters 221a, 221b, 221c, 221d and the load facility ( It is connected to the power lines L1, L2, L3 and the neutral line N between 200, respectively.

The in-phase elimination transformer portion 230 includes an in-phase elimination transformer portion 231a, 231b, 231c and 231d, capacitors 232a, 232b and 232c, and an in-phase elimination transformer portion enclosure 233 formed of a nonmagnetic material.

The in-phase elimination transformers 231a, 231b, 231c, and 231d are formed of a ferrite core of a troidal type and are installed on the power lines L1, L2, L3 and the neutral line N, respectively.

The capacitors 232a, 232b, and 232c are respectively provided between the power supply lines L1, L2, L3 and the neutral line N on each side of each of the in-phase elimination transformers 231a, 231b, 231c, and 231d.

The output side filter unit 240 has a feed-through filter 241a, 241b, 241c, 241d, a shunt resistor 242a, 242b, 242c, 242d and a magnetic material on each of the power lines L1, L2, L3 and the neutral line N. And an input side filter housing 243 formed therein.

The feed-through filters 221a, 221b, 221c, and 221d are installed on the power lines L1, L2, L3 and the neutral wire N, respectively, one side of which is connected to the power source 300 side and the other side of the load facility 200. ) And the ground terminal is connected to ground (GND).

One side of the shunt resistors 222a, 222b, 222c, and 222d is connected to the ground terminal of the feedthrough filters 221a, 221b, 221c, and 221d, and the other side is connected to the feedthrough filters 221a, 221b, 221c, and 221d and the power supply 300. Are respectively provided on the power lines L1, L2, L3 and the neutral line N between them.

The output transient suppression unit 250 includes switches 251a, 251b, 251c, and 251d, constant voltage elements 252a, 252b, 252c and 252d, and an output side transient suppressor housing 253 formed of a magnetic material. The 251a, 251b, 251c and 251d and the constant voltage elements 252a, 252b, 252c and 252d are connected in series to each other to connect the power lines L1, L2, L3, the neutral line N and the ground GND, respectively. Connected.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. Will understand. Accordingly, the technical scope of the present invention should be defined by the following claims.

100: electromagnetic wave protection device
110, 210: input transient suppression unit
111a, 111b, 211a-211d: switches
112a, 112b, 212a to 212d: constant voltage devices
113, 213: housing of input transient suppression unit
120, 220: input filter unit
121a, 122b, 221a-221d: feedthrough filter
122a, 122b, 222a-222d: shunt resistor
123, 223: housing the input filter unit
130, 230: phase inversion denaturation base
131a, 131b, 231a-231d: in-phase elimination transformers
132a, 132b, 232a ~ 232c: capacitor
133, 233: in-phase elimination denaturation base enclosure
140, 240: output filter unit
141a, 142b, 241a-241d: feedthrough filter
142a, 142b, 242a to 242d: Shunt Resistance
143, 243: housing the output filter unit
150, 250: output transient suppression unit
151a, 151b, 251a-251d: switch
152a, 152b, 252a-252d: constant voltage device
153, 253: housing of output transient suppression unit

Claims (7)

An input side transient suppression unit connected in parallel with a power supply and a load facility to suppress overvoltage and overcurrent supplied from the power source;
An input side filter unit connected in series between the power supply and the load facility to filter a high frequency output from the input side transient suppressing unit;
An in-phase elimination transformer unit connected in series between the power supply and the load facility to remove an in-phase portion of a signal waveform of electromagnetic waves generated at each of the power line and the neutral line from the input side filter unit;
An output side filter unit connected in series between the power supply and the load facility to filter a high frequency output from the in-phase elimination transformer unit; And
An output side transient suppression unit connected in parallel with the power supply and the load facility to suppress overvoltage and overcurrent supplied from the output side filter unit to the load facility,
The input side transient suppression unit includes a constant voltage unit for blocking an overvoltage, a switch for shutting off an electrical system when the constant voltage unit is short-circuited, and a magnetic body for protecting the constant voltage unit and the switch from magnetic induction, and the constant voltage The unit and the switch are connected in series with each other, the electromagnetic wave protection device, characterized in that connected between the power line and ground and the neutral and ground, respectively. The apparatus of claim 1, further comprising an enclosure for protecting the input transient suppression unit, the input side filter unit, the in-phase elimination transformer unit, the output side filter unit, and the output side transient suppression unit from magnetic induction. Electromagnetic wave protection device. delete The filter of claim 1, wherein the input filter unit
A feed-through filter installed at each of the power line and the neutral line;
A shunt resistor having one side connected to a ground terminal of each of the feedthrough filters and the other side connected to the power line and the neutral line respectively connecting the feedthrough filter and the load facility; And
And an input side filter housing housing for protecting the feed-through filter and the shunt resistor from magnetic induction. According to claim 1, wherein the in-phase removal denaturation unit portion
An in-phase elimination transformer installed on the power line and the neutral line to remove in-phase components generated in the power line and the neutral line; And
Electromagnetic wave protection device comprising a pair of capacitors installed on both sides of the in-phase elimination transformer. The filter of claim 1, wherein the output filter unit
A feed-through filter installed at each of the power line and the neutral line;
A shunt resistor having one side connected to a ground terminal of each of the feedthrough filters and the other side connected to the power line and the neutral line respectively connecting the feedthrough filter and the power source; And
And an output side filter housing for protecting the feed-through filter and the shunt resistor from magnetic induction. The method of claim 1, wherein the output side transient suppression unit
A constant voltage unit for blocking an overvoltage;
A switch to cut off the electrical system when the constant voltage unit is short-circuited to generate an overcurrent; And
A magnetic material protecting the constant voltage unit and the switch from magnetic induction,
The constant voltage unit and the switch is connected in series with each other, the electromagnetic wave protection device, characterized in that connected between the power line and ground and the neutral and ground, respectively.

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