KR20150144949A - Shielding Effectiveness measurement to optimize seperation distance between transmitting antenna and EMP shielding facility - Google Patents

Abstract

The present invention is to measure shielding effect even in the narrow space between an EMP shielding facility and an external concrete structure by replacing locations of transmitting and receiving antennas. That is, the transmitting antenna is arranged in the facility and the receiving antenna is arranged outside the facility in order to analyze the shielding effects. To achieve the above purpose, the present invention arranges the transmitting antenna inside and the receiving antenna outside to compare, measure, and test of shielding effect influence.

Description

TECHNICAL FIELD [0001] The present invention relates to a shielding effectiveness measurement apparatus for an EMP protection facility that optimizes a distance between a transmission antenna and an EMP protection facility,

The present invention relates to an apparatus for measuring the shielding effectiveness of an EMP protection facility, and more particularly, to a new methodology for increasing the efficiency of a space when measuring the shielding effect by changing the position of a transmitting / receiving antenna.

EMP (Electromagnetic Pulse) In order to satisfy the shielding requirement of electromagnetic wave which is one of the essential functions of the protection facility, the protection facility is constructed so that the electromagnetic wave (EMP) from outside can not penetrate. EMP shielding effectiveness tests are usually conducted on the protection facilities to ensure that the protection facilities have shielding capabilities. The shielding effectiveness test of internationally recognized protection facilities is mainly dealt with in military standards, and IEC international standards follow the military standards. The concept of shielding effect test is the same in military facilities and civil facilities. The shielding effect test frequency range, antenna distance, and judgment criteria are different. Although the shielding effectiveness test is described in the MIL specification, IEEE-STD-299 published in 2006 is the most detailed description of the private standard, whereas the IEC international standard is based on theory. At present, in order to calibrate the shielding effect test for the EMP protection facility according to MIL-STD-188-125-1 standard, the distance between the transmitting and receiving antennas should be at least 3.05 m. When measuring the shielding effect, The distance of the transmitting antenna shall be maintained at 2.0m and the receiving antenna shall be maintained at 1.00m. MIL-STD-188-125-1 The private description and other private specifications of this standard are shown in Table 1.

Shielding Effect Test Comparison between International Standard and Test Method division IEC 61000-4-23 MIL-STD-188-125-1 IEEE-STD-299 Year of publication 2000 2005 2006 Application field Private Facilities (EMP) Military facilities (HEMP) Private Facilities (EMC) Test frequency 15 kHz to 30 kHz: 1
300 kHz to 500 kHz: 1
1 MHz to 20 MHz: 1
50 MHz to 200 MHz: 3 10 kHz to 100 kHz: 20
100 kHz to 1 MHz: 20
1 MHz to 10 MHz: 40
10 MHz to 100 MHz: 150
100 MHz to 1 GHz: 150 9 kHz to 300 MHz: several
300 MHz to 600 MHz: 1
600 MHz to 1 GHz: 1
1 GHz to 2 GHz: 1
2 GHz to 4 GHz: 1
4 GHz to 8 GHz: 1
8 GHz to 18 GHz: 1 Transmitting and receiving antenna distance Loop Ant.
- Transmission: 0.955 m
- Reception: 5 ~ 60 cm
Dipole Ant.
- Transmission: 4.7 m
- Reception: 5 ~ 60 cm Loop / Bi-conical / LP Ant.
- Transmission: 2.05 m
- Reception: 1.0 m Loop Ant.
- Transmission: 0.3 m
- Reception: 0.3 m
Bi-conical / Dipole / Horn Ant.
- Transmission: 1.7 m
- Reception: 0.3 m Transmit antenna location Outside the facility Outside the facility Outside the facility Unit test area 2.5 m 2.5 m 3.05 m 3.05 m 2.6 m 1.5 m

A schematic diagram of a conventional EMP shielding facility shielding effect test will be described with reference to FIG. 1, the receiving unit 110 of the conventional experimental apparatus mainly includes a receiving antenna 111, a receiving unit signal generator 112, a receiving unit signal amplifier 113, a transmitting unit including a transmitting antenna 121, a transmitting unit signal generator 122 And a transmission signal amplifier 123, as shown in Fig. The measurement target is a rectangular parallelepiped with a size of 6.0m × 2.4m × 2.4m as an EMP protection facility. The N-type connector 101 is used as a path for connecting the cable of the transmitter and the receiver.

A biconical antenna is used in a test frequency range of 100 MHz to 300 MHz of the transmitting and receiving antennas 111 and 121, and an antenna is radiated in a range of 300 MHz to 1 GHz using a logarithmic periodic antenna. Typically, RF cables use coaxial cables to shield cables as much as possible from external electromagnetic radiation.

However, as shown in FIG. 1, in the conventional construction of the EMP protection facility, the concrete structure is first made and the EMP shielding room is built therein. EMP shielding rooms are generally placed adjacent to the outer concrete structure to place the wall of the shielding room because of the efficiency of the construction space and the cost of construction. It is common to place the walls of the shielded room adjacent to the EMP barrier facility wall and external concrete structures. The shielding effect measuring method of disposing the transmitting antenna on the outside is very practically impossible because the space between the wall surface of the EMP protection facility and the outer concrete structure is very narrow from about 10 cm to 1 m. Even in the case of EMP protection facilities built in the basement, there are some cases where the concrete structure is covered with earth and sand so that the shielding effect test is more impossible. It is also impossible to secure the external space of the EMP protection facility while consuming enormous construction costs for the shielding effectiveness test.

The present invention provides a shielding effect measuring apparatus for an EMP protection facility capable of measuring a shielding effect even when a space size between an EMP protection facility and an external concrete structure is small and reducing a construction cost of a building including a protection facility .

At the same time, the space between the wall and the ceiling of the EMP protection facility and the external concrete structure is currently being arbitrarily set. However, since the minimum separation distance can be suggested through the present invention, You will be able to set the size criterion.

A measuring device for differently arranging a transmitting and receiving antenna for measuring a shielding effect,

Disposing a transmitting antenna (221) inside and a receiving antenna (211) outside on the basis of a protection facility; Separating the transmitting antenna 221 from the protection facility at a distance of 2.05 m and the receiving antenna 211 at an interval of 1.00 m; Using a biconical antenna for transmitting and receiving antennas 221 and 211 in a frequency range of 20 to 300 MHz and using a logarithmic periodic antenna for transmitting and receiving antennas 221 and 211 in a frequency range of 300 M to 1 GHz;

The shielding effect measuring apparatus calculating method is a method of calculating a shielding effect measuring device by performing Fast Fourier Transform (FFT) on an amount of electromagnetic waves (Vm) received from a transmitting antenna and a quantity of electromagnetic waves (Vc) ) Is compared with a relative value according to a frequency to calculate a shielding effect by the following equation: The network generator 404 and the transducer 407 of the transceiver unit protect the electromagnetic wave radiated from the transmission antenna 401 as a shielding rack to shield the shielding effect of the EMP protection facility.

The experimental apparatus for disposing the transmission antenna provided in the present invention in the protection facility has an advantage that the shielding effect can be measured even when the space size between the EMP protection facility and the external concrete structure is narrow, It is excellent in that it can save money.

In addition, by analyzing the relationship between the test area and the antenna distance, it is possible to effectively reduce the measurement area size of the facility surface in the shielding effect test, thereby shortening the time for measuring the shielding effect for the entire facility.

FIG. 1 is a schematic view of a conventional EMP shielding facility experiment apparatus
2 is a schematic view showing an EMP protection facility shielding effect experiment apparatus of the present invention
3 is a perspective view of the EMP protection facility of the present invention
Figure 4 is a connection block diagram of the EMP shielding effect test facility of the present invention
5 is a flowchart of a shielding effect experiment applied in the present invention
Figs. 6 and 7 are graphs showing the results of comparison with the results of the conventional experiments for verifying the effectiveness of the shielding effect test method of the present invention

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

2 is a schematic view showing an EMP shielding facility testing apparatus of the present invention. Referring to FIG. 2, the EMP shielding effect measuring apparatus of the present invention will be described in detail. FIG. 2 is a diagram to which the methodology proposed in the present invention is applied. The technical principle of the present invention is that a transmitting antenna 121, which is located outside the facility (see FIG. 1), is installed inside the facility and radiated inside the facility to receive electromagnetic waves and measure the electromagnetic waves. As shown in FIG. 1 and FIG. 2, since the distance occupied by the experimental facility is reduced from 2.05 m to 1.00 m at the minimum transmission antenna distance, it can be seen that the present invention can make the experimental facility small.

3 is a perspective view of the EMP protection facility of the present invention. FIG. 3 illustrates an EMP protection facility to be measured. First, the system is configured as a car closing door 300 having a unique shielding effect of 90 dB or more, an N-type connector 301 connected to an antenna and a measuring device of a transmitting and receiving unit, and a gas pipe 303 capable of being connected to an external cable.

FIGS. 6 and 7 are comparative data with conventional experimental results to demonstrate the utility of the shielding effectiveness testing method of the present invention. 6 and 7, the validity of the EMP shielding effect test of the present invention is verified by comparing it with the results of the conventional experimental apparatus. First, the shielding effect of the EMP protection equipment can be presented through the following equation (1).

[Equation 1]

In the case of electromagnetic radiation from a transmitting antenna, the reception amount is expressed as a ratio (expressed in dB) under the condition of the absence of an electromagnetic shielding barrier against the reception amount of the receiving antenna with the electromagnetic shielding barrier

SE (Shielding Effectiveness) = 20 log (V _C / V _m ) [dB]

V _C : Measures in the same condition as calibration without electromagnetic shielding barriers

V _m : Measured quantity in the presence of an electromagnetic shielding wall

6 and 7, the difference of the shielding effect according to the position of the transmitting antenna was within 3 dB and the shielding effect difference was less than 5 dB at the frequency of 400 MHz or higher. The difference of the shielding effect within 5dB is converted to 5dB by the above equation, and the field intensity received from the outside of the transmitting antenna is 1.7 times smaller than the field intensity received from the outside. And a difference of 1.4 times in terms of 3 dB. The magnitude of the reception amount of the electromagnetic wave based on this data is not largely different and can be applied to the shielding effect test even when the transmission antenna proposed in the present invention is disposed inside.

4 is a connection block diagram of an EMP shielding facility testing facility in the present invention. The shielding effect test apparatus shown in FIG. 4 is a configuration diagram presented in the current MIL-STD-188-125-1 standard.

5 is a flowchart of a shielding effect experiment applied in the present invention. The overall design of the system is configured using the S / W program developed by Montenna, and the electromagnetic spectrum is converted into an optical signal by connecting the electromagnetic wave to the fiber / optics converter 406 using the network analyzer 404 . An optical cable and a coaxial cable end 409 having a shielding effect against an external electromagnetic wave for transmitting the converted signal, a preamplifier 402 for amplifying the present signal before reaching the antenna, Optic transducer 411 of the receiver so as to move the converted signal in the positive direction, an oscillator 415 for transmitting the radio signal, and a control unit 412 for transmitting the radio signal to the fiber / And a receiving antenna 417 for receiving the power amplifier 416 and the power amplifier 416.

The network generator 404 and the fiber / optic signal converter 411 of the transmission / reception unit are preferably affected by the electromagnetic waves radiated from the antenna to cause a malfunction. Therefore, it is preferable that the network generator 404 and the fiber / optics signal converter 411 are shielded as a shielding rack.

It is preferable to use a shielded cable that can protect the optical cable and coaxial cable 409 that transmits the electromagnetic wave to each end.

The influence of external noise and electromagnetic waves is minimized by using an optical cable for transmitting the electromagnetic wave from the transmitter to the receiver and a waveguide for passing the coaxial cable 409.

The transmit antenna 401 and the receive antenna 417 use a biconical antenna in the experimental frequency band of 20M to 300 MHz and a logarithmic period antenna in the 300 MHz to 1 GHz band.

Although it is not shown in the present invention, a loop antenna can be applied if a designer wants to carry out an experiment with a low frequency band of 20 MHz or less.

It is to be understood that the invention is not limited thereto and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims. It is expected that the technology capable of measuring the shielding effect even in the case where the external space is narrow through the present invention can set the size criterion for the installation space of the EMP protection facility and the ripple effect is very large.

100: Measurement protection facility
110: Receiving unit 111: Receiving antenna
112: Receiver amplifier 113: Receiver generator
120: Transmission unit 121: Transmission antenna
122: Transmitter amplifier 123: Transmitter generator
300: Car hood 301: N-type connector
302: Protection facility window 303: Gas pipe
401: Transmit antenna 402: Pre-Amplifier
403: coaxial switch 404: network analyzer / spectrum analyzer
405: transmitter GPIB connector 406: control computer
407: Transmitter fiber / optics converter 408: Parallel connector / relay control
409: Fiber / Optics Cable 411: Receiver Fiber / Optics Converter
412: Control section 413: Coaxial switch / relay control
414: Receiver GPIB connector 415: Oscillator
416: Power Amplifier 417: Receive antenna

Claims (4)

A measuring device for differently arranging a transmitting and receiving antenna for measuring a shielding effect,

(1) disposing a transmitting antenna 221 inside and a receiving antenna 211 outside, based on a protection facility;

(2) separating the transmitting antenna 221 from the protection facility by 2.05 m and the receiving antenna 211 by 1.00 m;

And a shielding effect measuring device The method according to claim 1,

Characterized in that a biconical antenna is used for the transmitting and receiving antennas (221, 211) in the frequency range of 20 to 300 MHz and a logarithmic period antenna is used for the transmitting and receiving antennas (221, 211) in the frequency range of 300 to 1 GHz The method according to claim 1,

The shielding effect measuring apparatus calculating method is a method of calculating a shielding effect measuring device by performing Fast Fourier Transform (FFT) on an amount of electromagnetic waves (Vm) received from a transmitting antenna and a quantity of electromagnetic waves (Vc) ) Is compared with a relative value according to the frequency, and the shielding effect is calculated by the following equation. ≪ EMI ID =
SE (Shielding Effectiveness) = 20 log (V _C / V _m ) [dB]
V _C : Measures in the same condition as calibration without electromagnetic shielding barriers
V _m : Measured quantity in the presence of an electromagnetic shielding wall The method according to claim 1,

The network generator 404 and the transducer 407 of the transceiver unit protect the electromagnetic wave radiated from the transmission antenna 401 as a shielding rack to shield the shielding effect of the EMP protection facility.

Images