KR102205603B1 - Nomal Monitering System for Shielding Effect of EMP Protective Facilities - Google Patents

Abstract

The present invention EMP shielding effect constant monitoring system is installed outside the shielded area, an RF signal generator that generates an RF signal and transmits it to the RF signal amplifying unit and the RF signal distribution unit, and received from the RF signal generation unit. An RF amplification unit that amplifies the RF signal and radiates it to the shielded area through a leaky coaxial cable, a SW switch that turns on and off the transmission of the RF signal by being connected in series to the rear end of the RF amplification unit, and receives from the RF amplification unit. A leaky coaxial cable installed outside the shielded area to radiate RF signals to the shielded area, an RF signal distribution and switching unit that distributes the RF signal received from the RF signal generator and transmits it to the RF / optical signal converter, and the RF signal distribution And an RF/optical signal conversion unit that converts the RF signal received from the switching unit into an optical signal and transmits it to the optical/RF signal conversion unit using an optical cable, and converts the optical signal received through the optical cable into an RF signal to the RF transmission unit. In the optical/RF signal conversion unit to be transmitted, the RF transmission unit that radiates the RF signal converted from the optical/RF signal conversion unit to the shielded area, and the RF signal transmitted from the RF transmission unit or leaky coaxial cable installed inside the shielded area. The RF receiver that receives the radiated RF signal and the RF signal generator are controlled to generate an RF signal, and the RF signal distribution and switching unit is controlled to turn SW on or off, or other SW2 to SWN switches are turned on with a time difference. Controls to turn on or off or turn on or off multiple switches at the same time, control to convert RF signals into optical signals by controlling the RF/optical signal conversion unit, and control the optical/RF signal conversion unit to convert optical signals to RF signals Shielding to determine shielding defects by controlling to convert to and radiating the converted RF signal through the RF transmitter, and to determine the shielding defect by receiving the RF signal received from the RF receiver installed inside the shielding area and comparing the received signal strength with the reference shielding strength. Characterized in that consisting of an effect analysis unit will be.

Description

Normal monitoring system for shielding effect of EMP protective facilities {Nomal Monitoring System for Shielding Effect of EMP Protective Facilities}

The present invention constantly monitors the shielding facility to prevent the strong electromagnetic pulse (EMP) generated when the EMP (Electromagnetic Pulse effect) bomb explodes from entering the shielding facility where electronic devices and communication control facilities are installed. It's about doing.

The prior art related to the present invention is disclosed in Korean Patent Registration No. 10-1336833 (announcement on Dec. 04, 2013). 1 is a block diagram of the conventional protection facility shielding effect monitoring system. In Fig. 1, the conventional protection facility shielding effect monitoring system is installed at a predetermined distance along the outer wall of the protection wall 40, and an external coaxial cable 10 and a protection wall 40 radiating RF signals generated by a signal generator connected to one end. ) The shielding effect of the protection wall 40 by using an internal coaxial cable 20 that is installed at a predetermined distance along the inner wall circumference and receives the RF signal, and the received RF signal connected to one end of the internal coaxial cable 20 It may be configured to include an analysis unit 30 for analyzing the analysis unit 30 and a display unit 50 for displaying the analysis result of the shielding effect of the analysis unit 30 to the outside. First, the external coaxial cable 10 may be installed at a certain interval along the outer perimeter of the protective wall 40 of the EMP (Electromagnetic Pulse) protection facility, and may be installed, for example, several meters (m) apart. One end of the external coaxial cable 10 is connected to the signal generator and the signal amplifier 13, and a terminating resistance 11 may be connected to the other end.

The conventional technology configured as described above can monitor the shielding effect of the protection facility, but there is a problem in which it is not possible to know whether the shielding is defective in any part of the protection facility. In addition, the conventional technology configured as described above has a problem in that when the shielding is defective, it is necessary to find the defective point again while moving the shielding analyzer. Accordingly, an object of the present invention is to firstly check the shielding defects of the protective equipment and, in the case of failure, to find out the defect points in detail secondarily. In addition, another object of the present invention is to reliably cope with failure of analysis equipment by duplexing a shielding detection facility based on an optical cable in parallel with a leaky coaxial cable. In addition, another object of the present invention is to prevent attenuation of the RF signal toward the terminal by converting the transmitted RF signal into an optical signal and transmitting it, thereby effectively monitoring the shielding over the entire shielding area.

The shielding effect constant monitoring system for the EMP protection facility of the present invention having the above object is installed outside the shielded area, and generates an RF signal and transmits it to the RF signal amplification unit and the RF signal distribution unit, and the RF An RF amplification unit that amplifies the RF signal received from the signal generator and radiates it to the shielded area through a leaky coaxial cable, and a SW switch that turns on and off the transmission of RF signals by being connected in series to the rear end of the RF amplification unit, A leaky coaxial cable installed outside the shielded area to radiate the received RF signal to the shielded area, an RF signal distribution and switching unit that distributes the RF signal received from the RF signal generator and transmits it to the RF / optical signal converter, and RF The RF/optical signal conversion unit converts the RF signal received from the signal distribution and switching unit into an optical signal and transmits it to the optical/RF signal conversion unit using an optical cable, and an RF signal by converting the optical signal received through the optical cable into an RF signal. An optical/RF signal conversion unit transmitted to the transmission unit, an RF transmission unit that radiates the RF signal converted by the optical/RF signal conversion unit to the shielded area, and an RF signal or leakage coaxial transmitted from the RF transmitter as installed inside the shielded area The RF receiver that receives the RF signal radiated from the cable and the RF signal generator are controlled to generate RF signals, and by controlling the RF signal distribution and switching unit, SW is turned on or off, or other SW to SWN switches are set for time difference. It controls to turn on or off, or to turn on or off a plurality of switches at the same time, control the RF/optical signal converter to convert the RF signal into an optical signal, and control the optical/RF signal converter to convert the optical signal. Controls to convert to RF signal so that the converted RF signal radiates through the RF transmitter, receives the RF signal received from the RF receiver installed inside the shielding area, and compares the received signal strength with the reference shielding strength to determine the shielding defect Characterized by consisting of a shielding effect analysis unit Is to do.

The shielding effect constant monitoring system for the MP protection facility of the present invention configured as described above has the effect of being able to constantly monitor whether or not shielding defects inside the shielded area are present. In addition, another effect of the present invention is that RF signal attenuation at the terminal can be reduced by transmitting a signal using an optical cable, so that the terminal can accurately determine whether the shielding is defective. In addition, another effect of the present invention is that it is possible to determine whether there is a total shielding defect inside the shielding area, and that it is possible to determine whether or not the shielding defects for each point.

1 is a block diagram of a conventional protection facility shielding effect monitoring system
2 is a block diagram of a system for monitoring the shielding effect at all times for the present invention EMP protection facility,
3 is a detailed configuration diagram of a system for monitoring the shielding effect at all times for the present invention EMP protection facility,
4 is an exemplary diagram illustrating an installation of a system for monitoring the shielding effect at all times for the EMP protection facility of the present invention,
5 is a control flow chart for a method of constantly monitoring the shielding effect for the EMP protection facility of the present invention.

The system for monitoring the shielding effect of the present invention EMP protection facility having the above object will be described on the basis of FIGS. 2 to 5 as follows.

2 is a block diagram of a system for monitoring the shielding effect of the present invention for EMP protection facilities. In Fig. 2, the present invention EMP protection system for the shielding effect constant monitoring system generates an RF signal to radiate the RF signal to the shielded area and transmits the RF signal amplification unit and RF signal distribution unit to the RF signal generator 100 and , RF amplification unit 200 that amplifies the RF signal received from the RF signal generator and radiates it to the shielded area through a leaky coaxial cable, and is connected in series to the rear end of the RF amplification unit to turn on and off the transmission of the RF signal. Shielding effect by distributing the SW switch 210 to perform, the leaky coaxial cable 300 installed outside the shielding area to radiate the RF signal received from the RF amplifying unit to the shielding area, and the RF signal received from the RF signal generator. The RF signal distribution and switching unit 400 transmitted to the RF/optical signal converter according to the control of the analysis unit, and each RF signal received from the RF signal distribution and switching unit 400 are converted into optical signals using an optical cable. An RF/optical signal conversion unit 500 for transmitting to the optical/RF signal conversion unit, and an optical/RF signal conversion unit 600 for converting each optical signal received through an optical cable into an RF signal and transmitting it to the RF transmission unit, An RF transmitter 700 that radiates each RF signal converted by the optical/RF signal converter to the shielded area, and each RF signal transmitted from the RF transmitter or radiated from a leaky coaxial cable as installed inside the shielded area The RF receiver 800 for receiving signals and the RF signal generator are controlled to generate RF signals, and the RF signal distribution and switching units are controlled to turn on or off the SW1 to SWN switches, and a plurality of switches are simultaneously controlled. It controls to turn on or off, controls the RF/optical signal converter to convert the RF signal into an optical signal, and controls the optical/RF signal converter to convert the optical signal into an RF signal, and the converted RF signal Radiation through the RF transmitter, based on the strength of the RF signal received from the RF receiver installed inside the shielded area It is characterized by consisting of a shielding effect analysis unit 900 that determines the shielding failure by comparing the shielding strength value. A terminating resistor is provided at the end of the leaky coaxial cable.

3 is a detailed configuration diagram of a system for monitoring the shielding effect of the present invention for EMP protection facilities. In FIG. 3, the present invention EMP protection system for the shielding effect constant monitoring system generates an RF signal to radiate the RF signal to the shielded area and transmits the RF signal amplification unit and RF signal distribution unit to the RF signal generator 100 and , RF amplification unit 200 that amplifies the RF signal received from the RF signal generation unit and radiates the RF signal to the shielded area through a leaky coaxial cable, and is connected in series to the rear end of the RF amplification unit. The SW switch 210 that turns on and off, the leaky coaxial cable 300 installed outside the shielding area to radiate the RF signal amplified by the RF signal amplifying unit to the shielding area, and the RF signal received from the RF signal generator A switch (SW1 ~ SWN) that distributes 1:N (where N is the number of transmitting antennas) and transmits n RF signals to the RF/optical signal converter and turns on and off the distributed RF signal transmission under the control of the shielding effect analysis unit. RF signal distribution and switching unit 400 installed in series, and each of the RF signals received from the RF signal distribution and switching unit 400 is converted into an optical signal and each optical/RF signal using each optical cable An RF/optical signal conversion unit 500 for transmitting to the conversion unit, an optical/RF signal conversion unit 600 for converting each optical signal received through each optical cable into an RF signal and transmitting it to each RF transmission unit, and an optical The RF transmission unit 700, which includes n transmission antennas 710, radiates each RF signal converted by the /RF signal conversion unit to the shielded area, and is installed inside the shielded area and is transmitted from the RF transmission unit. Receiving each RF signal or RF signal radiated from a leaky coaxial cable, n receiving antennas 810, and n receiving switches (RSW1) that are attached in series to each receiving antenna and block signal reception when excessive RF signals are input. ~RSWN) and the RF receiver 800 consisting of n RF receivers 820 connected in series to each switch, and RF signal generation Controls to generate RF signals by controlling the unit, and controls the RF signal distribution and switching unit to turn on and off SW, and to turn on or off SW1 to SWN switches, or simultaneously turn on or off a plurality of switches among SW1 to SWN switches. The converted RF signal is controlled to convert an optical signal into an RF signal by controlling the RF/optical signal conversion unit and controlling the RF/optical signal conversion unit to convert the RF signal into an optical signal. The RF signal is received by the RF receiver installed inside the shielding area, and the strength of the received signal is compared with the reference shielding strength to determine the shielding defect. If excessive received signals are received, the corresponding reception switch of the RF receiver is turned on. It is characterized in that it is made of a shielding effect analysis unit 900 that is controlled to be off.

4 is an exemplary diagram illustrating the installation of a system for constant monitoring of shielding effects for the EMP protection facility of the present invention. In FIG. 4, the installation of the shielding effect constant monitoring system for the EMP protection facility of the present invention includes the shielding area 1000 surrounding the shielding area, the RF signal generation unit 100, and the RF signal generated by the RF signal generation unit. RF signal distribution and switching unit that amplifies and transmits to the leaky coaxial cable 300 to radiate to the shielded area, distributes the RF signal and transmits the distributed RF signal to the RF/optical signal conversion unit under the control of the shielding effect analysis unit ( 400), an RF/optical signal conversion unit 500 that converts the RF signal transmitted from the RF signal distribution and switching unit into light, and the converted RF signal after receiving the converted optical signal through an optical cable and converting it into an RF signal. The optical/RF signal conversion unit 600 that transmits the signal to the RF transmission unit, and the RF signal converted by the optical/RF signal conversion unit is received and radiated from each point to the shielding area. Includes an RF transmitter 700 comprising a plurality of RF transmission antennas 710, and a plurality of RF receivers 820 respectively receiving RF signals radiated from the RF transmitter installed at points that are weak points inside the shielded area. The RF receiver 800 and the RF signal distribution and switching unit 400 are controlled to transmit the RF signal to the leaky coaxial cable to be radiated, distribute the RF signal, and convert the distributed RF signal to the RF/optical signal. Controls the optical signal converted by transmitting to the part to be transmitted through an optical cable, and controls the optical/RF signal converter to convert the optical signal into an RF signal, and controls it to radiate to the shielded area through the RF transmitter, and analyzes the RF signal received from the RF receiver. Thus, it is characterized in that it is made of a shielding effect analysis unit 900 that determines the shielding failure of each point.

5 is a control flow chart for a method of constantly monitoring the shielding effect for the EMP protection facility of the present invention. In FIG. 5, the method of constantly monitoring the shielding effect for the EMP protection facility of the present invention includes a step (S11) of generating an RF signal from an RF signal generator and radiating it to the shielded area through a leaky coaxial cable (S11), and a multi-point RF receiver. Comparing the RF received signal strength received from the RF receiving unit and the reference shielding strength to determine the shielding defect of the shielding area (S12), and if it is determined that the shielding is defective, the RF signal generated by the RF signal generator is distributed. And transmitting the RF signal to the RF/optical signal converter by turning on the switch SW1 associated with each RF transmitter installed at the first point, which is a weak point (S13), and the RF/optical signal converter converting the RF signal into an optical signal. And transmitting the converted optical signal to an optical/RF signal converter through an optical cable (S14), and the optical/RF signal converter converts the optical signal into an RF signal and transmits the RF signal through an RF transmission antenna installed at the first point. Radiating to the shielding area (S15), receiving the RF signal through the RF receiving antenna installed at the first point inside the shielding area, and transmitting the received RF signal to the shielding effect analysis unit (S16), and analyzing the shielding effect Comparing the additionally received RF signal strength and the reference shielding strength to determine whether the shielding is defective (S17), and sequentially performing steps S13 to S17 from the second point, which is another weak point, to detect the shielding defect point It is characterized in that made, including. In the above, the first point specifies the point where the transmission antenna outside the shielded area related to the SW1 switch is installed, but another point can be selected as the first point, and the remaining points can also be determined in an arbitrary order. There is. In addition, in the above, the reference shielding strength may vary depending on the installed protection equipment in the shielding area, and may be based on 80dB. In addition, when the received signal exceeds the input allowable value in step S17, the receiving switch is turned off and terminated to prevent damage to the RF receiver.

100: RF signal generation unit, 200: RF amplification unit,
300: leaky coaxial cable, 400: RF signal distribution and switching unit, 500: RF/optical signal conversion unit, 600: optical/RF signal conversion unit,
700: RF transmitter, 800: RF receiver,
900: shielding effect analysis unit

Claims (5)

In the continuous monitoring system for the shielding effect of the EMP protection facility to protect the facility installed inside the shielded area by dualizing the shielding detection facility based on the optical cable composed of leaky coaxial cable and juxtaposed,
The shielding effect constant monitoring system for the EMP protection facility to protect the facility installed inside the shielded area by dualizing the shielding detection facility,
An RF signal generator 100 for generating an RF signal to radiate the RF signal to the shielding area and transmitting the RF signal to the RF signal amplifying unit and the RF signal distribution unit;
An RF amplification unit 200 for amplifying the RF signal received from the RF signal generator and radiating it to the shielded area through a leaky coaxial cable;
A SW switch 210 connected in series to the rear end of the RF amplifying unit to turn on and off transmission of an RF signal;
A leaky coaxial cable 300 installed outside the shielded area to radiate the RF signal received from the RF amplifying unit to the shielded area;
A switch (SW1) that distributes the RF signal received from the RF signal generator and transmits it to the RF / optical signal converter under the control of the shielding effect analysis unit. It distributes the RF signal to 1: N and turns on and off the distributed RF signal transmission (SW1). An RF signal distribution and switching unit 400 to which to SWN) is connected;
An RF/optical signal conversion unit 500 for converting each RF signal received from the RF signal distribution and switching unit 400 into an optical signal and transmitting the converted RF signal to an optical/RF signal conversion unit using an optical cable;
An optical/RF signal conversion unit 600 for converting each optical signal received through an optical cable into an RF signal and transmitting the converted optical signal to an RF transmission unit;
An RF transmitter 700 for radiating each RF signal converted by the optical/RF signal conversion unit to the shielding area;
An RF receiver 800 that is installed inside the shielded area and receives each RF signal transmitted from the RF transmitter or RF signal radiated from the leaky coaxial cable;
And control to generate RF signals by controlling the RF signal generator, control to turn on or off SW1 to SWN switches by controlling the RF signal distribution and switching units, control to simultaneously turn on or off a plurality of switches, and control RF/optical The signal conversion unit is controlled to convert the RF signal into an optical signal, the optical/RF signal conversion unit is controlled to convert the optical signal into an RF signal, and the converted RF signal radiates through the RF transmitter, and the shielding area A facility installed inside the shielding area by dual shielding detection facilities, characterized in that it consists of a shielding effect analysis section 900 that determines shielding defects by comparing the strength of the RF signal received from the RF receiving section installed inside with a reference shielding strength value Shielding effectiveness for EMP protection facilities to protect the system.
Where N is the number of transmit antennas.
The method of claim 1,
The RF receiver 800,
A receiving antenna 810 for receiving each RF signal transmitted from the RF transmitter or an RF signal radiated from the leaky coaxial cable;
A receiving switch installed in series on the receiving antenna and blocking signal reception when excessive RF signal is input;
And an RF receiver (820) connected in series to the receiving switch. The shielding effect constant monitoring system for EMP protection facilities for protecting facilities installed inside the shielded area by double shielding detection facilities.
delete In the method of constantly monitoring the shielding effect of the EMP protection facility to protect the facility installed inside the shielded area by duplexing the shielding detection facility based on an optical cable composed of a leaky coaxial cable and a juxtaposition,
The method of constantly monitoring the shielding effect of the EMP protection facility to protect the facility installed inside the shielded area by double-doubling the shielding detection facility,
Generating an RF signal in an RF signal generator and radiating it to a shielded area through a leaky coaxial cable (S11);
Determining a shielding defect of the shielding area by comparing the RF received signal strength received by an RF receiver including a plurality of points of the RF receiver with a reference shielding strength (S12);
If it is determined that the shielding is defective, distributing the RF signal generated by the RF signal generator, turning on the switch SW1 associated with each RF transmitter installed at the first point, which is a weak point, and transmitting the RF signal to the RF/optical signal converter (S13) and;
An RF/optical signal converter converting the RF signal into an optical signal and transmitting the converted optical signal to an optical/RF signal converter through an optical cable (S14);
An optical/RF signal converter converting the optical signal into an RF signal and radiating the RF signal to the shielding area through an RF transmission antenna installed at an arbitrary first point (S15);
Receiving an RF signal through an RF receiving antenna installed at a first point inside the shielding area and transmitting the received RF signal to a shielding effect analyzer (S16);
Comparing the received RF signal strength and the reference shielding strength by the shielding effect analysis unit to determine whether the shielding is defective (S17);
And detecting a defective shielding point by sequentially performing steps S13 to S17 from the second point, which is another weak point, to protect the facilities installed inside the shielded area by duplexing the shielding detection facility. A method of constantly monitoring the shielding effectiveness of EMP protection facilities.
The method of claim 4,
The method of monitoring the shielding effect of the EMP protection facility at all times to protect the facility installed inside the shielded area by dualizing the shielding detection facility
In the step (S17) of determining whether the shielding is defective by comparing the strength of the received RF signal by the shielding effect analyzer with the reference shielding strength, when the received signal is excessive, the receiving switch is turned off and then terminated. A method of constantly monitoring the shielding effect of EMP protection facilities to protect the facilities installed inside the shielded area by redundancy.

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