KR100783056B1 - surge protect device - Google Patents

Abstract

An object of the present invention is to have a fast reaction rate and a large surge energy absorption resistance when a high voltage surge voltage / current is introduced through a communication and signal line.

A feature according to the invention is a surge protection device for a line comprising a line (L1L1 ') consisting of an input (L1) and an output (L1') and a line (L2L2 ') consisting of an input (L2) and an output (L2'). The multi-stage surge protectors are installed in parallel between the line L1L1 'and the line L2L2' from an input terminal to an output terminal.

Surge Protection, Raster, Parallel, Multistage

Description

Surge protect device

1 is a configuration diagram of a general communication line.

2 is a circuit diagram of a conventional surge protection device.

3 is a circuit diagram of still another example of a conventional surge protection device.

4 is a circuit diagram of a surge protection device according to an embodiment of the present invention.

Fig. 5 is a signal waveform diagram of each part of a circuit for explaining the operation of one embodiment of the present invention.

The present invention relates to a surge protection device for a communication line that protects a communication device in use at a later stage from an abnormal transient voltage / current induced in a communication and signal line due to an indirect brain.

Due to lightning strikes, building structures have been damaged and human injury accidents have been occurring worldwide. Recently, the frequency of lightning strikes with increasing weather conditions is also increasing in Korea. In addition, indirect lightning is induced to the communication and signal lines by the direct lightning strike, which causes a lot of damage to the communication equipment connected to the line.

1 is a configuration diagram of a general communication line.

1 is IEC 62305-5 (brain protection of incoming equipment), and equipment (M) such as a multiplexer and an optical communication unit is installed between an exchange station (E) and a terminal station (S), and a communication terminal device is provided in the exchange station (E). (T _E ), the main distribution box (MDF) is installed, the terminal station (S) is installed line terminal device (LT), network terminal device (NT), communication terminal device (T _E ) and these communication facilities are indirect You will be affected by lightning. Therefore, in order to protect these facilities, protection against indirect lightning is necessary.

In order to reduce the damage caused by the indirect brain of various communication equipment connected to the communication and signal lines, there is a method of replacing overhead lines with underground lines, using shielded cables, applying surge protectors, and applying cables with high impulse withstand voltage. In this way, the breakdown of the cables can be suppressed and the equipment connected to the communication and signal lines can be reduced.

However, the point where the electromagnetic environment changes drastically, such as the connection point of the shielded and unshielded cable, the entry point of the building, the connection point of the overhead line and the underground line, and the connection point of the cable with different insulation strength, the equipment connected to the communication line and the line A surge protector is needed at the point where the difference in insulation resistance is large, such as the connection part of, because a surge surge effect is large.

2 is a circuit diagram of a conventional surge protection device.

A pair of rasters AR1 and AR2 are provided in the communication lines L1 and L2 of Fig. 2, respectively. The raster AR1 has a pair of connection terminals AR1-a, AR1-b and a ground terminal AR1-c, and the raster AR2 has a pair of connection terminals AR2-a. ), (AR2-b) and ground terminal (AR2-c). The connection terminals AR1-a and AR1-b of the raster AR1 are connected to the communication line L1, and the connection terminals AR2-a and AR2-b of the raster AR2 are the communication lines. It is connected to the furnace L2, and the ground terminals AR1-c and AR2-c are connected and grounded.

The rasters AR1 and AR2 protect the line by discharging the voltage induced in the line by the indirect brain to the ground side through the gas charged inside the raster, but the response speed is slow and the surge energy absorption resistance is small, so the surge protection It has the disadvantage that the effect is not high.

3 is a circuit diagram of still another example of a conventional surge protection device.

In the surge protector illustrated in FIG. 3, varistors VA11, VA12, VA21, and VA22 are connected in series to the connection terminals of the pair of rasters AR1 and AR2 illustrated in FIG. 2. Since the varistors have a high reaction rate and large capacity, they are installed to compensate for the slow reaction speed and small capacity of the aster.

However, in this configuration, the reaction rate of the varistor is fast, but the overall reaction rate is slow because the speed of the series of rasters is slow.

In addition, since the varistor is capacitive, there is a problem of providing a cause of noise when installed in the communication line.

The present invention has been made to solve this problem, and an object of the present invention is to have a fast response rate and a large surge energy absorption resistance when a high voltage surge voltage / current is introduced through a communication and signal line.

A feature according to the invention is a surge protection device for a line comprising a line (L1L1 ') consisting of an input (L1) and an output (L1') and a line (L2L2 ') consisting of an input (L2) and an output (L2'). : Between the line L1L1 'and the line L2L2', a multi-stage surge protector is installed in parallel from an input terminal to an output terminal, and the surge protector of the first stage adjacent to the input terminal is the input terminal L1 and the input terminal ( L2) is connected to each of the connection terminal, the ground terminal comprises an aster to the ground, the second stage surge protector adjacent to the surge protector of the first stage is installed, the first stage and the second stage surge The lines connecting the protector are provided with an impedance for delaying the surge output from the surge protector of the first stage.

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In addition, in the present invention, the surge protector of the second stage includes an raster, the raster of the surge protector of the first stage is larger in surge resistance than the raster of the surge protector of the second stage, It is preferable that the raster of the surge protector of the second stage has a fast reaction rate with respect to the raster of the surge protector of the first stage.

Further, in the present invention, the surge protector of the second stage is preferably composed of a switching raster and a transient voltage suppression element interposed between the switching raster and the lines.

In the present invention, it is preferable that the raster of the surge protector of the first stage is a gas-filled raster.

Hereinafter, an embodiment of the present invention according to the accompanying drawings will be described in detail.

4 is a circuit diagram of a surge protection device according to an embodiment of the present invention.

4 shows a line of a communication line composed of a line L1L1 'consisting of an input terminal L1 and an output terminal L1', and a line L2L2 'consisting of an input terminal L2 and an output terminal L2'. Multiple stages of surge protection devices are provided in parallel between L1L1 ') and line L2L2'.

The surge protection element of the first stage provided at the portion adjacent to the input terminal L1 and the input terminal L2 is a gas-filled triode raster AR3. The contact terminal AR3-a of the raster AR3 is connected to the line L1L1 ', the contact terminal AR3-b of the raster AR3 is connected to the line L2L2', and the raster AR3 Ground terminal (AR3-g) is grounded.

The surge protection device of the second stage is provided at the rear end of the surge protection device of the first stage.

In addition, an impedance Z1 is provided between the connection point (node ①) of the first stage surge protection device and the line L1L1 'and the connection point (node ②) of the second stage surge protection device and the line L2L2'. The impedance Z2 is provided between the connection point of the surge protection element of the first stage and the connection point of the surge protection element of the second stage of the line L2L2 '.

The surge protection device of the first stage adopts a gas-filled triode raster with a slow speed but a large surge resistance, so that the surge spreads to the rear stage but is delayed by the impedances Z1 and Z2, and the surge of the second stage. The protection device does not have a large surge resistance, but it can be operated quickly to absorb the surge.

Impedances (Z1) and (Z2) are constructed using inductors of several mH when the frequency of the equipment to be protected is less than several hundred KHz, and inductive resistors of 1 ohm or less are applied to equipment using frequencies of several MHz. use.

The second surge protection device includes a gas-filled switching raster AR4 having a fast reaction rate, a transient voltage suppressor TVS1 installed between the raster AR4 and the line L1L1 ', the asterisk AR4 and It consists of a transient voltage suppressor TVS2 provided between the lines L2L2 '.

Since the switching raster AR4 of the second surge protection device generates a short circuit when a surge voltage is introduced, transient voltage suppressors TVS1 and TVS2, which are semiconductor devices that clamp voltage in series, are installed. This limits the transient voltage to below a certain voltage.

Further, a third surge protection device is provided at the rear end of the second surge protection device. The third surge protection device has the fastest reaction speed, and is composed of transient voltage suppressors TVS3 and TVS4 connected in series between lines L1L1 'and L2L2'.

In addition, a transient voltage suppress device TVS5 connected between the line L1L1 'and the line L2L2' of the output terminal, which is the rear end of the third surge protection device, is formed.

At this time, the ground terminals of the rasters AR3 and AR4, the connection points of the voltage suppressing elements TVS3 and TVS4, and the ground terminal of the voltage suppressing element TR5 are grounded.

Reference numerals F1 and F2 denote fuses installed in the case where the rasters AR3 and AR4 are burned out in a short circuit, and TH1 and TH2 are thermal relays operated by heat.

As such, the operation of the configured embodiment will be described with reference to FIG. 5.

Fig. 5 is a signal waveform diagram of each part of a circuit for explaining the operation of one embodiment of the present invention.

5A shows lightning voltages applied to the input terminals L1 and L2.

At this time, the applied surge voltage is generated from NoiseKEN's lightning generator (Model: LSS-6130). At this time, the lightning occurs according to the standard of IEEE C62.41 (1991), and has an applied voltage of 1.2X50uS, 6KV, an applied current of 8X20uS, 3KA, and an output impedance of 2Ω.

Such surge voltage is absorbed by the surge protector of the first stage. 5b shows that the highest voltage is reduced to 216V with the voltage measured at node ①.

The surge protector of the first stage is a raster (AR3), so the reaction rate is slow, so it spreads along the track and goes to the rear stage. At this time, the impedances Z1 and Z2 delay the surge spreading to the rear stage and absorb the delayed surge in the surge protector of the second stage.

The raster AR3, which is a surge protector of the first stage, is a gas-filled triode raster, which has a large surge absorption capacity and a slow reaction rate, but the raster AR4 used for the surge protector of the second stage is a gas filled type. Triode switching raster with small surge absorption capacity but fast response speed. In addition, these rasters AR3 and AR4 do not generate noise in the communication line with a capacitance of several pF.

In the second stage, the transient voltage suppressors TVS1 and TVS2 respond to the surge in a rapid manner to weaken the surge energy more stably. This weakened node ② is shown in Figure 5c, it can be seen that the maximum value of the surge voltage at this time is 200V.

In addition, the surge passing through the second stage is stabilized by the surge protectors of the third stage and the final stage (node ③), and thus has a voltage waveform as shown in FIG. 5D.

The present invention solves the problem of using a raster as a surge protector in a conventional communication line, a problem of slow response speed and small capacity, and a problem of increasing noise when using a varistor mixed with a large load without noise. It has the effect of absorbing surges.

Claims (5)

A surge protection device for a communication line comprising a line (L1L1 ') consisting of an input terminal (L1) and an output terminal (L1') and a line (L2L2 ') consisting of an input terminal (L2) and an output terminal (L2'): said line (L1L1) ') And the line (L2L2') is provided with a multi-stage surge protector in parallel from the input terminal to the output terminal, The surge protector of the first stage adjacent to the input terminal includes an aster to which a connection terminal is connected to the input terminal L1 and the input terminal L2, respectively, and a ground terminal is grounded, and adjacent to the surge protector of the first stage. A second stage surge protector is installed, and the lines connecting the first stage and the second stage surge protector are provided with an impedance for delaying the surge output from the surge protector of the first stage. Surge protector. delete The surge protector of claim 1, wherein the surge protector of the second stage includes an raster, and the raster of the surge protector of the first stage has a larger surge resistance than the raster of the surge protector of the second stage. And the raster of the two-stage surge protector has a fast reaction rate with respect to the raster of the first-stage surge protector. 4. The surge protective device according to claim 3, wherein the surge protector of the second stage comprises a switching raster and transient voltage suppression elements interposed between the switching raster and the lines. 2. The surge protector of claim 1 wherein the raster of the surge protector of the first stage is a gas filled raster.

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