SU1534602A1 - Test check for checking overvoltage protection of symmetric communication circuits equipment - Google Patents

Abstract

The invention relates to electrical engineering and is intended to test the effectiveness of the protection of communications equipment from overvoltages induced in communication lines by an internal electromagnetic field, for example, when lightning strikes. The purpose of the invention is to increase the efficiency of testing by simulating the mutual electromagnetic coupling between wires of a two-wire communication line. In the initial state, the voltage at pin 8 relative to the common pin 7 of the generator 6 and at the input pins 4 and 5 of the apparatus is absent. When the generator 6 is turned on up to the time point T _{1, the} voltage across pins 4 and 5 and the bits 12 and 13 connected to them increases relative to the ground. As a result, a voltage appears in the "two wires - ground" channel, and between terminals 4 and 5, i.e. There is no voltage in the wire-to-wire channel. At time T _1, the arrester with the lowest ignition voltage is triggered. The voltage on the appropriate pin 4 or 5 connected to this discharge is reduced to almost zero, and the voltage on the second discharge and other equipment connected to it is reduced by the amount of voltage drop across the resistor 11 due to current flowing through the resistor 11. If the wave voltage is low, then the second arrester does not work and in the "two wires - ground" and "wire - wire" channels the voltages operate for a long time, corresponding to the actual operating conditions of the equipment. 4 il.

Description

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low-voltage ignition voltage The voltage at the corresponding pin 4 or 5 connected to this battery lowers almost to zero, and the voltage from the second voltage and connected to a different output of the equipment decreases by the amount of voltage drop on

The invention relates to electrical engineering and is intended to test the effectiveness of the protection of communications equipment from overvoltages induced in communication lines by an external electromagnetic field, for example, during lightning strikes.

The purpose of the invention is to increase the efficiency of testing by simulating the mutual electromagnetic coupling between the wires of a two-wire communication line in a wide range of wave impedances of the working and additional channels.

FIG. 1 shows the scheme of the complex; in fig. 2 is a scheme for registering voltages at the input of the protected equipment; in fig. 3 oscillogram of voltages id 5 in the channel two wires - ground; in fig. 4 - the same, Unn in the wire-wire channel.

Complex 1 for testing the overvoltage protection of equipment 2 of a symmetric communication circuit, equipped with a common terminal 3 for grounding the first 4 and second 5 input terminals of a two-wire connection connected to the working communication channel and a wire and an additional channel Two wires - ground, in addition to the test apparatus 2, contains a generator of 6 pulsed voltages with the first pin 7 for connecting to the common pin 3 of the test apparatus 2 and the second pin 8, a simulator of a two-wire communication line, in which m odes first 9 and the second dividing resistor 10 each provided with a first terminal for connecting dividing resistors 9 and 10 respectively to the first 4 s 5 second input terminals of the test apparatus 2. The complex 1 has the resistor 11 communication connected between the second terminal of the generator 8

the resistor 11 due to the flow of current through the resistor 11. If the wave voltage is low, then the second arrester does not work and in the channels there are two wires - the earth and the wire - the wire for a long time act on the voltage corresponding to the actual operating conditions of the equipment. 4 il.

6 impulse voltages and combined second terminals of the separation resistors 9 and 10. Each of the separation resistors 9 and 10 is made with an active resistance Rp equal to half the wave impedance Znn of the working communication channel, and the resistor 11 is connected with an active resistance Rc equal to the difference between the impedance 2Лпз of the additional communication channel and one quarter of the impedance Zntl of the working channel Znn

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The apparatus 2 includes an overvoltage protection device, made in the form of arresters 12 and 13, connected between the input terminals 4 and 5 and the common terminal 3 at the input of the protected blocks 14. The voltage measurement in the wire-to-wire channel is performed by an oscilloscope 15, In the channel, two wires - ground oscilloscopes 16 and 17, the output terminals of the device 1 (resistors 9 and 10) are connected to the terminals 4 and 5 of the equipment 2, and the common terminal 7 of the generator 6 and the terminal 3 of the equipment 2 are connected and grounded.

The tests of the equipment are carried out in laboratory factory and field conditions in order to check the protection against dangerous overvoltages. The level of protection is determined by measuring the stresses on both the elements 12 and 13 of the protection, as well as the elements of the protection-on the blocks 14.

In the initial state, the voltage at pin 8 relative to the common pin 7 of the generator 6 and, accordingly, at the input pins 4 and 5 of the apparatus is absent. When you turn on the generator 6 to

the time point C (Fig. 3), the pin on terminals 4 and 5 and the adjuncts of the 12 and 13 on the ground are growing. As a result, the voltage of the UAn3B channel two appears

the wires are ground (fig. 3), and between pins 4 and 5, i.e. In the channel the wire-wire voltage U PP is absent (Fig. 4).

At time t, the arrester with the lowest ignition voltage is triggered (Uo, Fig. 3). The voltage on the corresponding pin 4 or 5 connected to this arrester decreases almost to zero, and the voltage on the second arrester and the other equipment output connected to it decreases by the amount of voltage drop across the resistor 11 due to current flowing through the resistor 11. The voltage between the terminals 4 and 5 in the wire-to-wire channel occurs only when the load is unbalanced, i.e. if the resistances of the terminals 4 and 5 are not equal to the common terminal 3. The magnitude of the voltage reduction is determined by the ratio of the resistances of the communication resistor 11 and the corresponding separation resistor 9 or 10, since the resistance of these resistors is much less than the input resistance of the blocks 14. If the voltage of the wave is small, then the second arrester does not work and in the channels two wires - ground and wire - wire are permanently energized

15346026

voltage - The wave impedances of the communication line are determined by the geometry of the circuit and can be determined by calculation or measurements on a real line. For a MPEVK-0 -1x4x1,2 type communication cable, the resistance of the communication resistor is Rc 15 Ohms, and the separation resistors are RD 75 Ohm each

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Claims (1)

Invention Formula Test set for overvoltage protection 15 equipments of symmetric communication circuits containing the equipment under test, equipped with a common grounding outlet, the first and second input pins for connecting to a two-wire 20th communication line performed with a working communication channel wire-to-wire and an additional communication channel two wires - ground , pulse voltage generator with the first output for connecting to the common output of the equipment under test and the second output and simulator of the two-wire communication line, made on the first and second separation resistors with the first terminals and 30 for connecting resistors to the first and second input pins of the equipment under test, respectively, with the difference between: To increase the efficiency of testing by simulating mutual electromagnetic coupling between the wires of a two-wire communication line in a wide range of impedances of the working and additional channels, 35 U A "uh and JJnn (fig. 3). Thus, the presence of a communication resistor 11 leads to a more severe test mode, corresponding to the actual operating conditions of the hardware device. The positive effect created by the invention is to increase the efficiency of the test by taking into account and modeling the mutual electromagnetic coupling between the wires of the communication line. The invention makes it possible to reproduce a near-real voltage in the wire — wire channel when voltage appears in The channel has two wires - ground and vice versa - its communication channel of the equipment under test. ten Invention Formula Test set for overvoltage protection equipments of symmetric communication circuits, containing the equipment under test, equipped with a common grounding outlet, the first and second input terminals for connecting to a two-wire communication line, made to the working communication channel, wire-to-wire, and an additional communication channel, two wires - ground, generator impulse voltages with a first output for connecting to the common output of the equipment under test and a second output and simulator of a two-wire communication line, made on the first and second separation resistors with the first leads to connect resistors to the first and second input pins of the equipment under test, respectively, in order to increase the test efficiency by simulating a mutual electromagnetic connection between the wires of a two-wire communication line in a wide range of impedances of the working and additional channels, An additional communication resistor is inserted into the complex, connected between the second output of the pulse voltage generator and the combined second terminals of the separation resistors, each of the separation resistors is made with an active resistance equal to half the impedance of the working communication channel of the equipment under test, and the connection resistor is made with an active resistance equal to the difference between the impedance of the additional communication channel and one quarter of the working impedance one FIG. 2 t, Fig.Z Fig4