SU515074A1 - Device for testing multi-pair cables - Google Patents

Description

one

The invention relates to measuring and measurement technology and can be used to control multi-pair telephone cables.

A device for testing multi-pair cables is known, comprising a measuring power supply, a switching unit, two test blocks and a display unit.

However, such a device has a complex circuit; in addition, for each pair of wires, a separate measuring power source and a high-resistance resistor, connected remotely, are required, which reduces the reliability of determining the type of fault.

The aim of the invention is to increase the reliability of determining the type of fault. For this purpose, an inverter, a coincidence unit, a memory unit and a decryption unit, as well as a frequency unit, are inserted into the device, the test pairs of wires, shorted at one end of the cable, are connected to the power source and test units, the outputs of which are simultaneously connected to the inputs of the memory and decryption unit, the frequency comparison unit and the coincidence element, the output of which is connected to the switching unit, while the output of one test unit is connected to the coincidence element via an inverter op and the output of the other directly, the outputs of the memory and decryption unit are connected to the switching unit and the display unit, and the inputs of the memory and decryption unit are connected to the communication unit and the frequency comparison unit.

The drawing shows a structural electrical circuit of the device.

The device for testing multi-pair cables contains pairs of h-1 ' wires shorted between each other at one end of the cable, measuring power supply 2, switching unit 3, test blocks 4 and 5, inverter 6, coincidence element 7, block 8 of memory and decoding, block 9 comparing the frequencies l block 10 of the display, the Ij-In pairs of the cable-free end are connected via block 3 to the common bus, source 2 and blocks 4 and 5, the outputs of which are connected respectively to the inputs of the inverter 6 and element 7, whose input connected to the output of the diverter 6, and the output not with the first control input of block 3; the outputs of blocks 4 and 5 are also connected respectively with the first and second inputs of blocks 8 and 9, the third and fourth inputs of block 8 are connected to the corresponding outputs of block 9, fifth

the input is to one of the outputs of block 3, and the first and second outputs are respectively to the second control input of block 3 and block 10.

The device works as follows. Through block 3 to block 5, a pair of li, for example, previously checked in a known manner and selected as a reference, is connected; Using block 3 to block 5, 12-In pairs are alternately connected to source 2, and the output of source 2 is connected to a common bus through series switched off, for example, test pair and a reference pair li, an equal-arm voltage divider is formed, with arms are the distributed resistances of the wires of the said pairs. The tripping thresholds of blocks 4 and 5 are set, respectively, to the difference And the sum of half the voltage and source 2 and the deviation of the voltage AU arising from the maximum allowable variation of the resistances of the pairs li and b. In the case of the serviceability of the tested pair, i.e., in the absence of a break, a ground fault, an entanglement with the wires of other pairs, the output of the said divider will establish a voltage

- from which only block 4 will work,

at the output of which, according to Wits, the logical zero signal. In this case, block 5 will save the state of the logical unit. Due to the presence of an inverter 6, the inputs of element 7 receive signals of a logical unit and it will give a signal to block 3 "and disconnecting the test pair la from source 2. At the same time, the inputs of blocks 4 and 5 are not bridged by the resistances of pairs 12 and li and they go to pulse generation mode, with the distributed capacitor la and Ij being the driving capacitor. The elements of blocks 4 and 5 are chosen so that, if the capacitances of the pairs C and li are equal, the generation frequency of block 4 is higher than that of block 5. If these capacities are within acceptable limits, block 8 of block 9 receives a signal including a health indication in block 10. At the same time, block 3 from block 8 is given a signal to connect the next pair b, and block 3, the signal is sent to reset the block 8 to the next initial polishing.

If the parameters of the tested bunker go beyond the permissible limits, the signal at the output of element 7 will be absent, and the signals from the outputs of blocks 4 and 5 through block 8 will turn on the indication of malfunction of block 10. To determine the type of malfunction, block 3 is forced to go the capacity of the tested pair, in the case of which the permissible limits of the unit 10 produces an indication of the corresponding fault. For example, if the insulation resistance decreases, the distributed capacitance of the tested pair will be bridged by the leakage resistance and unit 4 will not be able to generate pulses. If pairs of wires are reversed, then the tested pair will be broken and its distributed capacitance will be twice as large, since during the test the lara is short-circuited by block 3. The generation frequency of block 4 will change accordingly, and its change will be interpreted accordingly by blocks 8 and 9.

Claims (1)

Invention Formula A device for testing multi-pair cables containing a measuring power source, a switching unit, two test units and an indication unit, characterized in that, in order to increase the reliability of determining the type of fault, an inverter, a coincidence unit, a memory unit and a decryption unit are inserted into it, and also a frequency comparison unit, the test pairs of wires, shorted at one end of the cable, are connected via a switching unit to a measuring power source and to test blocks, the outputs of which are simultaneously connected The inputs to the memory and decryption unit, the frequency comparison unit and the matching element, whose output is connected to the switching unit, the output of one test unit connected to the coincidence element through the inverter, and the output of the other directly, the outputs of the memory and decryption unit are connected to the switching unit and the display unit, and the inputs of the memory unit and the decoding unit are connected to the switching unit and the frequency comparison unit.