SU1638671A1 - Device for determining a cable wire number - Google Patents

Abstract

The invention relates to the field of instrumentation technology and can be used to determine the number of individual conductors of a cable. The purpose of the invention, the extension of the field of application, is achieved by allowing the control of a large cable. The device contains the first 6 and second 1 generators, the first 8 and second 2 counters dividers, the first 9 and second 3 pulse counters, the first 10 and second 4 decoders, prohibition block 7, n elements OR, terminals 22 for connecting the wires of the cable being monitored, block 11 indications, indicator 14, first 12 and second 13 triggers, first 15, second 16, third 17 generators of a single pulse, key 18, probe 19, amplifier 20. 3 Cpf-ly, 2il. About $

Description

The invention relates to instrumentation and can be used to determine the numbers of individual cable wires.

The purpose of the invention is the expansion of the scope of the device by providing control cable, the ends of which are at a considerable distance.

In FIG. 1 shows a diagram of device 2 - temporary diameters: at characteristic points 10 for determining the nome (Fig. 1) it contains trigger 13, the switch (in Fig., Grams of voltage of the circuit.

Device for cable wire ra second generator 1, second counter divider 2, second counter 3 pulses, second decoder 4, elements OR 5.1-5.Π, first generator 6, block prohibition 7, first counter divider 8, first counter 9 pulses, first a decoder 10, an indication unit 11, a first trigger 12, a second indicator 14, a first ge; single pulse nerator 15, second single pulse generator 16, third single pulse generator 17, key 18, probe 19, amplifier 20. Figure 1 also shows a monitored cable 21 and terminals for connecting wires of a monitored cable.

The output of the first generator 6 is connected to the first input of the prohibition unit 7, the output of the first decoder 10 is connected to the first input of the display unit 11, the first output of the second pulse counter 3 is connected to the first input of the second decoder 4, the first _(the output of the probe 19 is connected to the input of the amplifier 20, the first the input of the first trigger 12 is connected to the output of the amplifier 20, the output of the first trigger 12 is connected to the second input of the block 7 of the ban and the first input of the second trigger 13, the output of block 7 of the ban is connected to the first input of the first counter-divider 8, the output of which is connected the input of the first counter 9 pulses, the output of which is connected to the input of the first decoder 10, the output of the second generator 1 is connected to the input of the second counter-divider 2, the output of which is connected to the input of the second counter 3 pulses, with the second input of the decoder 4, the third input of which is connected to the second the output of the second counter 3 pulses, the first output of the decoder 4 is connected to the first input of each of the η elements OR 5.1-5.P, each of the second outputs of the decoder 4 is connected to the second input of the corresponding element OR 5.1-5.П, the outputs of the elements of the IL 5.1-5.η are connected to the corresponding terminals for connecting the wires of the controlled cable, the output of the amplifier 20 is connected to the input of the first single pulse generator 15, the output of which is connected to the input of the second single pulse generator 16, the output of which is connected to the second input of the first trigger 12, second trigger 13, the first counter-divider 8, the first counter 9 pulses, the output of the second trigger 13 is connected to the first * input of the indicator 14 and to the third input of the prohibition unit 7, the output of the key 18 is connected to the second input of the display unit 11 and and cators 14, key input 18 is connected to the output of the third generator 17, a single pulse input coupled to an output of the first oscillator 15, a single pulse.

The device operates as follows.

The second generator 1 generates pulses that are input, the second counter-divider 2, where their frequency decreases by a factor of K, from the output of the second counter-divider 2 pulses are fed to the input of the second counter 3 pulses, which generates a sequence of binary codes at the outputs. From the output of the second counter 3 pulses, the sequence of binary codes is fed to the input of the second decoder 4, to the resolution inputs of which pulses are received from the second counter-divider 2 and from the output of the highest level of the second counter 3 pulses. The second decoder 4 converts the binary code of the second counter * 3 pulses into unitary and supplies the inputs of the OR 5.1-5.P elements, and the pulses of the first output of the second decoder 4 go to all OR 5.1-5.P elements, the pulses of the other outputs of the second decoder 4, starting from the third one, OR 5.1-5.P is supplied to each element, the outputs of the latter are connected to the known terminals 22.1-22.η for connecting the wires of the controlled cable 21. As a result, a sequence of two pulses is generated on each cable wire, the time interval m forward that carries information about the number of wires. After a period of time t ₃ (cycle time), a similar sequence of pulses is generated on each wire. The cycle time is 30,000 ms. For example, the timing diagram of the pulses on the first three wires is shown in figure 2, graphs 23, 24, 25. The maximum number of wires should not exceed TP / 2-2, where m is the number of states of the second counter 3 pulses.

I

The operator connects the probe 19 to one of the terminals 22.1-22.p. cable 21. When a signal appears at the output of the probe 19, the amplifier 20 amplifies it and the leading edge of the amplified pulse starts the first single pulse generator 15, which generates a duration pulse (counting time), shown in figure 2, graph 26, and 14 should not exceed half cycle time t ₃ . In turn, the pulse from the first single pulse generator 15 with its leading edge triggers the second single pulse generator 16, which generates a zero-setting pulse (Fig. 2, graph 27), which is fed to the zero-setting inputs of the first counter-divider 8, the first counter 9 pulses, the first and second triggers 12, 13, which go to the zero state. From the outputs of the triggers 12, 13, the inhibit block | 7 receives the enable signal levels, and the pulses from the first generator 6 through the inhibit block 7 go to the first counter divider 8 having a division coefficient K, and then to the first counter 9 pulses. When a second pulse arrives at the output of amplifier 20, the first trigger '12 switches and gives a ban signal to the input of block 7 and the pulses to the first counter 9 pulses are stopped. The number of pulses counted by the first 9 pulse counter corresponds to the number of the wire being detected. The timing diagram at the output of block prohibition 7 for the second wire number is shown in figure 2, graph 28.

1638671 ⁶

Impulse sec. the output of the single pulse generator 15 by a trailing edge (FIG. 2, graph 26) starts the single pulse generator 17, which generates a pulse of duration t ₂ (display time) shown in FIG. 2, graph 29, and t, + t ₂ must not be greater than t ₃ . The pulse from the output of the single-pulse generator 17 through the key 18 supplies the enable signal to the display unit 11 and indicator 14. From the output of the first counter 9 pulses, the binary decimal code is supplied to the input of the first decoder 10 and converted to the code necessary for the display unit 11. V the flow of time G. “display unit 1 1 and indicator 14 display information about the wire number and the presence of a short circuit between the tested wires, respectively. In the event of a short circuit between the tested wires at the input of the amplifier 20, at least a third pulse appears during the time Ts, which goes to the counting input of the first trigger 12 and switches it, the resolution level from the output of the first trigger 12 goes to the input of the inhibit block 7, but at the same time the pulse from the output of the first trigger 12 goes to the dynamic input of the second trigger 13 and switches it, the inhibit level from the output of the trigger 13 goes to the input of block 7 of the ban and prevents the passage of pulses from the output of the first g generator of 6. Thus, the state of the first pulse counter 4Q 9 is changed and it stores. the code of the wire number is connected first to the place. connection to the terminals from the interconnected wires of the cable 21 when connecting the probe 19 to any of the closed wires. The state of the second trigger, other than the initial one, indicates the presence of a short circuit between the wires and is displayed by an indi5Q motor M.

β case, when connecting the probe 19 to the cable wire 21, the second pulse of a sequence of two pulses will be detected at first, then 55, after passing a zero pulse from the output of a single pulse generator 16, the pulses will continuously enter the first pulse counter 9 and the readings of the inpeak block 11

tions will be false .. However, already in the second cycle of the device, synchronous operation will be restored and the device will give correct readings. Since the measurement frequency is 10-30 Hz, the false reading is invisible to the eye and does not cause inconvenience when working with the device. The graphs 30, 31, 32 show the pulses at the output of a single pulse generator 15, a single pulse generator 16 and a block 7, respectively, in the mode when the second pulse of a sequence of two pulses was first detected. When the operator connects the probe 19 to another wire, the device without any switching on the part of the operator will determine its number and check for a short circuit between the wires.

Thus, by introducing into the device the first generator 6 that generates the same frequency as the second generator 1, two divider counters 2 and 8, which have equal division factors, OR 5.1-5.-5 elements, three single generators 15, 16, 17 pulse and key 18 provides the definition of the cable wire number and the presence of a short circuit between the wires and allows the study of cables whose ends are at a considerable distance, which makes it possible to use the device, for example, during installation and operation with automation system in industrial facilities.

Claims (3)

Claim 1. A device for determining the number of cable wires, containing a first generator, the output of which is connected to the first input of the prohibition unit, a first pulse counter, a first decoder, the output of which is connected to the first input of the display unit, a second pulse counter, the first output of which is connected to the first input of the second a decoder, terminals for connecting wires of a controlled cable, a probe, the first output of which is connected to. the input of the amplifier, the first trigger ger, the first input of which is connected to. an amplifier output, the output of the first trigger is connected to the second input of the inhibit block and to the first input of the second trigger, an indicator, characterized in that, in order to expand the scope of application, a second generator, the first and second counters-dividers, the first and second generators of a single pulse ₇ η elements OR, where η is the number of monitored cable conductors, and the output of the prohibition block is connected to the first input of the first counter-divider, the output of which is connected to the input of the first pulse counter, the output of which is connected to the input of the first decoder, the output of the second generator is connected to the input of the second counter-divider, the output of which is connected to the input of the second pulse counter and the second input of the second decoder, the third input of which is connected to the second output of the second pulse counter, the first output of the second decoder is connected to the first input of each η OR elements, each of the second outputs of the second decoder is connected to the second input of the corresponding OR element, the outputs of the OR elements are connected to the corresponding terminals for connecting water of the controlled cable, the amplifier output is connected to the input of the first single pulse generator, the output of which is connected to the input of the second single pulse generator, the output of which is connected to the second input of the first trigger, second trigger, first counter-divider, first pulse counter ', the output of the second trigger is connected with the first input of the indicator and with the third input of the prohibition block. 2. The device according to claim 1, wherein the device contains a third single pulse generator and a key whose output is connected to the second input of the display unit and indicator, the key input is connected to the output of the third single pulse generator ·, whose input connected to the output of the first single pulse generator. 3. The device according to claim 1, characterized in that the first and second generators are made according to a scheme with quartz frequency stabilization.