SU1305061A2 - Device for measuring wear of contact system wire - Google Patents

Abstract

This invention relates to a measurement technique, relates to measuring the wear of contact wires on an electrified transport, and is an improvement to the author. St. No. 921900. The aim of the invention is to improve the measurement accuracy. Through the lens 1 and the fiber-optic converter 3, the image of the contact wires 2 gets to the television camera 4, which consists of the television tube 5, the horizontal scanning generator 6 and the vertical scanning generator 7. From the outputs of the television camera 4 and the height sensor 9, the signals are fed to the inputs of the scale converter 8. The control of the oscillators 6 and 7 is dried, the synchronization unit 10 is configured as a generator of rectangular pulses of constant frequency, amplitude and duty cycle, connected in series with divider 1 1 frequency, the output of which is connected to the inputs of the generators 6 and 7. Camera 4 is connected to the input of the key element 12. The device is equipped with measurement recording channels 14 and switching unit 13. 2 Il. F (L and-HIzH oo o ate o 05 N: Fig. 1

Description

The invention relates to a measurement technique, namely for measuring the wear of contact wires on an electrified transport, and is an improvement of the known device according to ed. St. No. 929100.

The purpose of the invention is to improve the measurement accuracy.

FIG. 1 shows the basic electrical circuit of the device; in fig. 2 is a timing diagram explaining the principle of operation and the sequence of signals passing according to the device circuit.

A device for measuring wear of a contact wire comprises a lens 1, which receives reflected rays from the contact wires 2, a fiber optic converter 3 associated with a television camera 4 consisting of a television tube 5, a horizontal scanning generator 6 and a vertical scanning generator 7, scaled th converter 8, height sensor 9 20, synchronization unit 10, frequency divider II, key element 12, switching unit 13 and measurement recording channels 14 according to the number of monitored contact wires 2, each of which from

ka 10 is fed to the first input of all elements 15. At the initial point of the scanning path of the electron beam of the tube 5, element 12 is in the initial state - - SRI, i.e. it is connected to the first channel 14 of the record. Therefore, the first signal 25 through element 12 passes to the third input of element 15 of the first recording channel 14, i.e. there is no signal at the third inputs of element 15 of all the other channels 14, 10 only one first recording channel 14 is activated, the counter 16 pulses signal 28 ("1st channel). The number of pulses transmitted to counter 16 is determined by the frequency of block 10 and the width of the first signal 25.

When the first signal 25 disappears, the latter, with its rear edge, switches element 12 to the second channel 14. Therefore, the second signal 25 passing through this element 12 enters the third input of element 15 of the second recording channel 14 and enters 16 of this channel 14 the number of pulses proportional to the frequency of the block 10 and the width of the second signal 25.

The back front of the second signal 25 ne15

series-connected elements And 25 switches off the key element 12 to the third 15, controlled counter 16 and element channel 14. Therefore, if in the field of view

MEMORY 17.

FIG. 2 shows the following signals: pulses 18 generated by synchronization unit 10, pulse sequence 30

A third pass appears in the optical system of the device, the third signal 25 caused by it enters the third channel 14, and so on.

At the end of the scanning trajectory of the electron beam of the television tube 5, i.e., at the end of the frame, the vertical scanning generator 7 generates a control signal 22 ("2nd output), which actuates the block 13. This block 13 generates

owls 19 - after frequency divider 11, signals 20 and 21, respectively, belong to generators 6 and 7 of line and frame sweeps, signal 22 is the output signal of frame sweep generator 7, signals 23 and 24 are short pulses, and "Reset 24 and "Record 23, the commutation is, respectively, the first and the second, respectively, to the control inputs of block 13, signal 25 is the output of converter 8, and signals 26 and 27 are the output pulses of element 12, signals 28 and 29 - impulses arriving at first first and second pulse counter 16, as determined by block 10.

The device works as follows.

Block 10, through a frequency divider 11, excites generators 6 and 7 of line and frame sweeps, which ensures the scanning trajectory from the initial tilt of the electron beam on the telescope screen, all the processes in the repetition tube circuit along the trajectory, respectively the same sequence. Behind

corresponding to the regular raster output of the existence of this frame, while in

the fiber optic transducer counter 16 accumulates information about

3. When a wire 2 is worn in the field of view, a two contact wire 2 50 (not shown) is recorded at the recording lens 1 and comes out of the outputs of element 12, counters 16 pulses and operational storage elements 17 in all channels 14. At that, element 12 40 is switched to the initial position (to the first channel), and the readings of the counters 16 of all the channels 14 are memorized in the elements 17.

During each subsequent frame, when the electron beam of the tube 5 begins

Yes, element 17 of each of the channels 14 wear information obtained in the previous frame.

In this way, a separate recording of the wear of several contact-cut large-scale transducer 8 of post-carrying wires 2 is ensured, observing the order of their alternation. The device also allows for improved measurement accuracy.

with different wear, two electric signals 25 (Fig. 2) are formed at the output of the television tube 5, and the width of each of them depends on the degree of wear of the corresponding wire 2. The signal 25 signals to the second input of the element 15 of all the recording channels 14, and the output signal

As 10 is fed to the first input of all elements 15. At the starting point of the scanning path of the electron beam of the tube 5, element 12 is in the initial state, i.e. it is connected to the first recording channel 14. Therefore, the first signal 25 through element 12 passes to the third input of element 15 of the first recording channel 14, i.e. there is no signal at the third inputs of element 15 of all the other channels 14, only one first recording channel 14 is activated, the counter 16 pulses signal 28 is received (“1st channel). The number of pulses transmitted to counter 16 is determined by the frequency of block 10 and the width of the first signal 25.

When the first signal 25 disappears, the latter, with its rear edge, switches element 12 to the second channel 14. Therefore, the second signal 25 passing through this element 12 enters the third input of element 15 of the second recording channel 14 and enters 16 of this channel 14 the number of pulses proportional to the frequency of the block 10 and the width of the second signal 25.

Rear edge of the second signal 25 ne

switches the key element 12 to the third channel 14. Therefore, if in the field of view

A third pass appears in the optical system of the device, the third signal 25 caused by it enters the third channel 14, and so on.

At the end of the scanning trajectory of the electron beam of the television tube 5, i.e., at the end of the frame, the vertical scanning generator 7 generates a control signal 22 ("2nd output), which actuates the block 13. This block 13 generates

The signals "Reset 24 and" Record 23, arriving respectively at the control inputs

The signals "Reset 24 and" Record 23, arriving respectively at the control inputs

the scanning trajectory from the initial position, all processes in the circuit repeat element 12, counters 16 pulses and operative storage elements 17 in all channels 14. At the same time, element 12 switches to the initial position (to the first channel), and the counters 16 all channels 14 are memorized in elements 17.

During each subsequent frame, when the electron beam of the tube 5 begins

Claims (1)

The invention The device for measuring the wear of the contact wire by the author. St. No. 921900, characterized in that, in order to improve measurement accuracy, it is equipped with a synchronization unit, a frequency divider, a key element, a switching unit and measurement recording channels according to the number of monitored contact wires, each of which consists of a series-connected And element, a controlled counter of the pulses and the MEMORY element, while the outputs of these elements are the outputs of the measurement recording channels, and the inputs of the recording channels are the inputs of the AND element, and 20 L L L L L V v v v v 22 23 2Ts 25 ZS 27 28 23 PP one output of the switching unit is connected to the control input of each MEMORY element, and the second output is connected to the control input of each pulse counter and the control input of the key element, the signal input of which is connected to the first inputs of the AND elements and the output of the large-scale converter, - the second inputs of the And elements are connected to the outputs of the key element, and the third inputs are connected to the input of the frequency divider and the output of the synchronization unit, and the output of the frequency divider is connected to the inputs of the personnel and horizontal generators rtok television camera.