SU900223A1 - Device for determination of damage location and non-uniformity degree of power and communication lines - Google Patents

Description

The invention relates to an electrical measuring technique and can be used to determine the location of damage and the degree of heterogeneity of the lines of electrical pulses, an illumination unit, a sweep and labels, an amplifier with a time-varying gain and an indication unit, while the output of the master transmission and communication.

Devices are known that contain a probe pulse generator *, a reflected pulse receiver, and an indication unit. Closest to the proposed technical essence is a device for determining the location of damage and the ^10th degree of heterogeneity of power lines and communications, containing a master oscillator, a probe pulse generator, a backlight, sweep and tag unit, an amplifier with a time-variable coefficient. amplification and indication unit.

The disadvantage of these devices is their low accuracy.

The purpose of the invention is to increase the exact '20 ty.

This goal is achieved by the fact that in the known device containing the master oscillator, the probe sounding generator is connected to the inputs of the probe pulse generator, backlight unit, sweep and tags and the first input of the amplifier with a time-varying gain, the output of the backlight, sweep and tags unit is connected to the first input of the display unit, and the output of the probe pulse generator and the second input of the amplifier with a time-variable gain are connected to the controlled line, the amplifier is introduced with a constant the gain, a switch, the first and second pulse dividers, and a delay line, the output of the amplifier with a time-varying gain being connected to the input of the switch, the first output of which is connected to the input of the amplifier with a time-constant gain, the output of which is connected to the second the input of the display unit and the second output of the switch, the first control input of which is connected to the output of the first pulse divider, the input of which is connected to the output of the master oscillator and the input of the delay line, the output of which is connected to the input of the second pulse divider, the output of which is connected to the second control input of the switch. 10

The drawing shows a structural 'diagram of the device.

The device comprises a master oscillator 1, a probe pulse generator 2, a backlight, sweep and tag unit 3, an amplifier 4 with a time-varying gain, an indication unit 5, an amplifier 6 with a constant-time gain, a switch 7, pulse dividers 8 and 9, and delay line 10.

The device operates as follows.

The master oscillator 1 generates clock pulses synchronously triggering a probe pulse generator 2, a backlight, sweep and tag unit 3 and an amplifier 4 with a time-variable gain. The same clock pulses arrive at two parallel circuits: a divider of 8 pulses - the first control input of the switch 7 and a pin 10 of the delay - a divider of 9 pulses the second control input of the switch

7. Since the dividers 8 and 9 of pulses ⁵⁵ give out every second of the pulses arriving at their input, and the delay line 10 delays the incoming pulses by one clock cycle (for the duration of the interval between pulses of the master oscillator ⁴⁰ ), switch 7 is one, for example , each odd cycle closes the circuit: amplifier 4 with a time-variable gain - amplifier 6 with a constant time gain ⁴³ - display unit 5, and the second, for example, every even cycle of amplifier 6 with a time-constant gain Iya opens and shunts it, forming a circuit: amplifier 50 4 with variable gain over time - display unit 5.

At the same time, on the screen of the display unit 5, a simultaneous image (overlay) of two processes is formed, the same 55 processes in time (by sweep, highlight and marks), i.e. along the horizontal axis and different along the vertical axis due to the presence or absence of gain with a constant gain over time.

The gain of the amplifier 6 with a constant constant gain can be made large enough so that reflections from microinhomogeneities of the monitored line (not shown) can be seen on the screen of the display unit 5.

The gain K ^ of amplifier 4, with a time-varying gain, varies according to the law К ^ = К where Кр is the gain at the moment of sending the probe pulse (b = 0), P is the attenuation coefficient of the monitored line, V is the propagation velocity of the probe pulse along of the controlled line, f, is the double travel time of the probe pulse (there and back) to the inhomogeneity of the controlled line.

If during the measurement process the coefficient β for the amplifier 4 is changed so that the gain is variable over time, so that on the screen of the display unit 5 the image of the set of reflections from microinhomogeneities takes the form of a rectangle, then the corresponding value and, therefore, the value of the attenuation degree K 2 objectively characterizes this controlled line. Against the background of this rectangle, the image of a pulse reflected from macroinhomogeneity is simultaneously visible, which, together with reflections from microinhomogeneities, is amplified by an amplifier 4 with a time-variable gain according to the desired law, i.e. has an established early value of Ko. By measuring the amplitude 1) _{0 of the} pulse reflected from the macroinhomogeneity, we can obtain the exact value of the reflection coefficient Κθ based on the following relation:

U _O = K Ρί ^K about U b where is the amplitude of the probe pulse. In this ratio, K ^ is determined by reflection from microinhomogeneities.

The device allows you to accurately determine the location of damage and the degree of heterogeneity of power lines and communications.

Claims (1)

(54) DEVICE FOR DETERMINING THE PLACE OF DAMAGE AND THE DEGREE OF INHOMOGENEITY OF ELECTRICAL TRANSMISSION LINES The invention relates to electrical measuring equipment and can be used to determine the location of damage and the degree of heterogeneity of transmission lines and communication. Devices are known that contain a generator of probe pulses, a receiver of reflected pulses, and a display unit. The closest to the proposed technical entity is a device for locating the damage site and the degree of heterogeneity of transmission lines and communications, containing a master oscillator, a generator of probe pulses, a backlight unit, a sweep and tags, an amplifier with a time-varying gain, and a display unit. The disadvantage of these devices is low accuracy. The purpose of the invention is to improve accuracy. The goal is achieved by the fact that in a known device containing a master oscillator, a probe generator, a coupling pulse, a backlight unit, a sweep and marks, an amplifier with a variable time gain factor and a display unit, while the output of the master oscillator is connected to the probe inputs pulses, light unit, scan and tags and the first input of the amplifier with time-varying gain, the output of the light block, scan and tags are connected to the first input of the display unit, and the output is a pulse oscillation pulse and a second amplifier input with a variable gain factor are connected to a controlled line, an amplifier with a constant gain factor, a switch, first and second pulse splitters and a delay line are introduced, and the output amplifier with a variable gain factor is connected to the input of the switch, the first output of which is connected to the input of the amplifier with a constant gain factor, the output of which 390 is connected to the second input of the indicator unit and the second th switch output, a first control input coupled to an output of the first divider pulse having an input connected to the output of the master oscillator and the input of the delay line, whose output is connected to the input of the second divider pulses, whose output is connected to a second control input of the switch. The drawing shows a structural diagram of the device. The device contains a master gene. rator 1, generator 2 probe pulses, block 3 for illumination, scanning and marks, amplifier 4 with variable time gain, display 5, amplifier b with constant gain time, switch 7, dividers 8 and 9 pulses and line Yu delay. The device works as follows. The master oscillator 1 generates clock pulses synchronously triggering the oscillator 2 of the probe pulses, the block 3 of the illumination, the sweep and the marks and the amplifier 4 with a time-variable gain factor. These more clock pulses are sent to two parallel chains: a divider of 8 pulses — the first control input of switch 7 and a delay line 10 — a divider of 9 pulses of the second control input of switch 7. Since the divisors 8 and 9 of pulses give every second outgoing signal to their outputs their input pulses, and the delay line 10 delays incoming pulses for one clock (for the interval between pulses of the master oscillator 1), then the switch 7 is one, for example, every odd clock closes the circuit: amplifier 4 with variable during The gain factor is an amplifier 6 with a constant gain time — the display unit 5, and the second, for example, every even clock of the amplifier 6 with a constant time gain factor, opens and shunts it, forming a circuit: an amplifier 4 with a time variable gain factor - display unit 5. In this case, on the screen of the display unit 5, a simultaneous image (superposition) of two processes, identical in time (in scanning, highlighting and marks), i.e. along the horizontal axis and different along the vertical axis due to the presence of 3 parts or the absence of amplification with a constant gain in time. The gain of the amplifier 6 with a constant gain of time can be made sufficiently large so that reflections from the micro-inhomogeneities of the monitored line (not shown) become visible on the screen of the display unit 5. The gain factor K ,, of the amplifier 4 C with a variable in time power factor varies according to the law de KQ - the gain at the time of the oscillation of the probe pulse (0), ft - the attenuation coefficient of the monitored line, V is the speed of propagation of the probe pulse along the monitored line, -fc - time of the double run of the probe pulse (there and back) to the non-uniformity of the controlled line. If in the measurement process the coefficient fi for amplifier 4 with a variable gain is varied in such a way that on the screen of the display unit 5 the image of a set of reflections from microhomogeneities is rectangular, then the corresponding value p, and hence the attenuation value K, objectively characterizes - controlled line. Against the background of this rectangle, the image of a pulse reflected from macro-inhomogeneity is simultaneously visible, which, together with reflections from micro-inhomogeneities, is amplified by amplifier 4 with a time-varying gain according to the desired law, i.e. has an established Ko value. By measuring the amplitude DO of a pulse reflected from macroinhomogeneity, one can obtain the exact value of reflection coefficient K based on the following relationship: Uo - 4 oU% where Ua is the amplitude of the probe pulse. In this ratio, K a is determined from the reflection from microinhomogeneities. The device makes it possible to accurately determine the location of damage and the degree of heterogeneity of power transmission lines and communications. The invention The device for determining the location of damage and the degree of heterogeneity of power lines and communications, containing a master oscillator, a generator of probe pulses, a light unit, times