SU764032A1 - Device for monitoring level of ice load conductors of power transmission lines - Google Patents

Description

The invention relates to electrical engineering and is intended for use in icy-hazardous areas to control the level of icing on split-phase power lines.

A device is known for monitoring the level of ice load on wires, whose operation is based on changing the geometrical parameters of one or several spans of the transmission line under the influence of the ice load compared to the rest of the line and measuring the characteristic impedance caused by this difference 1.

However, high voltage class lines (330 kV and above), which are made with split phase conductors, have such large geometrical dimensions that their distortions caused by icing do not lead to a significant change in wave resistance.

The closest technical solution to the invention is a device for monitoring the level of ice load on wires of power transmission lines equipped with interconnect systems, comprising a probe pulse generator and a receiver 2.

Such a device requires installation on the line in addition to the hazardous areas of sensors and tunable barriers, which leads to a decrease in the reliability of the power line. In addition, this device can control the level of ice in one, two points of the line, which reduces the reliability of controlling the level of ice.

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The purpose of the invention is to improve the reliability of detecting a dangerous level of ice load on power lines with isolated groups of wires in at least one split phase.

The goal is achieved by the fact that

15 a device for monitoring the level of ice load on the wires of power lines equipped with connection systems, comprising a probe pulse generator and a receiver, additionally holds a control unit, two switches, a memory unit and a comparison unit, the probe pulse generator input connected to the first input of the control unit .

the output of the probe pulse generator and the receiver input are connected to the input of the first switch, and its outputs are intended to be connected to the interfacial and intraphase channels by the connection systems, the control inputs of their switches and the comparator are connected to the second output of the control unit, the receiver output is connected to the input a second switch, the outputs of which are connected to the first input of the comparison unit and the input of the memory unit, the output of which is connected to the second input of the comparison unit.

The drawing shows a block diagram of the device.

The circuit contains a transmission line 1 with split phase wires, a generator of 2 probe pulses designed to generate pulses sent to the test lines. The output of the generator is connected to the input of the first switch. The receiver 3 receives, filters and detects the pulse signals coming from the power line. The receiver input is connected to the input of the first switch, and its output is connected to the input of the second switch. Phase 4 power lines are insulated with groups of wires.

The control unit 5 serves to synchronize the operation of the device. The first output of the control unit is connected to the input of the generator, and the second to the control inputs of both switches and the comparison unit. The first switch 6 is designed to be connected to the input of the receiver and the output of the generator at the command of the control unit of one of the HS connection systems. The second switch 7 is designed to be connected to the output of the receiver by the command of the input control unit of the memory unit or the input of the comparison unit. The memory unit 8 is designed to store information about the level of the reflected pulse. Comparison unit 9 compares the level of reflection of pulses coming from the interfacial and intraphase channels.

The attachment systems 10 and 11 serve to connect high-frequency equipment to the interfacial and intraphase high-frequency channels, respectively.

The intraphase channel is formed from the insulated portions of the wires of the split phase.

The device works as follows.

In the event of a threat of ice formation on line 1, the generator 2, at the command of the control unit 5, begins to generate sounding pulses each cycle. Every even-numbered clock, these pulses through the switch 6 and the attachment system 10 are sent to phase 4 of line 1 and propagate through the phase-to-phase channels. Each odd clock pulse pulses through the switch 6 and the system 11 connection come on isolated from each

the other group of wires of the split phase 4 line 1 and propagates along the intraphase channel. The operation of the switch 6 is controlled by the control unit 5.

The pulses reflected from the end of the high-voltage line come through the system of connection 10 or 11 and switch 6 corresponding to the operation cycle of the generator and the switch 6 to the input of the receiver 3, where they are filtered, amplified and detected.

The reflected pulses every even clock of the generator 2 is received through the switch 7 into memory block 8, where it is stored until the arrival of the reflected pulses of an odd clock that arrive every odd clock through the switch 7 into block 9 of the comparison.

Since the attenuation increment caused by the formation of ice in the intraphase channel is much higher than the increment of attenuation in the interphase channel, and the length of the ice coating is the same, the ratio of the change in attenuation of the pulses during their run along the interfacial and intraphase channels characterizes the wall thickness of the ice.

Block 9 comparison, measuring ratio

0 levels of reflected pulses coming from the end of the high-voltage line will characterize the thickness of the ice coating. An overrun by this relationship is given. Node value means the need to start melting ice.

 The proposed device allows reliable control over the level of ice throughout the transmission line of high voltage classes having insulated groups of wires.

0 in split phases, and does not require the installation of any sensors on the power lines or a change in the design of the line itself. It can also be used to control the melting of ice.

 Technical and economic efficiency of the proposed device is to increase the reliability of power supply to consumers, reduce the requirements for mechanical strength of power lines,

0 as well as in reducing the cost of the device itself as compared with the known devices of the same purpose. In addition, its use prevents unreasonable melting of ice.

Claims (2)

1. USSR author's certificate for application No. 2650848 / 24-07, cl. H 02 G 7/16, 1978. 2. USSR author's certificate number 603034, cl. H 02 G 7/16, 1978.