RU2713215C1 - Device for intelligent damper of vibration of overhead transmission lines - Google Patents

Abstract

FIELD: electric power engineering.

SUBSTANCE: use in the field of electric power engineering for damping of mechanical oscillations of wires of overhead power lines. Device includes a damper element, loads, a suspension clamp for a damper on a wire with lugs for attachment of an intelligent unit housing and a detachable current transformer with a latch, accelerator, first and second integrators, comparator with adjustable insensitivity zone, pulse counters, rectifiers, comparison units are arranged in smart unit housing, setter of allowable value of vibration amplitude, setters of minimum and maximum allowable current, voltage limiters, intelligent unit power filter, ionistor, intelligent unit supply stabilizer, OR logic element, a transceiver via a radio channel or a cellular communication channel and a clock pulse generator.

EFFECT: broader functional capabilities of the device owing to measurement of mechanical oscillations of wires of overhead power transmission lines and values of allowable changes of flowing currents for monitoring of vibration damping, dancing and breaking of wires and flowing currents.

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Description

The invention relates to the field of electric power, in particular to devices for damping mechanical vibrations of wires of overhead power lines.

Known unified vibration damper for wires and cables of overhead power lines containing an elastic damper element, at least two loads secured to the ends of the elastic damper element and made in the form of a body of revolution, consisting of two end parts in the form of a circular barrel and a ball, respectively, connected by a link in the form of a one-sheeted hyperboloid, and a clip intended for suspension on a wire, fixed in the middle of an elastic damper element and by means of a grip and a die on the line wire, while the mass of the goods, the distance of their fastening on the elastic damper element, the weight and diameter of the end parts of the goods differ in value from each other [1].

The disadvantage of this device is the weak ability to energy absorption of the elastic damper element and the narrow functional capabilities of the device, which limits the range of practical use of vibration dampers of this type.

Known vibration damper to protect the bare wires of overhead power lines, containing an elastic damper element in the form of a twisted from a wire rope with at least two weights fixed at its ends and in the middle with a clamp made in the form of a housing and pressure plate designed to suspend the damper on wire [2].

The disadvantage of this device is the low ability to absorb energy of an elastic damper element and the lack of functionality for measuring mechanical vibrations of wires of overhead power lines and the values of permissible changes in flowing currents.

The closest technical solution with respect to the proposed one is a vibration damper for protecting bare wires and lightning protection cables of overhead power lines, containing an elastic damper element in the form of a rope twisted from wires with at least two weights fixed at its ends and with a clamp made in the middle in the form of a housing and a pressure plate designed to suspend the damper on the wire, the part of the clamp housing in contact with the wire is made in the form of a hook with an internal radius of at least the maximum diameter of the mounted wires, and rotated relative to their longitudinal axis so that the loose damper is held in suspension, the clamping plate is fixed with a fine thread bolt and one or two expansion spring washers to prevent self-unscrewing [3].

The disadvantage of this device is the lack of functionality for measuring the mechanical vibrations of the wires of overhead power lines and the values of permissible changes in flowing currents, which significantly reduces the ability to monitor the process of damping vibrations, dancing, and wire breakage and flowing currents.

The objective of the invention is to expand the functionality of the device by measuring the mechanical vibrations of the wires of overhead power lines and the values of permissible changes in the flowing currents to provide monitoring of the process of damping vibrations, dancing and wire breakage and flowing currents.

The essence of the invention lies in the fact that in the device of the vibration damper of the wires of overhead power lines, containing an elastic damper element in the form of a rope twisted from wires with at least two weights fixed at its ends and in the middle with a clamp made in the form of a body and a pressure die, designed to suspend the damper on the wire, the part of the clamping housing in contact with the wire is made in the form of a hook with an inner radius not less than the maximum diameter of the mounted wires, and the rotated relative but their longitudinal axis in such a way that the loose damper is held in suspension, the pressure plate is fixed with a fine thread bolt and one or two spring compensation washers to prevent self-unscrewing, additional tides are made on the clamp case and the smart block case and a plug-in current transformer with a latch mounted on the tides of the clamp housing, an accelerometer, first and second integrators, a comparator with a customizable insensitivity, the first, second and third pulse counters, the first, second and third rectifiers, the first, second and third comparison units, the setpoint for the permissible value of the amplitude of vibration, the setter for the minimum allowable current, the setter for the maximum allowable current, the first and second voltage limiters, power filter a smart unit, an ionistor, a power supply stabilizer of a smart unit, an OR logic element, a radio transmitter or a cellular channel, a clock pulse generator, moreover, The current transformer is made with a rotatable detachable part, which covers the power line wire and is latched, the accelerator output is through the information inputs of the first and second integrators, a comparator with a adjustable dead zone is connected to the information input of the first pulse counter, reset inputs of the first and second integrators and the first counter pulses are connected to the reset output of the clock generator, the output of the second integrator through the second rectifier is connected to the second input a comparison unit, the first input of which is connected to the output of the setpoint of the permissible amplitude of vibration, the output of the split current transformer through the first voltage limiter and the first rectifier is connected to the second inputs of the first and second comparison blocks, the first inputs of which are connected to the outputs of the setpoint of the minimum allowable current and the setter permissible current, respectively, the output of the first comparison unit through the information input of the second pulse counter is connected to the transceiver, the output of the second of the comparison unit through the information input of the third pulse counter is connected to the transceiver, the reset inputs of the second and third pulse counters are connected to the reset output of the clock generator, the outputs of the first pulse counter, the first rectifier, accelerometer and second integrator are connected to the transceiver, the outputs of the first , the second and third comparison blocks are connected to the inputs of the logic element "OR", the output of the initiation of the exchange of the clock generator is connected to the input of the logic element "OR", the output of which is connected to the input of the initiation of the exchange of the transceiver, the output of the detachable current transformer through the second voltage limiter, the third rectifier, a power filter and an ionistor are connected to the power stabilizer of the smart unit of the device.

The invention is illustrated by drawings, where in FIG. 1 is a general view of an intelligent vibration damper device for wires of overhead power lines, a view parallel to a wire of power lines; in FIG. 2 is a view perpendicular to a power line wire; in FIG. 3 is a functional diagram of an intelligent vibration damper device for wires of overhead power lines.

An intelligent vibration damper device for wires 1 of overhead power lines contains an elastic damper element 2 in the form of a twisted from a wire rope with at least two weights 3.4 fastened at its ends and in the middle with a clip made in the form of a housing 5 and a pressure plate 6, designed for the damper suspension on the wire 1, the part of the clamp housing 5 in contact with the wire 1 is made in the form of a hook with an inner radius not less than the maximum diameter of the mounted wires 1 and rotated relative to their longitudinal axis so that the loose damper is held in suspension, the clamping plate 6 is fixed with a bolt 7 with a small thread and one or two compensation spring washers 8 to prevent self-unscrewing.

The housing 5 of the clamp has tides 9, the housing 10 of the smart unit and the detachable current transformer 11 with the latch 12, are mounted on the tides 9 of the housing 5 of the clamp.

Accelerometer 13, first 14 and second 15 integrators, comparator 16 with adjustable dead band, first 17, second 18 and third 19 pulse counters, first 20, second 21 and third 22 rectifiers, first 23, second 24 and the third 25 comparison blocks, a setpoint 26 of the permissible amplitude of vibration, a setter 27 of the minimum allowable current, a setter 28 of the maximum allowable current, the first 29 and second 30 voltage limiters, the filter 31 of the power supply of the smart block, the ionistor 32, the stabilizer 33 power supply int smart block, the logical element "OR" 34, the transceiver 35 by radio or cellular communication, clock generator 36.

The detachable current transformer 11 is made with a rotatable detachable part, which covers the wire 1 of the power line and is fixed by a latch 12.

The output of the accelerator 13 through the information inputs of the first 14 and second 15 integrators, the comparator 16 with a custom dead zone is connected to the information input of the first 17 pulse counter.

The reset inputs of the first 14 and second 15 integrators and the first 17 pulse counter are connected to the reset output of the clock generator 36.

The output of the second integrator 15 through the second 21 rectifier is connected to the second input of the third 25 comparison unit, the first input of which is connected to the output of the setpoint 26 of the permissible vibration amplitude.

The output of the detachable current transformer 11 through the first 29 voltage limiter and the first 20 rectifier is connected to the second inputs of the first 23 and second 24 comparison units, the first inputs of which are connected to the outputs of the setpoint 27 of the minimum allowable current and the setpoint 28 of the maximum allowable current, respectively.

The output of the first 23 comparison unit through the information input of the second 18 pulse counter is connected to the transceiver 35, the output of the second 24 block of the comparison through the information input of the third 19 pulse counter is connected to the transceiver 35.

The reset inputs of the second 18 and third 19 pulse counters are connected to the reset output of the clock generator 36.

The outputs of the first 17 pulse counter, the first 20 of the rectifier, the accelerometer 13 and the second integrator 15 are connected to the transceiver 35.

The outputs of the first 23, second 24 and third 25 comparison blocks are connected to the inputs of the logical element "OR" 34.

The output of the initiation of the exchange of the clock generator 36 is connected to the input of the logical element "OR" 34, the output of which is connected to the input of the initiation of the exchange of the transceiver 35.

The output of the detachable current transformer 11 through the second 30 voltage limiter, the third 22 rectifier, a power filter 31, an ionistor 32 is connected to the power supply stabilizer 33 of the smart unit.

The device is an intelligent vibration damper wires of overhead power lines works as follows.

On the tides 9 of the housing 5 of the clamp, the housing 10 of the smart unit and the detachable current transformer 11 with the latch 12 are fastened. Then the device is fixed to the wire 1 of the overhead power line by means of the clamp. The housing 5 and the clamping die 6 of the clamp are fixed with a small thread bolt 7 and one or two spring compensation washers 8 to prevent self-unscrewing. After fixing the device on the wire 1, the folding part of the detachable current transformer 11 is rotated, covering the wire 1, and is fixed by a latch 12. As a result, the magnetic circuit of the current transformer 11 is closed around the wire 1.

Vibration damping is performed by an elastic damper element 2 with at least two weights 3 and 4 fixed at its ends.

In the process, the accelerometer 13, located in the housing 10 of the smart block, which in turn is rigidly connected with the tides 9 of the clamp housing 5 and the wire 1, measures the accelerations transmitted from the wire 1 to the accelerometer 13.

As a result, the accelerometer 13 measures the amount of vibration of the wire 1 overhead power lines. The value of the magnitude of the vibration through the transceiver 35 via radio or cellular communication is transmitted to the dispatching service of the energy company (not shown in the figures) to take measures that impede the possible development of events unfavorable for the operation of the equipment.

To detect a wire break based on the vibration value transmitted to the dispatch service, the amplitude and acceleration vector of the accelerometer 13 are analyzed.

The output signal of the accelerometer 13 is integrated on the first 14 and second 15 integrators, as a result, an oscillation amplitude is formed, which causes the comparator 16 to operate with an adjustable deadband. The adjustable deadband provides increased noise immunity when the comparator 16 is activated with a wide frequency spectrum of wire vibrations 1.

The first 17 pulse counter calculates the number of operations for a set period of time and the signal of the fundamental frequency of vibration of wire 1 is formed at its output.

The values of the oscillation amplitude from the output of the second 15 integrator and the oscillation frequency from the output of the first 17 pulse counter through the transceiver 35 via radio or cellular communication are transmitted to the dispatching service of the energy company (not shown in the figures) to take measures that impede the possible development of unfavorable for operation event equipment.

The signal of the amplitude of the oscillations from the output of the second 15 integrator is rectified by the second 21 rectifier and compared on the third 25 block comparison with the permissible value set by the setter 26 of the permissible value of the amplitude of the vibration.

As a result, when the acceptable value of the amplitude of the oscillations is exceeded, an alarm is triggered at the output of the third 25 comparison unit, which, passing through the OR logic element 34, triggers an extraordinary transmission of data by the transceiver 35 via a radio or cellular communication channel to the dispatching service of the energy company for taking measures, hindering the possible development of adverse events.

This achieves the control of such a phenomenon as a "dance" of wires.

Scheduled data transmission by the transceiver 35 via a radio or cellular communication channel to the dispatching service of the energy company is performed by a signal from a clock pulse generator 36 via an exchange initiating output connected to the input of an OR logic element 34, which initiates a time-scheduled data transmission by the transceiver 35 via radio or cellular communication to the dispatching service of an energy company.

The value of the signal proportional to the current in wire 1 of the overhead power line from the plug-in current transformer 11 through the first 29 voltage limiter and the first 20 rectifier is fed to the second inputs of the first 23 and second 24 comparison units and to the transceiver 35 for transmitting the current value in wire 1 to the dispatching service energy company.

The permissible operational range for changing the current in the conductor 1 is set by the setpoint 27 of the minimum allowable current and the setpoint 28 of the maximum allowable current. If the current value is in the set range, then the first 23 and second 24 comparison units do not work and the alarm initiation signal is not generated. When the current value leaves the set range, the first 23 (lower limit) or second 24 (upper limit) comparison unit is triggered and an alarm signal is triggered at the block output, which, passing through the OR logic element 34, causes the data to be transmitted out of order by the transceiver 35 over the air or a cellular communication channel to the dispatching service of an energy company to take measures that impede the possible development of adverse events.

The number of cases when the current value drops below the permissible level is recorded by the second 18 pulse counter, and the number of excesses above the allowable rate is recorded by the third 19 pulse counter. This data is sent to the transceiver 35 for transmission to the dispatching service of the energy company.

A periodic reset of the accumulated values of the first 17, second 18 and third 19 pulse counters and reset of the values of the first 14 and second 15 integrators is performed by the reset output of the clock pulse generator 36 with an adjustable reset period time. Counting the number of trips by the first 17, second 18, and third 19 pulse counters for the set time between discharges allows you to determine the frequency of trips by exiting the set limits for transmission through the transceiver 35 to the dispatch service of the energy company.

The device is powered directly from the current transformer 11. The current value is converted into voltage by the second 30 voltage limiter, which limits the possible voltage surges. Then the voltage is rectified by the third 22 rectifier, smoothed by the filter 31 of the power supply of the smart block, the energy is accumulated (accumulated) in the ionistor 32 and the voltage obtained is stabilized by the stabilizer 33 of the power of the smart block of the device.

Tests of the inventive device on overhead power transmission lines of LLC Tulenergo showed high efficiency of real-time monitoring of operational performance of the lines, provided timely information to the enterprise specialists about the recorded current and vibration values outside the permissible limits, the presence of "dancing" and wire breakage, and made it possible to evaluate the efficiency of blanking vibrations

Thus, the expansion of the functionality of the device is achieved by measuring the mechanical vibrations of the wires of overhead power lines and the values of permissible changes in the flowing currents to provide monitoring of the process of damping vibrations, dancing and breaking wires and flowing currents.

Sources of information.

1. RF patent No. 229284. Unified vibration damper // Dubinich L.A. et al. H02G 7/14, claimed 03/18/2003, publ. 03/27/2005 Bull. No. 9.

2. RF patent No. 2180765. Vibration damper // Ryzhov S.V. et al. H02G 7/14, claimed 07/03/2000, publ. March 20, 2002 Bull. Number 8.

3. RF patent No. 2483408. Vibration damper // Kozlov K.S. et al. H02G 7/14, decl. 11/08/2011, publ. May 27, 2013 Byul. Number 15.

Claims (1)

An intelligent vibration damper device for wires of overhead power lines, containing an elastic damper element in the form of a twisted from a wire rope with at least two weights fixed at its ends and in the middle with a clamp made in the form of a housing and a pressure plate designed to suspend the damper on the wire, part of the housing the clamp in contact with the wire is made in the form of a hook with an inner radius not less than the maximum diameter of the mounted wires, and rotated relative to their longitudinal axis with t In such a way that the loose damper is held in a suspended position, the pressure plate is fixed with a fine-threaded bolt and one or two spring compensation washers to prevent self-unscrewing, characterized in that the clamp housing has tides and an intelligent block housing and a detachable current transformer with latch, mounted on the tides of the clamp housing, the accelerometer, the first and second integrators, the comparator with adjustable n dead zone, the first, second and third pulse counters, the first, second and third rectifiers, the first, second and third comparison units, the setpoint for the permissible value of the amplitude of vibration, the setter for the minimum allowable current, the setter for the maximum allowable current, the first and second voltage limiters, filter power supply of an intelligent unit, an ionistor, a power supply stabilizer of an intelligent unit, an OR logic element, a radio transceiver or a cellular communication channel, a clock generator, moreover, a connector The current transformer is made with a rotary detachable part, which covers the power line wire and is latched, the accelerometer output is through the information inputs of the first and second integrators, a comparator with a adjustable dead zone is connected to the information input of the first pulse counter, reset inputs of the first and second integrators and the first counter pulses are connected to the reset output of the clock generator, the output of the second integrator through the second rectifier is connected to the second input the third comparison unit, the first input of which is connected to the output of the permissible vibration amplitude, the output of the detachable current transformer through the first voltage limiter and the first rectifier is connected to the second inputs of the first and second comparison blocks, the first inputs of which are connected to the outputs of the minimum permissible current and maximum permissible current, respectively, the output of the first comparison unit through the information input of the second pulse counter is connected to the transceiver, the output is W The second comparison unit, through the information input of the third pulse counter, is connected to the transceiver, the reset inputs of the second and third pulse counters are connected to the reset output of the clock generator, the outputs of the first pulse counter, the first rectifier, accelerometer, and the second integrator are connected to the transceiver, the outputs of the first , the second and third comparison blocks are connected to the inputs of the logic element OR, the output of the initiation of the exchange of the clock generator is connected to the input of the logic element OR, whose output is connected to the input of the exchange initiation transceiver, yield releasably current transformer via a second voltage limiter, the third rectifier, and the power filter is coupled with the stabilizer ionistor supply IED block.

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