RU2713472C1 - Polymer insulator with overhead power line intelligent monitoring module - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention is related to electric engineering, in particular to designs of high-voltage insulators used in conditions of high mechanical loads in high-voltage power transmission lines. Polymer insulator with overhead power line intelligent monitoring module comprises insulating rod lined with tracking protective ribs, terminators, module of intelligent monitoring of overhead power transmission line, built into lower thickened tracking-protective rib, detachable transformer, tensometric plates, three-axis gyroscope, setters of values of mechanical loads, deviations of insulator and current in wire of overhead line, units of comparison, memory of variables, initialization of emergency transmissions over cellular and radio communication network.

EFFECT: broader functional capabilities of the polymer insulator in terms of providing monitoring of the overhead power line and operational data transmission during wire icing, foreign objects falling on the line, "dancing" and breaking wires, as well as data on line load and short circuits.

1 cl, 2 dwg

Description

The invention relates to electrical engineering, in particular to the design of high-voltage insulators used in conditions of high mechanical loads in high-voltage power lines.

Known insulator containing a cylindrical supporting rod with tapered shanks, terminators and bushings, on which couplings are additionally installed, the inner surfaces of the couplings and bushings are made in the form of truncated cones that are connected to the tapered shanks of the rod and face large ends to the ends of the rod (Patent RF No. 21115183, IPC Н01В 17/00, published on July 10, 1998).

The disadvantage of this device is the inability to monitor overhead power lines and data transfer for operational decisions.

Known polymer insulator containing a mechanical rod of polymer, covered by a protective shell and reinforced with metal current-carrying terminators made in the form of a glass (RF Patent No. 2262760, IPC НВВ 17/02, publ. 20.10.2005).

A disadvantage of the known polymer insulator is the inability to monitor overhead power lines when icing the wires, getting foreign objects on the line, “dancing” and wire breakage, as well as data on the line load and short circuits, which reduces the functionality of the device.

The closest is a polymer insulator containing an insulating rod, lined with tracking protection ribs installed on its outer cylindrical surface, at the ends of the insulating rod there are installed ring terminators in the form of a ring consisting of two arcs connected by rectilinear sections, on the ring arc of each terminal, the upper and lower metal plates (RF Patent No. 2320042, IPC H01DB 17/02, publ. March 20, 2008).

The disadvantage of this device is the small functionality of the polymer insulator in terms of monitoring overhead power lines and efficient data transfer during icing of wires, foreign objects getting on the line, “dancing” and wire breakage, as well as data on line load and short circuits.

The technical result achieved by the implementation of this invention is to expand the functionality of the polymer insulator in terms of monitoring overhead power lines and efficient data transfer during icing of wires, foreign objects on the line, “dancing” and wire breakage, as well as data on line load and short circuits.

The specified technical result is achieved by the fact that in the polymer insulator with the module for intelligent monitoring of overhead power lines, containing an insulating rod, lined with tracking protection ribs installed on its outer cylindrical surface, end faces in the form of a ring consisting of two arcs connected by rectilinear are installed on the ends of the insulating rod in sections, on the arc of the ring of each terminal, from the inside, upper and lower metal plates are installed, in the device but an intelligent overhead power line monitoring module, a detachable transformer, and three strain gauge plates were introduced, the first strain gauge plate mounted on the outside of the lower metal plate in its lower part, the second and third strain gauge plates mounted on the side parts of the outer side of the lower metal plate, the detachable transformer is installed on overhead power line wire, intelligent overhead power line monitoring module vstra is inserted into the lower additional thickened tracking protective rib and contains a setpoint for the maximum permissible mechanical load along the first strain gauge plate, a setter for the lowest value of mechanical load on the first tensometric plate, a setter for the highest permissible mechanical load along the first tensometric plate, a setter for the highest permissible mechanical load along the third tensometric plate, the first , second, third and fourth blocks of comparison of mechanical load, three-axis gyroscope, first th, second and third sets of permissible deviations of a three-axis gyroscope, first, second and third blocks compares the permissible deviations of a three-axis gyroscope, a rectifier, a setter of the highest permissible current value in an overhead line wire, a unit for comparing permissible current values in an overhead line wire, voltage limiter, smoothing filter , power stabilizer for the intelligent overhead power line monitoring module, variable memory unit, emergency and cyclic initialization unit, master transmission units, a data transmission unit over a cellular and radio communication network, and an antenna built into the lower additional thickened tracking protection rib, the outputs of the first, second, and third strain gauge plates, a three-axis gyroscope, and a rectifier connected to the inputs of the variable memory, the output of the first tensometric plate connected to the second the inputs of the first and second units for comparing the mechanical load, the output of the second strain gauge plate is connected to the second input of the third unit for comparing the mechanical load, the output d of the third strain gauge plate is connected to the second input of the fourth unit for comparing the mechanical load, the outputs of the adjusters of the highest permissible mechanical load along the first tensometric plate, the lower value of the mechanical load along the first tensometric plate, the largest permissible mechanical load along the second tensometric plate, the largest allowable mechanical load along the third tensometric plate plate through the first inputs of the first, second, third and fourth blocks comparing mechanics The load is connected to the inputs of the initialization unit for emergency and cyclic transmissions, respectively, the outputs of the three-axis gyroscope are connected to the second inputs of the first, second, and third blocks for comparing the permissible deviations of the three-axis gyroscope, the outputs of the first, second, and third adjusters of the permissible deviations of the three-axis gyroscope through the first inputs of the first, second, and the third blocks comparing the permissible deviations of the three-axis gyroscope are connected to the inputs of the block initialization of emergency and cyclic transmissions but, a detachable transformer through a rectifier, a voltage limiter and a smoothing filter is connected to the power regulator of the intelligent overhead power line monitoring module, the output of the rectifier is connected to the second input of the unit for comparing the permissible current value in the overhead line wire, the first input of which is connected to the setpoint for the highest permissible current value in overhead line wire, and the output with the emergency and cyclic gear initialization unit, the output of the gear cycle master is connected to the input unit and initialization of emergency and cyclic transmissions, the variable memory unit is connected to the information input of the data transmission unit via the cellular and radio communications network, the control input of which is connected to the output of the emergency and cyclic transmission initialization unit, the data transmission unit via the cellular and radio communications network is connected to the antenna.

In FIG. 1 shows a general view of a polymer insulator with an intelligent overhead power line monitoring module.

In FIG. Figure 2 shows the structure of the intelligent overhead power line monitoring module.

The polymer insulator with the intelligent overhead power line monitoring module contains an insulating rod 1 lined with tracking protection ribs 2 installed on its outer cylindrical surface; at the ends of the insulating rod there are installed terminators 3 in the form of a ring consisting of two arcs connected by straight sections on each ring arc the upper 4 and lower 5 metal plates, an intelligent monitoring module of 6 overhead power lines, mny transformer 7 and the three strain-gauge plate.

The first 8 strain gauge plate is fixed on the outer side of the lower 5 metal plate in its lower part, the second 9 and third 10 strain gauge plates are fixed on the side parts of the outer side of the lower 5 metal plate.

Detachable transformer 7 is installed on the wire overhead power lines.

Intelligent monitoring module 6 of an overhead power line contains a setpoint for the largest allowable mechanical load 11 along the first 8 strain gauge plate, a setter for the lowest value of the mechanical load 12 along the first 8 strain gauge plate, a setter for the highest allowable mechanical load 13 along the second 9 strain gauge plate, a setter for the highest allowable mechanical load 14 on the third 10 strain gauge plate, the first 15, second 16, third 17 and fourth 18 blocks of comparison of mechanical load, three sowing gyroscope 19, first 20, second 21 and third 22 setpoints of permissible deviations of the three-axis gyroscope 19, first 23, second 24 and third 25 blocks for comparing the permissible deviations of the three-axis gyroscope 19, rectifier 26, setpoint of the highest permissible current value 27 in the overhead wire, block comparison of the permissible current value 28 in the overhead line wire, voltage limiter 29, smoothing filter 30, power supply stabilizer 31 of the intelligent monitoring module 6 of the overhead power line, variable memory 32, initialization block stations 33 emergency and cyclic transmissions, a gear cycle knob 34, a data transmission unit via a cellular and radio communication network 35, and an antenna 36.

The outputs of the first 8, second 9 and third 10 strain gauge plates, a three-axis gyroscope 19 and rectifier 26 are connected to the inputs of the variable memory 32, the output of the first 8 strain gauge plate is connected to the second inputs of the first 15 and second 16 mechanical load comparison blocks, the output of the second 9 strain gauge plate connected to the second input of the third 17 unit for comparing the mechanical load, the output of the third 10 strain gauge plate is connected to the second input of the fourth 18 unit for comparing the mechanical load.

The outputs of the setpoints of the greatest permissible mechanical load 11 along the first 8 strain gauge plate, the lower value of the mechanical load 12 along the first 8 strain gauge plate, the greatest permissible mechanical load 13 along the second 9 tensometric plate, the largest allowable mechanical load 14 along the third 10 tensometric plate through the first inputs of the first 15 , second 16, third 17 and fourth 18 mechanical load comparison units are connected to the inputs of the initialization unit 33 emergency and cyclic transmissions respectively naturally.

The outputs of the three-axis gyroscope 19 are connected to the second inputs of the first 23, second 24 and third 25 blocks for comparing the permissible deviations of the three-axis gyroscope, the outputs of the first 20, second 21 and third 22 adjusters of the permissible deviations of the three-axis gyroscope 19 through the first inputs of the first 23, second 24 and third 25 blocks comparing the permissible deviations of the three-axis gyroscope 19 are connected to the inputs of the initialization unit 33 of emergency and cyclic transmissions.

A detachable transformer 7 through a rectifier 26, a voltage limiter 29 and a smoothing filter 30 is connected to a power regulator 31 of the overhead power line intelligent monitoring module 6.

The output of the rectifier 26 is connected to the second input of the unit for comparing the permissible current value 28 in the overhead wire, the first input of which is connected to the setpoint for the highest permissible current value 27 in the overhead wire, and the output with the initialization unit 33 for emergency and cyclic transmissions.

The output of the gearshift master 34 is connected to the input of the initialization unit 33 of emergency and cyclic gears.

The 32 variable memory unit is connected to the information input of the data transmission unit 35 via a cellular and radio communication network, the control input of which is connected to the output of the initialization unit 33 of emergency and cyclic transmissions.

The data transmission unit 35 via a cellular and radio communication network is connected to the antenna 36.

The device operates as follows.

The polymer insulator during operation perceives significant tensile forces directed along the axis of the insulator, and bending moments. Especially these efforts increase with strong winds and icing of the wires of an overhead power line.

Over time, the magnitude of the tensile force directed along the axis of the insulator is monitored by the first 8 strain gauge plate mounted on the outside of the lower 5 metal plate in its lower part.

Time monitoring of the magnitude and bending moment of the polymer insulator directed across the axis of the insulator is performed by the second 9 and third 10 tensometric plates mounted on the side parts of the outer side of the lower 5 metal plate in its lower part.

The monitoring data over time of the magnitude of the tensile force and bending moment of the polymer insulator is sent to the variable memory 32 for transmission to the operational dispatch center of the electric grid company (not shown in the figure) by means of a data transmission unit via a cellular and radio communication network 35 with antenna 36.

If there are mechanical loads acting on the polymer insulator, tensile forces along the axis of the insulator and bending moments within acceptable limits, the first 15, second 16, third 17 and fourth 18 blocks of comparing mechanical loads with permissible values do not work and the initialization unit 33 emergency and cyclic gears does not generate a data transfer initialization signal. The polymer insulator in this case operates under permissible mechanical loads.

With an increase in the tensile force directed along the axis of the insulator (for example, when icing the wires), the signal at the output of the first 8 strain gauge plate increases and, at a certain moment, exceeds the value set by the master of the largest allowable mechanical load 11 along the first 8 strain gauge plate. The first 15 block comparing the mechanical load with permissible values is triggered, and through the initialization block 33 of emergency and cyclic transmissions, initiates data transfer to the operational dispatch center of the electric grid company (not shown in the figure) of the variables 32 and current values stored in the memory block by means of the data transmission unit cellular and radio communications networks 35 with antenna 36. A signal about icing of wires is sent to the operational service of the electric grid company.

With a decrease in the tensile force directed along the axis of the insulator (for example, when the wire is broken), the signal at the output of the first 8 strain gauge plate decreases and, at a certain moment, becomes less than the lower value of the mechanical load 12 set by the adjuster on the first 8 strain gauge plate. The second 16 block comparing the mechanical load with the permissible values is triggered, and through the initialization block 33 of emergency and cyclic transmissions, initiates the transfer of data to the operational dispatch center of the electric grid company (not shown in the figure) of the variables 32 and current values accumulated in the memory block via the data transmission unit via cellular and radio communications network 35 with antenna 36. A signal about wire breakage is received in the operational service of the electric grid company.

With an increase in the bending moment of the polymer insulator directed across the axis of the insulator (for example, when the wires sway during strong winds or foreign objects get on the wires), the signal at the output of the second 9 strain gauge plate increases and, at a certain moment, exceeds the value set by the setter of the highest allowable mechanical load 13 on the second 9 strain gauge plate. The third 17 block comparing the mechanical load with the permissible values is triggered, and through the initialization block 33 of emergency and cyclic transmissions, initiates the transfer of data to the operational dispatch center of the electric grid company (not shown in the figure) of the variables 32 and current values accumulated in the memory block by the data transmission unit via cellular and radio communication networks 35 with antenna 36. The operational service of the electric grid company receives a signal about a significant sway in the wires in a strong wind or a wire getting into the wire These items.

Similarly, when the signal at the output of the third 10 strain gauge plate installed by the master set the maximum permissible mechanical load 14 on the third 10 strain gauge plate is exceeded, the fourth 18 block comparing the mechanical load with the permissible values is triggered and through the initialization block 33 of emergency and cyclic transmissions initiates data transfer to the operational dispatch center of the electric grid company through a variable memory block 32, a data transmission unit over a cellular and radio communication network 35, and an antenna 36. The main service of the electric grid company receives a signal of a significant sway in the wires during strong winds or foreign objects getting on the wires.

Monitoring over time the position of the lower part of the polymer insulator is carried out by means of a three-axis gyroscope 19 in a microcircuit design. Monitoring data of the position of the lower part of the polymer insulator in three axes is sent to the variable 32 memory unit for transmission to the operational dispatch center of the electric grid company via the data transmission unit over the cellular and radio communication network 35 with antenna 36.

If the position of the lower part of the polymer insulator is within acceptable limits, the first 23, second 24 and third 25 units for comparing the permissible deviations of the three-axis gyroscope 19 do not work and the initialization unit 33 of emergency and cyclic transmissions does not generate a data transfer initialization signal. The position of the lower part of the polymer insulator in this case is within acceptable limits.

When changing the position or vibrations of the lower part of the polymer insulator (for example, during a “dance” or wire break), the values of the signals of the three-axis gyroscope 19 along three axes at a certain moment exceed the values established by the first 20, second 21, and third 22 adjusters of the permissible deviations of the three-axis gyroscope 19.

When the signals of the three-axis gyroscope 19 are exceeded at least on one of the three axes, the corresponding unit for comparing the permissible deviations of the three-axis gyroscope 19 is triggered. At the same time, at the output of one or more blocks from the first 23, second 24 and third 25 blocks of comparing the permissible deviations of the three-axis gyroscope 19 initialization unit 33 of emergency and cyclic transmissions for data transmission to the operational dispatch center of the electric grid company through variable 32 memory blocks and data transmission over the cellular network oh and radio 35 with the antenna 36. The operational service of the electric grid company receives a signal about a “dance” or wire break.

Monitoring the amount of current in the overhead power line wire is carried out by a detachable transformer 7 installed on the overhead power line wire and a rectifier 26. The monitoring amount of current is supplied to the variable 32 memory unit for transmission to the operational dispatch center of the electric grid company via the data transmission unit via the cellular network and radio communications 35 with antenna 36.

If the current value is within acceptable limits, the unit for comparing the allowable current value 28 in the overhead wire does not work and the initialization unit 33 of emergency and cyclic transmissions does not generate a data transfer initialization signal. The magnitude of the current in the wire of the overhead line in this case is within acceptable limits.

If the current is exceeded (for example, during short circuits or unacceptable load values), the value at the output of the rectifier 26 increases and exceeds the value set by the master of the highest permissible current value 27 in the overhead line wire. The unit for comparing the permissible current value 28 in the overhead line wire is triggered and, through the initialization unit 33 of emergency and cyclic transmissions, initiates data transfer to the operational dispatch center of the electric grid company through variable 32 memory units and current values and data transmission via the cellular and radio communication network 35 with antenna 36 . The operational service of the electric grid company receives a signal about short-circuit currents or unacceptable loads in the overhead power line.

The transmitter of the transmission cycles 34, after certain time periods, starts the initialization unit 33 of emergency and cyclic transmissions for transferring the variable 32 data accumulated in the memory unit to the operational dispatch center of the electric grid company through the data transmission unit via the cellular and radio communication network 35 with antenna 36.

A data transmission unit via a cellular and radio communication network 35 with an antenna 36 uses a cellular communication channel in the case of covering the territory with cellular communication and a radio communication channel for transmitting data between smart monitoring modules 6 along an overhead power line.

The power supply of the intelligent monitoring module 6 of the overhead power line is provided by the energy generated by the plug-in transformer 7. The supply voltage through the rectifier 26, the voltage limiter 29 and the smoothing filter 30 is supplied to the power regulator 31 of the intelligent monitoring module 6 of the overhead power line.

Such a technical solution provides overhead power line monitoring and efficient data transmission during icing of wires, foreign objects getting on the line, “dancing” and wire breakage, as well as data on line load and short circuits.

Claims (1)

A polymer insulator with an intelligent overhead power line monitoring module, comprising an insulating rod lined with tracking protection ribs mounted on its outer cylindrical surface; end faces are installed on the ends of the insulating rod in the form of a ring consisting of two arcs connected by straight sections, on the arc of the ring of each terminal from the inside the upper and lower metal plates are installed, characterized in that the module is additionally introduced intellectually into the device monitoring the overhead power line, a detachable transformer and three strain gauge plates, the first strain gauge plate mounted on the outer side of the lower metal plate in its lower part, the second and third strain gauge plates mounted on the side parts of the outer side of the lower metal plate, the detachable transformer is installed on the wire of the air power lines, the intelligent overhead power line monitoring module is integrated in the lower additional This is a thick tracking protective rib and contains a setpoint for the maximum permissible mechanical load along the first strain gauge plate, a setter for the lowest value of mechanical load on the first tensometric plate, a setter for the highest permissible mechanical load along the second tensometric plate, a setter for the highest permissible mechanical load along the third tensometric plate, first, second, third and fourth mechanical load comparing units, three-axis gyroscope, first, second and third gear adjusters of the triaxial gyroscope deviations, the first, second, and third triaxial gyroscope tolerance comparison blocks, a rectifier, the maximum permissible current value in the overhead line wire, the voltage allowable current comparison unit in the overhead line wire, voltage limiter, smoothing filter, power supply stabilizer for intelligent monitoring module overhead power line, variable memory unit, emergency and cyclic transmission initialization unit, transmission cycle master, data transmission unit connected via a cellular and radio communication network and an antenna built into the lower additional thickened tracking protection rib, the outputs of the first, second and third strain gauge plates, a three-axis gyroscope and a rectifier connected to the inputs of the variable memory unit, the output of the first strain gauge plate connected to the second inputs of the first and second blocks comparing the mechanical load, the output of the second strain gauge plate is connected to the second input of the third unit for comparing the mechanical load, the output of the third strain gauge connected to the second input of the fourth unit for comparing the mechanical load, the outputs of the adjusters of the highest allowable mechanical load along the first strain gauge plate, the lowest value of the mechanical load along the first strain gauge plate, the largest allowable mechanical load along the second strain gauge plate, the largest allowable mechanical load along the third strain gauge plate the inputs of the first, second, third and fourth blocks of comparison of the mechanical load are connected to the input and the initialization block for emergency and cyclic transmissions, respectively, the outputs of the three-axis gyroscope are connected to the second inputs of the first, second, and third blocks for comparing the permissible deviations of the three-axis gyroscope, the outputs of the first, second, and third adjusters of the permissible deviations of the three-axis gyroscope through the first inputs of the first, second, and third blocks for comparing the allowable deviations of the three-axis gyroscope are connected to the inputs of the initialization unit for emergency and cyclic transmissions, respectively, a detachable transformer through a rectifier, a voltage limiter, and a smoothing filter are connected to the power stabilizer of the intelligent overhead power line monitoring module, the output of the rectifier is connected to the second input of the unit for comparing the permissible current value in the overhead line wire, the first input of which is connected to the setpoint for the highest permissible current value in the overhead line wire, and an output with an initialization unit for emergency and cyclic transmissions, the output of the gear cycle master is connected to the input of an emergency initialization unit and cycles transmissions, the variable memory unit is connected to the information input of the data transmission unit via the cellular and radio communications network, the control input of which is connected to the output of the emergency and cyclic transmission initialization unit, the data transmission unit via the cellular and radio communications network is connected to the antenna.

Images