KR101063293B1 - Spacer Damper and Overhead Transmission Line Monitoring System - Google Patents

Abstract

The overhead transmission line monitoring system using the spacer damper of the present invention includes a spacer damper including a clamp surrounding and supporting a small conductor and a through hole formed therein; A pressure detector configured to surround the small conductor in the clamp, and a data processor installed in the through hole to receive the detected data detected by the pressure detector and wirelessly transmit the detected data. Detection device; And a data collection device that wirelessly receives the detection data and compares the detection data with reference data to determine a transmission state of a small conductor. It includes.

Description

Spacer Damper and Monitoring System for Overhead Transmission Lines Using the Insulation System {SPACER DAMPER AND SYSTEM FOR MONITORING OVERHEAD TRANSMISSION LINE USING THEREOF}

The present invention relates to a spacer damper, and more particularly, to a technology for monitoring a overhead transmission line using a spacer damper with a built-in sensor.

In general, overhead transmission lines are intended for directing power generated by power plants to substations, including lines, supports, insulators and grounding devices. The overhead transmission line transmits the boosted power according to the increase in the transmission capacity, and uses the multi-conductor method which constitutes the transmission line by several conductors instead of the single conductor method which constitutes the transmission line by one conductor.

In the polyconductor mode, one conductor constituting the polyconductor is called a small conductor. In general, the multi-conductor method is such that 2N (N: natural number) small conductors such as corridors (two small conductors), four conductors (four small conductors), and six conductors (six small conductors) constitute one overhead transmission line. do. In the ultra-high voltage transmission line of more than 354kV, four- or six-conductor type is mainly used to increase transmission capacity and solve corona problems.

The spacer damper is a vibration damper that controls the vibration of small conductors in a spacer that maintains a constant interval between small conductors in a multi-conductor overhead transmission line, and maintains the spacing between the small conductors and twists and slits jumps. It is installed with a certain section on the overhead transmission line to prevent it.

On the other hand, overhead transmission lines are developing in an increasingly complex form to address the rapidly increasing demand for electricity. When a sudden accident occurs in such a complicated overhead transmission line, there is a problem that it is difficult to control the entire power system with a limited number of utility companies and a conventional overhead transmission line detection system. In particular, if the sudden accident occurs on the ultra-high-voltage overhead transmission line, which is constructed for the purpose of transporting a large amount of electric power to a long distance point, the impact of the accident is very serious. Therefore, in order to increase the reliability of the power supply, a new technology capable of constantly monitoring and managing the status of overhead transmission lines is required.

The present invention has been made in accordance with the above requirements, the object of the present invention to provide a technique for monitoring the overhead transmission line using a spacer damper with a built-in sensor.

In addition, another object of the present invention is to provide a technology for monitoring the state of overhead transmission lines without a separate power supply by using a current induction part spaced apart from a current detector.

The overhead transmission line monitoring system using the spacer damper of the present invention includes a spacer damper including a clamp surrounding and supporting a small conductor and a through hole formed therein; A pressure detector configured to wrap the small conductor in the clamp and detect a pressure applied to the small conductor by the clamp; and a data provided in the through hole to receive detection data detected from the pressure detector and transmit the data wirelessly Pressure including processing section Detection device; And a data collection device that wirelessly receives the detection data and compares the detection data with reference data to determine a transmission state of a small conductor. It includes.

The pressure detector includes a piezoelectric cable.

The pressure detecting device further includes a current inducing part installed in the clamp to be spaced apart from the pressure detecting part to surround the small conductor.

The clamp may be a hinge-type clamp that is coupled to the fixing pin by rotationally coupled to the fixed portion around the hinge hinge.

The clamp includes a gripping portion in contact with the small conductor, wherein the gripping portion is formed with a first groove and a second groove spaced apart from each other, and the pressure detection unit and the current induction unit are positioned in the first groove and the second groove, respectively. Can be.

The overhead transmission line monitoring system using the spacer damper of the present invention includes a spacer damper including a clamp for wrapping and supporting a small conductor and a through hole formed therein; A pressure cable sensor installed at the clamp to surround the small conductor and detecting a pressure applied to the small conductor; a pressure detection sensor installed at the through hole and converting the pressure signal into a data signal and transmitting the signal wirelessly; Device; And a data collection device that wirelessly receives the data signal and compares the data signal with a reference data signal to determine a transmission state of the small conductor.

The data processor may include a first signal converter configured to convert the pressure signal into the data signal, and a transmitter configured to wirelessly transmit the data signal.

The data processor may further include a memory configured to store a unique identifier assigned to the spacer damper, and the first signal converter may convert the unique identifier into a data signal together with the pressure signal.

The pressure detecting device may further include an induction coil installed in the clamp so as to surround the small conductor and spaced apart from the pressure detecting unit, to induce an induction current from the small conductor, wherein the data processor is configured to rectify the induction current. A rectifier and a capacitor for supplying power to the first signal converter, the transmission unit by storing the rectified induced current.

The data collection device may include a receiver configured to wirelessly receive the data signal, a second signal converter configured to convert the data signal from the receiver into the pressure signal, and a reference value preset and stored in a pressure value corresponding to the pressure signal. Compared with and comprises a comparison unit for determining the presence or absence of the abnormality of the small conductor provided to the output unit.

The data collection device may include a receiver configured to wirelessly receive the data signal, a second signal converter configured to convert the data signal into the pressure signal and the unique identifier from the receiver, and a pressure value corresponding to the pressure signal in advance. And a comparison unit for determining a wind direction and a wind speed state of the surrounding of the small conductor around the spacer damper to which the unique identifier is assigned to the output unit.

The spacer damper of the present invention is a frame having a through hole is formed in the center and the clamp connection portion symmetrical with each other around the through hole; A clamp connected to the clamp connection part to surround and support a small conductor; And a pressure detector configured to surround the small conductor in the clamp to detect a pressure applied to the small conductor, and to store the detected pressure data and a unique identifier. A pressure detection device is provided that includes a data processor for digitally processing the information output from the memory and a data transmission unit for converting the processed data into a wireless signal.

The clamp may be a hinge-type clamp that is coupled to the fixing pin by rotationally coupled to the fixed portion around the hinge hinge.

The pressure detection device further includes a current induction unit for inducing an induction current from the induction coil installed in the clamp to be spaced apart from the pressure detection unit to surround the small conductor, the data processing unit, rectification unit for rectifying the induction current And a pressure detection device including a capacitor by accumulating the rectified induction current and using the capacitor as a power source.

The clamp includes a gripping portion in contact with the small conductor, wherein the gripping portion is formed with a first groove and a second groove spaced apart from each other, and the pressure detection unit and the current induction unit are positioned in the first groove and the second groove, respectively. do.

Since the spacer damper of the present invention includes a capacitor for accumulating the induced current by using a current induction part spaced apart from the pressure detector, there is an effect capable of detecting the state of the overhead transmission line without a separate power supply.

In addition, the overhead transmission line monitoring system using the spacer damper of the present invention has a pressure detection device for detecting the pressure applied to the overhead transmission line in the spacer damper which is essentially installed in the overhead transmission line, there is no overhead transmission line It is effective to monitor the state of the.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

1 is a view showing a overhead line monitoring system using a spacer damper according to an embodiment of the present invention.

Referring to FIG. 1, the overhead line monitoring system using the spacer damper of the present invention includes a spacer damper 100, a pressure detecting device 200, and a data collecting device 300.

The spacer damper 100 is a four-conductor spacer damper installed at regular intervals on the four-conductor overhead transmission line to maintain the spacing between the small conductors 12, 14, 16 and 18 and to prevent twisting or slitting jumping. Can be.

Here, the four conductor overhead transmission line includes four small conductors 12, 14, 16 and 18. The overhead transmission line may be an ultrahigh voltage overhead transmission line of 354 kV or more.

The spacer damper 100 has a polygonal through hole 102 formed at the center thereof and a frame 110 having four clamp connections 112, 114, 116 and 118 symmetrical with each other about the through hole 102, and four clamp connections 112, 114, 116 and 118. And four clamps 122, 124, 126, and 128 respectively connected to and supporting the four small conductors 12, 14, 16, and 18, respectively.

The clamps 122, 124, 126, and 128 may be hinge clamps in which the cover part 122 ″ is rotationally fastened to the fixing part 122 ′ around the hinge and coupled to the fixing pin 123.

Spacer damper 100 has a built-in pressure detection device 200 for detecting the pressure applied to the four small conductors (12, 14, 16, 18), can be assigned a unique identifier uniquely identified on the overhead transmission line .

Above pressure The detection apparatus 200 includes a pressure detector 202, a current induction unit 212, a data signal line 204, a power supply line 214, and a data processing unit 220, and four small conductors (clamps 122, 124, 126, and 128). The pressure applied to 12, 14, 16, and 18 is detected, and the detected pressure value and the unique identifier are wirelessly transmitted to the data collection device 300. pressure The detection unit 202 may be a flexible pressure cable sensor (hereinafter referred to as a piezoelectric cable) in the form of a piezo cable (Piezo cable) installed in the clamp 122, the piezoelectric cable is a small conductor (12, 14, 16, 18) ) By contacting the clamps 122, 124, 126, and 128 to press the small conductors 12, 14, 16, and 18, that is, the pressure applied to the small conductors 12, 14, 16, and 18. 204 is connected to the data processor 220. The degree of pressurization of the small conductors 12, 14, 16, and 18 by the clamps 122, 124, 126, and 128 can grasp the vibration amount of the small conductors 12, 14, 16, and 18 generated by the wind, and the like. , 14, 16, 18 can be monitored when the pressure is reduced.

The current induction part 212 is spaced apart from the pressure detection part 202 by a predetermined distance and is equilibrated in the pressure detection part 202 and installed in the clamp. The current induction part 212 may be an induction coil for inducing current from the small conductor, and is connected to the data processing part 220 through a power supply line 214. The appearance of the data processor 220 may have a predetermined shape, for example, a polygonal shape that may be inserted into the through hole 102 formed in the center of the spacer damper 100.

The data collection device 300 determines whether there is an abnormality in the overhead transmission line in which the spacer damper 100 is installed using the pressure value received from the pressure detection device 200 and the unique identifier, and provides the same to the user. The data collection device 300 may be mounted on a circuit inspection vehicle 400 moving along the overhead transmission line to detect an abnormality of the overhead transmission line.

Hereinafter, the relationship between the spacer damper 100 and the pressure detection device 200 will be described. The data processor 220 may be inserted into the through hole 102 of the spacer damper 100 to be fixed by fixing means (not shown) such as a screw. When the clamps 122, 124, 126, 128 support and fix the small conductors 12, 14, 16, 18, each of the clamps 122, 124, 126, 128 has a piezoelectric cable and an induction coil for the corresponding conductors 12, 14, 16, 18. The clamps 122, 124, 126, and 128 may be installed to have an annular wrapping shape. The piezoelectric cable is for detecting the pressure applied to the small conductor.

In the present embodiment, the spacer damper has been described as an example of a spacer damper for four conductors, but the spacer damper is not limited thereto, and the spacer damper may be a spacer damper for a multi-conductor installed in a multi-conductor overhead transmission line of four conductors or less.

In addition, in the present embodiment, the spacer damper has been described with an example including a hinge cracker (Nut Cracker Type Clamp), but the spacer damper is not limited thereto, and may be a detachable clamp (Cantilever Type Clamp).

FIG. 2 is a perspective view illustrating the clamp of the spacer damper illustrated in FIG. 1, and shows a state in which a cover part of the clamp is opened. Referring to FIG. 2, first and second grooves 131 and 132 are spaced apart from each other along the semicircular shape of the grip portion 130 in the grip portion 130 inside the clamp 122 contacting the small conductor. The pressure detector 202 is located in the first groove 131, and the current induction part 212 is located in the second groove 132. The depth of the second groove 132 may be deeper than the depth of the first groove 131, and the pressure detector 202 is partially exposed from the first groove 131 to contact the small conductor. The first grooves 131 and the second grooves 132 are made of resin or the like such that the pressure detector 202 and the current induction unit 212 are not separated from the first grooves 131 and the second grooves 132, respectively. Can be molded as.

Through holes 123 ′ and 123 ″ in which fixing pins are inserted are formed in the fixing parts 121 and 121 ′ where the fixing part 122 ′ and the cover part 122 ″ of the clamp 122 are attached to each other. In addition, each of the binding parts 121 and 121 ′ is provided with connection connectors 136 and 137 and 138 and 139 connected to the pressure detector 202 and the current induction part 212. Outside the fixing part 122 ′ of the clamp 122, output terminals 206 and 216 are formed to allow the pressure detector 202 and the current inducing part 212 to be connected to the data signal line 204 and the power supply line 214, respectively.

After the user places the small conductor in the grip portion 130 of the clamp 122, the cover portion 122 ″ is rotated around the hinge 134 to closely adhere to the fixing portion 122 ′, and the through hole 123 is disposed. When the fixing part 122 'is fixed to the fixing part 122' by inserting the fixing pin into the fixing part 122 ', each of the binding parts 121 and 121' of the cover part 122 'and the fixing part 122' is fixed. The connecting connectors 136, 137; 138, 139 are interconnected to the connecting connectors corresponding to each other. When the connection connectors 136 and 137 and 138 and 139 are interconnected, the pressure detector 202 may be shaped to surround the small conductor. 3 is a plan view of the clamp showing that the pressure detector is shaped to surround the small conductor.

4 is a block diagram illustrating a data processor and a data collector of the current detector of FIG. 1. Referring to FIG. 4, the data processor 220 of the current detector includes an amplifier 221, a memory 223, a signal converter 224, a transmitter 225, a rectifier 226, and a capacitor 227. Include. The data processor 220 is manufactured according to a circuit design considering cold resistance and heat resistance to withstand an external weather environment and includes a waterproof enclosure that can protect an internal circuit. The data collection device 300 includes a receiver 310, a signal converter 320, a comparator 330, an output 350, and a storage 340.

First, the data processing unit 220 of the pressure detector will be described in more detail.

The amplifier 221 amplifies the pressure signal detected by the pressure detector through the data signal line 204. The memory 223 stores a unique identifier assigned to the spacer damper in which the data processor 220 is installed. The unique identifier is for identifying a specific spacer damper on a overhead transmission line provided with a plurality of spacer dampers.

The signal converter 224 converts the pressure signal provided from the amplifier 221 and the unique identifier of the memory 223 into a data signal that can be wirelessly transmitted to the transmitter 225. The transmitter 225 wirelessly transmits the data signal provided from the signal converter 224 to the data collection device 300.

The rectifier 226 rectifies the induction current induced by the current induction unit through the power supply line 214, and stores the rectified induction current in the capacitor 227. The capacitor 227 supplies the stored electricity to the amplifier 221, the memory 223, the signal converter 224, and the transmitter 225 to drive the data processor 220.

The data processor 220 of the pressure detector may further include a surge protector that protects the components of the data processor 220 from surge voltage due to a thunderstorm or the like.

Next, the data collection device 300 will be described in more detail.

The receiver 310 wirelessly receives a data signal provided from the data processor 220 and provides the signal to the signal converter 320. The signal converter 320 converts the data signal provided from the receiver 310 into a pressure signal and a unique identifier and provides the converted signal to the comparator 330. The comparison unit 330 compares the preset reference value and the pressure value corresponding to the pressure signal provided from the signal conversion unit 320 and outputs the comparison result along with the unique identifier through the output unit 350. The comparator 330 compares the pressure information of the conductors of the normal transmission line with the pressure information of the conductors by the wind direction and the wind speed to the pressure information of each of the small conductors currently measured using the data already acquired through the experiment. Afterwards, it is configured to calculate wind direction and wind speed information, which are the main environment variables around transmission line and whether there is an abnormality of transmission line. When the comparison value is a pressure value or less than the reference value, it can be determined that an abnormality has occurred in the overhead transmission line around the spacer damper to which the unique identifier is assigned.

The output unit 350 may be a display device or an alarm generating device that informs a user of a state in which an abnormality has occurred in the overhead transmission line. The output unit 350 may include an input / output interface for interfacing with another external device such as a computer. The comparison unit 330 may store the comparison result and the unique identifier in the storage unit 340. The comparison result and the unique identifier stored in the storage unit 340 may be processed later by the user and used in a process transmission line failure history management system.

Although the detailed description of the present invention described above has been described with reference to a preferred embodiment of the present invention, a person skilled in the art without departing from the spirit and scope of the present invention described in the claims to be described later It will be understood that various modifications and variations can be made in the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1 is a view schematically showing a overhead line monitoring system using a spacer damper according to an embodiment of the present invention.

FIG. 2 is a view illustrating a clamp of the spacer damper shown in FIG. 1.

FIG. 3 is a view of a clamp showing that the current detector of FIG. 2 surrounds the small conductor. FIG.

4 is a block diagram illustrating a data processor and a data collector of the current detector of FIG. 1.

Claims (15)

A spacer damper including a clamp surrounding and supporting the small conductor and having a through hole formed therein; A pressure detector configured to wrap the small conductor in the clamp and detect a pressure applied to the small conductor by the clamp; and a data provided in the through hole to receive detection data detected from the pressure detector and transmit the data wirelessly Pressure including processing section Detection device; And A data collection device that wirelessly receives the detection data and compares the detection data with reference data to determine a transmission state of a small conductor; Overhead transmission line monitoring system using a spacer damper comprising a. The method of claim 1, wherein the pressure detector, Overhead transmission line monitoring system using spacer dampers including piezoelectric cables. The pressure detection device of claim 2, The overhead transmission line monitoring system using a spacer damper further comprises a current inducing unit which is installed in the clamp so as to surround the small conductor spaced apart from the pressure detector. The method of claim 1, wherein the clamp, The overhead transmission line monitoring system using a spacer damper which is a hinged clamp which is rotated and fixed to a fixed part around a hinge and coupled to a fixed pin. The method of claim 4, wherein the clamp, And a gripping part contacting the small conductor, wherein the gripping part is formed with a first groove and a second groove spaced apart from each other, and the pressure detector and the current inducing part respectively include spacer dampers positioned in the first groove and the second groove. Overhead transmission line monitoring system. A spacer damper including a clamp surrounding and supporting the small conductor and having a through hole formed therein; A pressure cable sensor installed to surround the small conductor in the clamp to sense a pressure applied to the small conductor, data installed in the through-hole and converting a pressure signal output from the pressure cable sensor into a data signal for wireless transmission A pressure detecting device including a processing unit; And And a data collection device for wirelessly receiving the data signal and comparing the data signal with a reference data signal to determine a transmission state of a small conductor. The method of claim 6, wherein the data processing unit, A first signal converting unit converting the pressure signal into the data signal, and Overhead transmission line monitoring system using a spacer damper including a transmission unit for transmitting the data signal wirelessly. The method of claim 7, wherein The data processor further includes a memory in which a unique identifier assigned to the spacer damper is stored. And said first signal converting portion converts said unique identifier into a data signal together with said pressure signal. The method of claim 8, The pressure detecting device further includes an induction coil installed in the clamp to surround the small conductor and spaced apart from the pressure detecting unit to induce an induction current from the small conductor, The data processing unit may further include a rectifier configured to rectify the induced current, and a capacitor configured to accumulate the rectified induced current to supply power to the first signal converter and a transmitter. . The method of claim 9, wherein the data collection device, A receiver which wirelessly receives the data signal; A second signal converter converting the data signal from the receiver into the pressure signal; And a comparison unit for comparing the pressure value corresponding to the pressure signal with a preset and stored reference value to determine whether there is an abnormality of the small conductor and to provide it to the output unit. The method of claim 10, wherein the data collection device, A receiver which wirelessly receives the data signal; A second signal converter converting the data signal from the receiver into the pressure signal and the unique identifier; A spacer damper including a comparison unit for comparing the pressure value corresponding to the pressure signal with a preset reference value and determining the wind direction and the wind speed of the surroundings of the small conductor around the spacer damper to which the unique identifier is assigned and providing it to the output unit. Transmission line monitoring system using A through hole formed in the center and having a clamp connection part symmetrical with each other about the through hole; A clamp connected to the clamp connection part to surround and support a small conductor; And A pressure detector configured to surround the small conductor in the clamp to detect a pressure applied to the small conductor, and store the detected pressure data and a unique identifier And a pressure detector including a data processor for digitally processing the information output from the memory and a data transmitter for converting the processed data into a wireless signal. The clamp of claim 12, Spacer damper with a current detector, which is a hinge-type clamp, the lid of which is rotated and fixed to the fixing part around the hinge and coupled to the fixing pin. The pressure detecting device of claim 13, And a current inducing part spaced apart from the pressure detecting part to induce an induction current from an induction coil installed in the clamp to surround the small conductor, The data processing unit includes a rectifier for rectifying the induced current, and a capacitor for accumulating the rectified inductive current, and a spacer damper provided with a pressure detection device using the capacitor as a power source. The method of claim 14, wherein the clamp, And a gripping portion in contact with the small conductor, wherein the gripping portion is formed with a first groove and a second groove spaced apart from each other, and the pressure detector and the current inducing portion are respectively located in the first groove and the second groove.

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