KR101808752B1 - Diagnosis system for underground transmission line - Google Patents

Abstract

The present invention relates to a diagnosis system for an ultra high voltage underground transmission line. More specifically, the present invention relates to a diagnosis system for an ultra high voltage underground transmission line which measures a partial discharge, distribution temperature, deformation and flooding of an underground transmission line throughout an entire underground transmission line; remotely determines a failure of the underground transmission line and transmission capacity by transmitting it to a high-level system using a wire/wireless communication network; monitors and controls environmental facilities in a power source; and stably supports the underground transmission line from a bottom surface of the power source. The diagnosis system comprises: a sensor part, a data collection part, a high-level server, and a control part.

Description

{DIAGNOSIS SYSTEM FOR UNDERGROUND TRANSMISSION LINE}

The present invention relates to an ultra high voltage underground transmission line diagnostic system, and more particularly, to a system for diagnosing an ultra high voltage underground transmission line by measuring the partial discharge, distribution temperature, deformation and immersion of an underground transmission line over an entire underground transmission line, , It is possible to remotely determine the failure of the underground transmission line and the transmission capacity, to monitor and control the environmental facilities in the power line, and to control and control the environmental facilities in the power line by using the ultra high voltage underground transmission line for stably supporting the underground transmission line from the bottom of the power line Diagnostic system.

An underground transmission line is a power cable that transmits a super high voltage and is installed in a power port.

Conventionally, in order to check for an accident in an underground transmission line, an inspector enters and exits the power transmission line, and visually inspects the underground transmission line or performs measurement in the form of measurement equipment.

However, due to the characteristics of the underground pipe, there are problems in safety of the inspectors and reliability of the work, and there is a problem of human consumption due to the necessity of carrying out the preventive maintenance management work regularly.

In addition, even if the power facilities such as the electric power facilities and the electric lamps do not operate normally, there is a problem that the operator can not confirm the electric power without accessing the electric power facilities directly.

A Korean Patent Registration No. 10-1183587 (Sept. 17, 2012) discloses a system and method for monitoring and monitoring ultra high voltage underground transmission lines.

However, since such a conventional ultra high voltage transmission line supervisory diagnostic system can not stably support the underground transmission line from the bottom of the power line, the underground transmission line is hardened due to moisture present on the bottom surface of the power line, And the like.

Korea Patent Registration No. 10-1183587 (2012.09.17) 'Supervision under high voltage underground transmission line system and method'

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a method of measuring partial discharge, distribution temperature, deformation and immersion of an underground transmission line over an entire underground transmission line, It is possible to monitor and control the environmental facilities in the electric power facilities while determining whether the transmission line is faulty and transmission capacity remotely by transmitting it to the upper system, And to provide a transmission line diagnostic system.

The problems to be solved by the present invention are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided an apparatus for detecting an underground transmission line. A data collection device 200 for collecting sensing information of the underground transmission line sensed by the sensor unit 100; An upper server (300) for receiving the sensing information from the data collection device (200) and monitoring the status of the underground transmission line based on the sensing information; And a control unit (120) for generating at least one operation state information of at least one of an operation state of a ventilation facility, which is a power facility of a power source, and an operation state of an illumination, wherein the data collection device (200) And the upper server (300) generates a control signal capable of controlling the power plant, the system comprising: a high-voltage underground transmission line diagnosis system for stably supporting the underground transmission line The supporting unit 400 includes a support plate 410 mounted on a bottom surface of the power hole, A fixing bar 420 extending upward from the support plate 410 and passing through the underground transmission line on both sides and having an upper portion opened; A cap 430 for blocking the upper portion of the fixed bar 420 opened; And a support means (440) for supporting the underground transmission line from the cap (430), the support means (440) comprising: a fastening ring (441) connected to the underground transmission line; A support bar 442 connected to the fastening ring 441 at the lower end and extending upwardly at the upper end to pass through the cap 430; And fixing means (443) for fixing the support bar (442) to the cap (430).

According to the present invention, it is possible to construct a remote inspection system capable of diagnosing the underground transmission line over the entire area of the underground transmission line without inputting the inspectors.

In addition, since the underground transmission line can be stably supported from the bottom surface of the power line, the ground transmission line can be hardened due to moisture present on the bottom surface of the power line, and the leakage current can be prevented.

The effects of the present invention are not limited to those mentioned above, and other solutions not mentioned may be clearly understood by those skilled in the art from the following description.

1 is a conceptual diagram schematically showing an ultra high voltage underground transmission line diagnostic system according to the present invention.
2 is a block diagram showing a data collecting apparatus in the ultra high voltage underground transmission line diagnostic system according to the present invention.
3 is a front sectional view showing a state in which a supporting unit is provided in the ultra high voltage underground transmission line diagnostic system according to the present invention.
And
4 is a partially enlarged side sectional view showing the fixing portion in Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. And should not be construed as limited to the embodiments described herein.

Since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein.

It should be understood that the embodiments according to the concept of the present invention are not limited to the particular mode of disclosure but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

Since the present invention uses the below-described prior-art patent No. 1183587 as it is, the features of the device configuration described below can all be understood as those described in Registration No. 1183587. [

However, the present invention further includes a structure for stably supporting the underground transmission line from the bottom of the power hole among the structures disclosed in the above-mentioned U.S. Provisional Patent Application No. 1183587 and its operation description, Respectively.

Therefore, the device structure, characteristics, and operation relationship described below will be referred to as the contents of the above-mentioned Registration No. 1183587, and the configuration related to the main features of the present invention will be described in detail at the rear end.

Referring to FIG. 1, the ultra high voltage underground transmission line diagnostic system according to the present invention includes a sensor unit 100, a control unit 120, a data collection device 200, and an upper server 300.

The sensor unit 100 monitors the state of the power transmission path and the environment of the power transmission line. The sensor unit 100 includes a PDMS (Partial Discharge Monitoring Sensor) for sensing the partial discharge of the underground transmission line, a temperature sensor for measuring the distribution temperature of the underground transmission line, an external factor of the underground transmission line And a submersion sensor that detects the submergence of the underground transmission line.

The partial discharge detection sensor detects the partial discharge in the underground transmission line. It is installed in the conductor part of the underground transmission line, and is placed in the ground transmission line to be monitored at a predetermined interval. Conventionally, the partial discharge is monitored only at the connection portion of the underground transmission line where the partial discharge is likely to occur. However, the reliability of the partial discharge monitoring system can be improved by monitoring and installing the partial discharge monitoring sensor over the entire underground transmission line.

The temperature sensor and the strain sensor may be equipped with a distributed strain and temperature sensor (DSTS) in the form of an optical cable installed together with an underground transmission line. In this case, the detection of temperature and deformation is not a point, but a continuous distribution throughout the optical cable.

The submersion sensor and the water level sensor are used to monitor the submergence of underground transmission line. The immersion sensor and the water level sensor can be selectively used or can be used in parallel. The immersion sensor may be attached to the surface of the underground transmission line and the level sensor may be attached to the underground transmission line or attached at a predetermined height from the ground surface of the power source.

The control unit 120 senses the operation state of the ventilation equipment, the lighting equipment, and the opening and closing states of the doors, which are the main facilities of the underground power source, generates the operation state information thereof, receives the control signal from the data collection device 200, The operation can be controlled.

The data collecting apparatus 200 collects the sensing information of the sensor unit 100 and the operation state information of the controller 120 and transmits the collected information to the upper server 300. The data collecting apparatus 200 is provided with a plurality of power sources at predetermined intervals so as to transmit the respective positions of the sensor unit 100 and the sensed information measured.

The data collecting apparatus 200 and the sensor unit 100 can communicate in a sleep & wake up manner at predetermined time intervals. This is because the data collecting device 200, which can always receive power, transmits a synchronization packet to the sensor unit 100, and the sensors included in the sensor unit 100 operate in synchronization with the synchronization packet. The sleep time can be set by the operator through the upper server 300, and the sensor unit 100 receives the synchronization packet after wake up and transmits the sensing information to the data collection device 200.

The upper server 300 receives the sensing information and operation state information collected by the data collecting apparatus 200 and can monitor the state of the underground transmission line and the operation state of the power saving facility based on the received information. The upper server 300 stores sensing information and operation status information in a database and manages the information, and provides a diagnostic environment for an underground transmission line using stored information.

For example, it is possible to monitor the partial discharge of the underground transmission line, to provide the operator with diagnostic information about the partial discharge, to calculate the transmission capacity of the underground transmission line based on the temperature sensing information of the underground transmission line, have.

In addition, by using flood sensor and water level sensor, it is possible to monitor the possibility of inundation in the electric power pit and utilize it to prevent flood damage in advance. That is, the operator can determine whether the underground transmission line is inspected and the equipment is repaired by utilizing the underground transmission line diagnosis system based on the sensing information received from the data collection device 200.

In addition, the operation status of each facility can be monitored and the operation can be controlled based on the operation state information of the power saving facility received from the control unit 120. For example, in the case of the ventilation system, the concentration (ppm) of CO, CO2, H2S, CH4, etc. of the power source is higher than a certain level or operates at predetermined time intervals. If not, the ventilation system can be remotely operated or the ventilation system can be checked and repaired.

The upper server 300 generates a control signal for controlling the operation of each facility and transmits the control signal to the control unit 120 through the data collection device 200 to determine whether each facility is operated.

The upper server functions as an HMI (Human Machine Interface) that provides an interface for the operator to control the electric power facilities. When a partial discharge occurs in the underground transmission line, the transmission capacity is not constant, or the underground transmission line is flooded Or an alarm signal can be output when a fault occurs in the electric power facility. The alarm signal may be implemented by outputting a warning message on the display screen, or by transmitting the message to the operator's e-mail or cellular phone registered in the database.

Referring to FIG. 2, the data collecting apparatus 200 includes a data collecting unit 210, a data transmitting unit 220, a central processing unit 230, and a power supplying unit 240.

The data collection unit 210 is connected to the sensor unit 100 and the control unit 120 and collects sensing information and operation state information and transmits the control signal received from the upper server 300 to the control unit 120 . At this time, the data collecting unit 210 and the sensor unit 100 may perform wired or wireless communication. When the wired communication is performed, the data collecting unit 210 and the sensor unit 100 may be connected by an analog signal line, or may use RS232, RS422, RS485 serial communication, or Ethernet communication, Wireless LAN, Zigbee or Bluetooth can be used.

The data transmission unit 220 is connected to the upper server 300 and transmits sensing information and operation state information and receives a control signal from the upper server 300.

The data transfer unit 220 and the upper server 300 may be connected to each other through a local area network (LAN), and may be an Ethernet based TCP / IP protocol.

In addition, IEC61850, a standard for substation communication, can be applied.

The central processing unit 230 stores sensing information and operation state information in a storage unit (not shown), and processes data to be transmitted and received by the data collecting unit 210 and the data transmitting unit 220 according to a communication standard. The central processing unit 230 generates a synchronization packet, transmits the generated synchronization packet to the sensor through the data collecting unit 210, and collects the sensing information according to the sleep & wake up method.

The power supply unit 240 plays a role of supplying power so that each functional unit of the data collection device 200 can operate.

At this time, it is preferable that the power supply unit 240 is a rechargeable battery that can be charged and discharged. In the case of charging the power supply unit 240, a battery floating charging method can be used.

In the case where the data collecting apparatus 200 performs communication with the sensor unit 100, the control unit 120, or the upper server, it may be influenced by the environment of the power port. Particularly, Can be exposed. In the case of the floating charging method, since the power source can be charged through the voltage lower than the equal charging method, there is an effect that the amount of noise generated in the communication environment can be further reduced than in the equal charging method.

Also, the power supply unit 240 can be charged through a battery energy storage system (BESS). The battery energy storage system (BESS) means a facility for storing the nighttime power by using a battery in order to equalize the weekly power load relatively higher than the nighttime, and to utilize it during the daytime. The battery power storage system can be installed directly in an area where electric power is required, and in the present invention, it can be installed in a power port to supply charging power to the data collection device 200.

As a result, the present invention extends the surveillance region of the underground transmission line from the node concept to the line region and remotely monitors the occurrence of partial discharge, distribution temperature of underground transmission line, , And can be used to build an integrated management system that can control power distribution facilities along with monitoring of underground transmission lines.

Further, by using a battery electric power storage system, the power charged at night can be used during the daytime, thereby contributing to equalizing the power load of daytime and nighttime.

3 to 4, the structure of the support unit 400 for stably supporting the ground transmission line from the bottom surface of the power unit is further implemented in the present invention.

The support portion 400 stably supports the underground transmission line from the bottom surface of the power line, thereby preventing hardening of the underground transmission line due to moisture and the like existing on the bottom surface of the power line.

For this, the support part 400 includes a support plate 410 mounted on the bottom surface of the power hole, a fixing bar 420 extending upward from the support plate 410 and passing through the underground transmission line on both sides, A cap 430 for blocking the upper portion of the open fixed bar 420 and a support means 440 for supporting the underground transmission line from the cap 430. [

The support plate 410 has a rectangular plate shape and may be provided with a compression pad 411 on the lower surface thereof so that the underground transmission line can be easily seated.

The fixing bar 420 is preferably formed in a rectangular barrel shape having an open top, and may be connected to the support plate 410 by welding or the like.

The fixing bars 420 extend from the upper side to the lower side on both sides, and guide holes 421 through which the underground transmission line passes are formed.

The cap 430 has a rectangular shape with its bottom opened and blocks the upper portion of the fixed bar 420 while being coupled to the upper portion of the fixing bar 420.

The supporting means 440 is connected to the underground transmission line by a fastening ring 441. The lower end of the support ring 441 is connected to the fastening ring 441. The upper end of the support ring 442 extends upwardly, And fixing means 443 for fixing the bar 442 to the cap 430.

The fastening ring 441 is connected to the upper and lower fastening ring units 441a and 441b in the vertical direction so that one end of the fastening ring 441 is rotatably connected by a folding member 444 such as a hinge and the other end is fastened with bolts and nuts And are preferably detachably connected to each other by fastening means (445).

This is for the purpose of facilitating the detachment to the underground transmission line.

The support bar 442 is connected to the upper fastening ring unit 441 at the lower part and is positioned above the cap 430 while the upper part passes through the cap 430. [

The cap 430 is vertically penetrated and a through hole 431 through which the upper portion of the support bar 442 passes is formed.

The securing means 443 includes a securing member 446 that is coupled to the outside of the support bar 442 to be positioned at the top of the cap 430 and a support bar 442 that is positioned between the securing member 446 and the cap 430. [ And a pressing ring 448 coupled to the outside of the supporting bar 442 so as to be positioned between the fixing member 446 and the spring 447.

The supporting bar 442 is threaded on the outer peripheral surface and the fixing member 446 is screwed to the outside of the supporting bar 442 while forming a thread on the inner peripheral surface.

The spring 447 shrinks or slackens due to an external force generated by an earthquake or a construction site, thereby cushioning the shock.

The joining ring 448 extends outwardly from the fixing member 446 so that contact with the spring 447 can be made more smooth than with the fixing member 446. [

The fixing member 446 adjusts the tension of the underground transmission line while adjusting the elastic force of the spring 447 while rotating the support bar 442 in the longitudinal direction according to the rotation.

Here, the supporting bar 442 can be moved up and down in the longitudinal direction according to the rotation of the fixing member 446, so that the tension of the underground transmission line can be controlled.

Therefore, the support portion 400 can stably support the underground transmission line from the bottom surface of the power line, thereby preventing hardening of the underground transmission line due to moisture and the like existing on the bottom surface of the power line.

100: sensor unit 120:
200: data collecting unit 210: data collecting unit
220: data transferring unit 230: central processing unit
240: power supply unit 300: upper server
400: Support part 410: Support plate
411: Crimp pad 420: Fixed bar
421: guide ball 430: cap
431: through hole 440: support means
441: fastening ring 442: support bar
443: fixing means 444: folding member
445: fastening means 446: fastening member
447: spring 448: pressurizing ring

Claims (1)

A sensor unit 100 for detecting the state of the underground transmission line;
A data collection device 200 for collecting sensing information of the underground transmission line sensed by the sensor unit 100;
An upper server (300) for receiving the sensing information from the data collection device (200) and monitoring the status of the underground transmission line based on the sensing information; And
And a control unit (120) for generating at least one operating state information of an operating state of the ventilation equipment and the lighting,
The data collection device (200)
Further collects the operation state information of the controller 120,
The upper server (300)
An overvoltage transmission line diagnostic system for generating a control signal capable of controlling the power plant,
Further comprising a support part (400) for stably supporting the ground transmission line from the bottom surface of the power hole,
The support portion 400 includes:
A support plate (410) seated on a bottom surface of the power hole;
A fixing bar 420 extending upward from the support plate 410 and passing through the underground transmission line on both sides and having an upper portion opened;
A cap 430 for blocking the upper portion of the fixed bar 420 opened;
And support means (440) for supporting the underground transmission line from the cap (430)
The support means (440)
A fastening ring (441) connected to the underground transmission line;
A support bar 442 connected to the fastening ring 441 at the lower end and extending upwardly at the upper end to pass through the cap 430; And
And fixing means (443) for fixing the support bar (442) to the cap (430).

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