KR102029012B1 - Fault section monitoring system of underground distribution line - Google Patents

Abstract

The present invention relates to a fault section monitoring system of an underground distribution line and, more specifically, relates to the fault section monitoring system of the underground distribution line capable of notifying and inspecting at a set period whether or not a sensor detects a fault section of a distribution line installed underground. In addition, the present invention ensures that the light receiving part for the light emitted from the light emitting part is accurately detected by removing foreign materials present in a translucent panel. The present invention comprises: a sensor part; a data collection device; a parent server; and a detecting part.

Description

Failure section monitoring system of underground distribution line {FAULT SECTION MONITORING SYSTEM OF UNDERGROUND DISTRIBUTION LINE}

The present invention relates to a failure section monitoring system of underground distribution lines in the distribution technology field, and more specifically, to detect and inspect the failure of the sensor detecting a failure section of the distribution line installed in the underground at a set cycle so that inspection can be performed. On the other hand, the present invention relates to a failure section monitoring system for underground distribution lines to remove foreign substances present in the translucent panel so that the detection at the light-receiving unit can be made accurately.

With the development of IT technology, important devices used in distribution lines have built-in monitoring sensors to enable real-time monitoring.

Underground distribution lines are installed around urban centers where most loads are concentrated and managed as one of the important distribution facilities.

However, in the case of underground distribution lines, the construction of a real-time monitoring system has not been achieved due to installation and operation costs, and the monitoring technology that can be applied is also limited.

Accordingly, underground distribution lines have been subjected to periodical off-line to determine the deterioration state.

For this diagonal diagnosis, there is a problem in that the line is blackout, and the diagnosis accuracy is not high.

Korean Patent Registration No. 10-1439399 (2014.09.12.) Discloses an optical complex underground power transmission, distribution and substation cable monitoring device.

However, such a conventional optical underground transmission, distribution and substation cable monitoring device does not remove foreign substances present in the translucent panel, so it is difficult to expect accurate detection in the light receiving unit for light emitted from the light emitting unit. .

Republic of Korea Patent Registration No. 10-1439399 (2014.09.12.) 'Optical composite underground transmission, distribution and substation cable monitoring device'

The present invention has been made to solve the above-described problems, the object of the present invention is to notify the inspection of the failure of the sensor for detecting the failure section of the distribution line is installed in the ground to check and check the semi-transparent panel, while It is to provide a failure section monitoring system for underground distribution lines to remove the foreign matter present in the light emitting unit to accurately detect the light from the light emitting unit.

The problem to be solved of the present invention is not limited to those mentioned above, other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention provides a sensor unit 100 for detecting a state of a distribution line; A data collection device 200 for collecting sensing information of the distribution line detected by the sensor unit 100; A higher server 300 receiving the sensing information from the data collection device 200 and monitoring a state of a distribution line based on the sensing information; A control unit 120 for generating at least one operation state information of an operation state of a ventilation facility and an illumination device that is a power facility in a power outlet; And a detection unit 700 for detecting whether the sensor unit 100 has failed when a set time elapses. The sensor unit 100 is installed in the distribution line at a predetermined interval to detect the partial discharge of the partial discharge of the distribution line 104; A temperature sensor 102 installed in the form of an optical cable together with the distribution line to sense the temperature of the distribution line; A water level sensor 106 which detects the flooding of the power distribution line by detecting the water level of the electric power outlet in which the power distribution line is installed; And a deformation sensor 108 installed at predetermined intervals on the distribution line to detect deformation of the distribution line, and the detection unit 700 is wound around the resistor 712 connected to the temperature detection sensor 102. The overheat detection unit includes a first coil 714 and a power supply 710 for supplying current to the first coil 714 to generate heat; A discharge detector 720 which supplies a current to the partial discharge detection sensor 104 and checks whether the partial discharge detection sensor 104 is broken; The translucent panel 736 is advanced between the light emitting unit 732 and the light receiving unit 734 to determine whether the water level detecting sensor 106 detects the water level by the light emitting unit 732 and the light receiving unit 734. A water level sensing unit consisting of a cylinder 730 for reversing; And a deformation detection unit configured to provide a modified image to the deformation detection sensor 108 that detects deformation by photographing the appearance of the distribution line, and detects whether the deformation detection sensor 108 is broken. The cylinder 730 includes: Underground power distribution line is provided with a rod (731) having a rear end connected to a support (P) extending upward from the bottom of the power port, the front and the rear part is driven in accordance with the front end is connected to the translucent panel 736 In the failure zone monitoring system of the support, the guide portion 800 for guiding the progress of the rod 731 according to the driving of the cylinder 730, while supporting the rod 731 from the bottom surface of the power sphere; And a foreign substance removing unit 900 for removing foreign substances present in the translucent panel 736, wherein the foreign substance removing unit 900 is disposed on the upper portion of the translucent panel 736 and the inner side thereof is opened. The upper brush roller 911 is rotatably coupled to, the upper frame 910 is formed with an upper flange 912 extending outwardly on both sides; The lower frame 920 is disposed below the translucent panel 736 and the lower brush 922 is rotatably coupled to the inside while the upper portion is opened, and the lower flange 922 is formed to extend outwardly on both sides. ; Posts 930 extending from the bottom of the power sphere in the upward direction and passing through both sides of the upper and lower frames (910,920); And fixing means 940 for connecting the upper and lower frames 910 and 920 to the support 930 so that the upper and lower frames 910 and 920 can be raised and lowered. The upper and lower brush rollers 911 and 921 are driven by the cylinder 730. By removing the foreign matter present on the surface of the translucent panel 736 while being rotated by the contact with the translucent panel 736, the fixing means 940 is disposed below the upper flange 912 An upper fixing member 941 screwed to the support 930; And a spring 942 connecting the upper and lower flanges 912 and 922 to provide a failure section monitoring system for an underground distribution line.

According to the present invention, first, there is an effect capable of monitoring and diagnosing underground distribution lines throughout the underground distribution line without inputting the inspector.

Second, since the sensing unit for detecting a failure of the sensor unit for detecting the status of the underground distribution line is provided, it can be determined according to the set cycle of the sensor unit has the effect of preventing a safety accident due to malfunction or damage to the sensor unit.

Third, the foreign matter present in the semi-transparent panel can be removed, so that the detection at the light-receiving unit for light emitted from the light-emitting unit can be accurately performed.

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

1 is a configuration diagram showing a fault zone monitoring system of an underground distribution line according to the present invention.
2 is a block diagram showing an apparatus for collecting data in a failure section monitoring system of an underground distribution line according to the present invention.
3 is a block diagram showing a detection unit in the fault zone monitoring system of the underground distribution line according to the present invention.
Figure 4 is a side view showing a state provided with a support and the foreign matter removing unit in the failure section monitoring system of the underground distribution line according to the present invention.
FIG. 5 is an exploded view illustrating the supporter in FIG. 4.
And
6 is a side view showing a state of the foreign material removing unit in FIG.

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

1 to 3, the fault zone monitoring system of the underground distribution line according to the present invention includes a sensor unit 100, a control unit 120, a data collection device 200, an upper server 300, and a detection unit 700. It includes.

The sensor unit 100 monitors the state of the power distribution line installed in the power port and the environment of the power port. The sensor unit 100 includes a partial discharge detection sensor 104 for detecting partial discharge of a distribution line, a temperature detection sensor 102 for measuring a distribution temperature of a distribution line, and a deformation detection for detecting deformation caused by external factors of the distribution line. Sensor 108, and includes a water level sensor 106 for detecting whether the distribution line is inundated.

The partial discharge detection sensor 104 detects a partial discharge in a distribution line and is installed in a conductor part of the distribution line, and is disposed around the distribution line to be monitored at predetermined intervals.

Conventionally, partial discharge is monitored only at a connection portion of a distribution line that is likely to cause partial discharge. However, by installing and monitoring the partial discharge monitoring sensor over the entire distribution line, the reliability of the partial discharge monitoring system can be improved.

The temperature sensor 102 may be provided as a sensor in the form of an optical cable installed together with the distribution line.

In this case, the sense of temperature is not about any point but rather as a continuous distribution throughout the optical cable.

The water level sensor 106 is for monitoring the flooding of the distribution line, the light emitting unit 732 for irradiating light, and the light receiving unit for detecting the water level by detecting the speed at which the light irradiated from the light emitting unit 732 is incident 734.

The control unit 120 detects the operation state of the ventilation facility and lighting, which are the main facilities of the underground power outlet, and the opening / closing state of the door, generates the operation state information accordingly, and receives the control signal from the data collection device 200 to The operation can be controlled.

In addition, the control unit 120 transmits a driving signal to the monitoring unit 700 when the setting period has elapsed, so that the sensor unit 100 may be determined whether or not the sensor unit 100 is broken by the operation of the monitoring unit 700.

The data collection device 200 collects the sensing information of the sensor unit 100 and the operation state information of the control unit 120, and transmits the collected information to the upper server 300. The data collection device 200 is provided in a plurality of power units at predetermined intervals so as to transmit each position of the sensor unit 100 and the measured sensing information.

The data collection device 200 and the sensor unit 100 may communicate in a sleep & wake up manner at predetermined time intervals. This is because the data collection device 200, which can always be powered, 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 may be set by an operator through the upper server 300, and the sensor unit 100 may receive a synchronization packet after wake up and transmit sensing information to the data collection device 200.

The upper server 300 may receive the sensing information and the operation state information collected by the data collection device 200, and may monitor the state of the distribution line and the operation state of the power outlet facility based on the received information. The upper server 300 stores and manages the sensing information and operation state information in a database, and provides a monitoring and diagnosis environment of the distribution line using the stored information.

For example, it is possible to monitor the partial discharge of the distribution line, provide diagnostic information on the partial discharge to the operator, calculate the distribution capacity of the distribution line based on the temperature sensing information of the distribution line and provide it to the operator.

In addition, the immersion sensor and the water level sensor can be used to monitor the possibility of immersion inside the power outlet and to be able to take precautions against flood damage. That is, the operator may determine whether to check the distribution line and repair the facility based on the sensing information received from the data collection device 200.

In addition, the operation status of each facility may be monitored and the operation may be controlled based on the operation state information of the power tool facility received from the control unit 120. For example, in the case of the ventilation equipment, the concentration of ppm, CO2, H2S, CH4, etc. of the power source is operated at a predetermined level or more or at predetermined time intervals, but the ventilation equipment is operated even when the ventilation equipment is required. If not, the ventilation system can be operated remotely, 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 to operate each facility.

The host server acts as a Human Machine Interface (HMI) that provides an interface for the operator to control the power equipment, and when partial discharge occurs in the distribution line, the distribution capacity is not constant, or the distribution line is flooded, Alarm signal can be output in case of failure of power equipment. The alarm signal may be implemented by outputting a warning message on a display screen or transmitting a message to an e-mail or a mobile phone of an operator registered in a database.

The data collecting device 200 includes a data collecting unit 210, a data transmitting unit 220, a central processing unit 230, and a power supply unit 240.

The data collection unit 210 is connected to the sensor unit 100 and the control unit 120 to collect sensing information and operation state information, and transmit a control signal received from the upper server 300 to the control unit 120. To perform.

In this case, the data collection unit 210 and the sensor unit 100 may perform wired or wireless communication. In the case of performing wired communication, the data collection unit 210 and the sensor unit 100 may be connected by analog signal lines, or may use RS232, RS422, or RS485 serial communication and Ethernet communication. Wireless LAN, Zigbee (Bluetooth) or Bluetooth can be used.

The data transmitter 220 is connected to the upper server 300 to transmit sensing information and operation state information, and receives a control signal from the upper server 300. The data transmitter 220 and the upper server 300 may be connected to a local area network, and may preferably be an Ethernet-based TCP / IP protocol.

In addition, IEC61850, the standard for substation communication, may be applied.

The central processor 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 collector 210 and the data transmitter 220 according to a communication standard. The central processing unit 230 generates a synchronization packet, transmits it 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 serves to supply power so that each functional unit of the data collection device 200 can operate.

In this case, the power supply unit 240 is preferably a rechargeable battery capable of charging and discharging, and when the power supply unit 240 is charged, a battery floating charging method may be used. When the data collection device 200 communicates with the sensor unit 100, the control unit 120, or an upper server, the data collection device 200 may be affected by the environment of the power supply, and in particular, due to the noise of the charging signal and interference from the power supply source. May be exposed.

In the case of the floating charging method, since the power supply can be charged through a lower voltage than the equal charging method, the amount of noise generated in the communication environment can be further reduced than the equal charging method.

In addition, the power supply unit 240 may be charged through a battery power storage system.

The battery power storage system refers to a facility for storing the late night power using the battery to use during the day to equalize the power load during the day, which is relatively higher than the night.

The battery power storage system may be installed directly in an area where power is required, and in the present invention, the battery power storage system may be installed at a power outlet to supply charging power to the data collection device 200.

The sensing unit 700 includes a first coil 714 wound around a resistor 712 connected to the temperature sensor 102, and a power supply 710 that generates heat by supplying current to the first coil 714. An overheat detection unit, a discharge detection unit 720 for supplying a current to the partial discharge detection sensor 104 to check whether the partial discharge detection sensor 104 has failed, the light emitting unit 732 and the light receiving unit 734 A water level detecting unit comprising a cylinder 730 for advancing or reversing the translucent panel 736 between the light emitting unit 732 and the light receiving unit 734 to determine whether the water level detecting sensor 106 detects a water level by It includes a deformation detection unit for detecting the failure of the deformation detection sensor 108 by providing a modified image to the deformation detection sensor 108 to detect the deformation by taking a picture of the distribution line.

When a driving cycle is transmitted after a setting period has elapsed from the controller 120, power is supplied from the power supply 710 to the resistor 712 to generate heat from the first coil 714, and the temperature sensor 102 overheats. Will be detected to detect

In addition, the current is supplied to the partial discharge detection sensor 104 from the current supply unit 720 according to the drive signal transmitted from the control unit 120 to check whether the partial discharge detection sensor 104 detects the discharge.

In addition, since the rod protrudes from the cylinder 730 according to the driving signal transmitted from the controller 120, the translucent panel 736 is advanced at an interval between the light emitting unit 732 and the light receiving unit 734. The irradiated light arrives at the light receiving unit 734 by delaying the water level sensor 106 to check whether the failure.

In addition, by transmitting a deformation signal from the image providing unit to the deformation detection sensor 108 in accordance with the driving signal transmitted from the control unit 120 to check whether the deformation detection sensor 108 is broken.

Since the inspection operation is performed as described above, it is possible to determine whether or not the sensor unit 100 is broken. Therefore, it is possible to determine whether the safety accident is normally monitored by the distribution line due to the failure of the sensor unit 100. .

On the other hand, the cylinder 730 is a rod 731 is connected to the support (P) is formed in the rear end extending upward from the power sphere bottom surface, the front and rear in accordance with the drive to the front end is connected to the translucent panel 736 ) Is provided.

The failure zone monitoring system of the underground distribution line according to the present invention guides the progress of the rod 731 according to the driving of the cylinder 730 as shown in FIGS. It further includes a support 800 for supporting.

The support part 800 may stably support the rod 731 so that the translucent panel 736 may be horizontally driven when the cylinder 730 is driven.

The support part 800 includes a fixing ring 810 coupled to the outside of the front end of the rod 731, a moving means 820 including a wheel 821 seated on the bottom surface of the power tool, a moving means 820, and a fixing ring. And support means 830 for connecting 810.

The fixing ring 810 is installed so as not to collide with the cylinder 730 when the rod 731 is driven backward by the driving of the cylinder 730, and is preferably fixed so as not to be separated from the rod 731.

The wheel 821 guides the progress of the rod 731 while being seated on the bottom surface of the electric bulb.

The moving unit 820 further includes a support bar 822 which is formed in a pair and rotatably connected to the wheel 821 inward, and a support plate 823 provided on the support bar 822.

The support means 830 is an upper bar 831 extending downward from the fixing ring 810, the lower portion is connected to the support plate 823, the upper portion is coupled to the upper and lower movable inside the lower portion of the upper bar 831 The lower bar 832, the fastening member 833 coupled to the lower outer side of the lower bar 832, and the spring 834 coupled to the outside of the lower bar 832 to be positioned between the fastening member 833 and the support plate 823. It includes.

The upper bar 831 forms a tubular shape in which both ends are opened, and the lower bar 832 forms a circular rod shape and the upper part is introduced into the lower inner side of the upper bar 831.

The upper bar 831 is formed with a screw thread on the lower outer peripheral surface, the fastening member 833 may be screwed to the lower outer side of the upper bar 831 while the thread is formed on the inner peripheral surface.

The spring 834 presses the wheel 820 downward from the fastening member 833 so that the wheel 820 contacts the bottom surface of the electric bulb.

In addition, the spring 834 buffers the shock while relaxing and relaxing according to the vibration or shock transmitted from the wheel 820 during the progress of the rod 731 according to the driving of the cylinder 70.

The upper bar 831 is formed with guide holes 831a extending upwards from the lower side on both sides thereof.

The lower bar 832 is formed with guide protrusions 832a which are led into guide holes 831a on both sides.

The guide protrusion 832a is positioned above the fastening member 833 and is not separated from the upper bar 831.

Guide protrusion 832a is a wheel 820 while moving in the longitudinal direction of the guide hole 831a in accordance with the rise and fall of the wheel 820, if the bottom surface of the power sphere is irregular, or if there is foreign matter, etc. Along with the lower bar 832, the rise and fall to be made stably.

For this reason, the support part 800 may stably support the rod 731 to allow the translucent panel 736 to progress while maintaining the horizontal state when the cylinder 730 is driven.

The failure zone monitoring system of the underground distribution line according to the present invention further includes a foreign material removal unit 900 for removing foreign substances present in the translucent panel 736 as shown in FIGS. 4 and 6.

The foreign material removing unit 900 removes foreign substances, etc. present on the surface of the semi-transparent panel 736 according to the forward and backward of the translucent panel 736 according to the driving of the cylinder 730 to emit light emitted from the light emitting unit 732. The detection at the light-receiving unit 734 for the to be made accurately.

The foreign material removing unit 900 is disposed above the translucent panel 736 and disposed below the upper frame 910 and the translucent panel 736 to which the upper brush roller 911 is rotatably coupled inward while the lower part is opened. The lower frame 920 to which the brush roller 921 is rotatably coupled to the inside while the upper part is opened, and extends upwardly from the bottom surface of the power outlet, and passes through both sides of the upper and lower frames 910 and 920 ( 930 and the support 930 includes a fixing means 940 for connecting the upper and lower frames 910 and 920 to be lifted and lowered.

The upper frame 910 has a form in which the upper brush roller 911 is rotatably coupled to the inside while forming a 'c' shape in which the lower portion is opened.

The lower frame 920 has a form in which the brush brush 921 is rotatably coupled to the inside while forming an 'c' shape in which the upper portion is opened.

The upper and lower brush rollers 911 and 921 are disposed on an upper portion of the translucent panel 736, and are rotated by the contact with the translucent panel 736 according to the driving of the cylinder 730 and present on the surface of the translucent panel 736. Remove foreign substances.

The upper and lower frames 910 and 920 are disposed between the support part 800 and the light receiving part 734 to allow the translucent panel 736 to be moved forward and backward as the cylinder 730 is driven.

The translucent panel 836 is disposed on the light receiving part 734 through the upper and lower brush rollers 911 and 921 while moving forward as the cylinder 730 moves forward. In this case, the translucent panel 836 may be disposed on the light receiving unit 734 while the foreign matter is removed while passing through the upper and lower brush rollers 911 and 921.

The strut 930 forms a cylindrical shape and passes through both sides of the upper and lower frames 910 and 920.

The upper and lower frames 910 and 920 have upper and lower flanges 912 and 922 formed to extend outwardly on both sides thereof to allow the support 930 to pass therethrough.

The fixing means 940 includes a fixing member 941 screwed to the support 930 to be disposed under the upper flange 912 and a spring 942 connecting the upper and lower flanges 912 and 922.

The support 930 is threaded on the outer circumferential surface, and the fixing member 941 is screwed to the support 930 while the thread is formed on the inner circumferential surface.

The fixing member 941 prevents the upper and lower brush rollers 911 and 921 from falling along with the upper and lower frames 910 and 920 while supporting the upper flange 912 from the support 930.

The fixing member 941 may adjust the position of the upper and lower brush rollers 911 as it moves up and down according to rotation.

The spring 942 is formed in a pair to connect the upper and lower flanges 912 and 922 while being disposed on both sides of the upper and lower brush rollers 911 and 921.

The spring 942 relaxes as the translucent panel 736 is introduced between the upper and lower brush rollers 911 and 921 while the upper and lower brush rollers 911 and 921 are opened, and the upper and lower brush rollers 911 and 921. To be in close contact with the translucent panel 736.

The upper and lower brush rollers 911 and 921 may be in close contact with the translucent panel 736 to effectively remove foreign substances on the surface of the translucent panel 736 while being rotated in accordance with the progress of the translucent panel 736.

Then, the spring 942 is restored to its original state as the translucent panel 736 is drawn out from between the upper and lower brush rollers 911 and 921 so that the upper and lower brush rollers 911 and 921 are returned to their original states.

Here, it is to be understood that the space between the upper and lower brush rollers 911 and 921 is opened or returned to its original state while the upper and lower frames 910 and 920 are moved in the vertical direction by the elastic force of the spring 942.

The fixing means 940 may further include a separation preventing member 943 which is coupled to the upper portion of the support 930 and prevents the separation of the upper flange 912.

For this reason, the foreign matter removing unit 900 removes the foreign matter, etc. present on the surface of the semi-transparent panel 736 according to the forward and backward of the translucent panel 736 according to the driving of the cylinder 730 in the light emitting unit 732 It is possible to accurately detect the light receiving unit 734 for the light to be irradiated.

What has been described above is only an embodiment for implementing the fault section monitoring system of the underground distribution line according to the present invention, the present invention is not limited to the above-described embodiment, as claimed in the following claims Without departing from the gist of the invention, anyone of ordinary skill in the art to which the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

100: sensor unit 120: control unit
200: data collector 210: data collector
220: data transmission unit 230: central processing unit
240: power supply unit 300: upper server
700 detection unit 800 support unit
810: fixing ring 820: means of transportation
830: support means 900: upper frame
910: lower frame 920: lower frame
930: prop 940: fixing means

Claims (1)

A sensor unit 100 for detecting a state of a distribution line;
A data collection device 200 for collecting sensing information of the distribution line detected by the sensor unit 100;
A higher server 300 receiving the sensing information from the data collection device 200 and monitoring a state of a distribution line based on the sensing information; And
It includes a detection unit 700 for detecting whether the sensor unit 100 is broken;
The sensor unit 100,
It includes a water level sensor 106 for detecting the flooding of the power distribution line by detecting the water level of the power outlet installed on the distribution line,
The detection unit 700,
The translucent panel 736 is advanced between the light emitting unit 732 and the light receiving unit 734 to determine whether the water level detecting sensor 106 detects the water level by the light emitting unit 732 and the light receiving unit 734. It includes a water level detection unit consisting of a cylinder 730 to reverse,
The cylinder 730 is,
Underground power distribution line is provided with a rod (731) having a rear end connected to a support (P) extending upward from the bottom of the power port, the front and the rear part is driven in accordance with the front end is connected to the translucent panel 736 In the fault zone monitoring system of
A support part 800 which guides the progress of the rod 731 according to the driving of the cylinder 730 and supports the rod 731 from the bottom surface of the electric power tool; And
Further comprising a foreign material removal unit 900 for removing the foreign matter present in the translucent panel 736,
The foreign material removing unit 900,
The upper frame 910 is disposed on the upper portion of the translucent panel 736 and the upper brush roller 911 is rotatably coupled to the inside while the lower portion is opened, and the upper flange 912 is formed to extend outward on both sides. ;
The lower frame 920 is disposed below the translucent panel 736 and the lower brush 922 is rotatably coupled to the inside while the upper portion is opened, and the lower flange 922 is formed to extend outwardly on both sides. ;
Posts 930 extending from the bottom of the power sphere in the upward direction and passing through both sides of the upper and lower frames (910,920); And
It comprises a fixing means (940) for connecting the upper and lower frames (910,920) to the support (930), the lifting and lowering,
The upper and lower brush rollers (911, 921),
In accordance with the driving of the cylinder 730 is rotated by the contact with the translucent panel 736 to remove foreign substances present on the surface of the translucent panel 736,
The fixing means 940 is,
An upper fixing member 941 screwed to the support 930 so as to be disposed below the upper flange 912; And
The failure section monitoring system of the underground distribution line, characterized in that it comprises a spring (942) for connecting the upper and lower flanges (912,922).

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