KR102644674B1 - Failure section detection system of underground distribution line and its installation method - Google Patents

Abstract

The present invention relates to a method of installing a fault section detection system for an underground distribution line, and more specifically, to a method of constructing a detection system for detecting a fault in a distribution line buried underground, by excavating the ground and forming an excavation hole. A distribution line exposure step of exposing a distribution line buried underground, a distribution line detection system placement step of placing a detection system to be installed on the distribution line inside the excavation hole, and covering the upper part of the excavation hole formed in the ground. An excavation hole blocking net installation step of arranging a blocking net, a distribution line detection system installation step of installing a detection system disposed inside the excavation hole to the distribution line, and removing the blocking net installed while covering the excavation hole. It consists of a step of removing the excavation block blocking network and a step of finishing the excavation hole by inserting soil into the excavation hole. In the step of installing the distribution line detection system, the work situation at the site is identified by a continuous confirmation work guidance means, and A continuous confirmation work guidance step is further included to transmit a danger signal when a situation occurs, and a fault section detection system is established in the distribution line buried underground to detect faults such as electric leakage and fire that occur in the distribution line, and to send a detection signal. By transmitting, rapid maintenance is possible and it is easy to identify damaged sections of distribution lines, thereby enabling accurate and effective maintenance.

Description

Failure section detection system of underground distribution line and its installation method}

The present invention relates to a method of installing a fault section detection system in an underground distribution line in the field of distribution technology. More specifically, by providing a fault section detection system in a distribution line buried underground, to prevent electrical leakage and fire occurring in the distribution line. A method of installing a fault section detection system for underground distribution lines that detects the same fault and transmits a detection signal, enabling rapid maintenance and making it easy to identify damaged sections of the distribution line, enabling accurate and effective maintenance. It's about.

Distribution cables, which are distribution lines through which power is generally applied in urban areas, are buried underground at a predetermined depth, receive power generated from power plants, and supply power to demand-side buildings (apartment buildings) on the ground. Hereinafter, distribution cable and wiring cable have the same meaning and will be described selectively to suit the context.

These distribution lines are buried underground and are periodically inspected for damage to the coating caused by external forces, disconnection, and short circuits. When damaged, a certain section of the distribution line is cut and replaced with a new distribution line.

However, the conventional distribution line has no means of detecting a short circuit or fire when it occurs due to friction or cutting due to external force or vibration, so there is a problem in that safety accidents due to short circuit frequently occur, and it is difficult to check the damaged part of the distribution line. There is a problem that it is difficult and takes excessive time for maintenance, and as a result, there is a problem of excessive maintenance costs.

The above-described invention refers to the background art of the technical field to which the present invention pertains, and does not mean prior art.

Republic of Korea Patent Publication No. 10-0709571 Republic of Korea Patent Publication No. 10-2001-05958

The present invention was devised to solve the above-described conventional problems. The purpose of the present invention is to provide a fault section detection system in a distribution line buried underground, to detect faults such as electric leakage and fire occurring in the distribution line. By detecting and transmitting a detection signal, rapid maintenance is possible and it is easy to identify damaged sections of the distribution line, thereby providing a method of installing a system for detecting faulty sections of underground distribution lines that enables accurate and effective maintenance. There is a purpose.

The present invention is a method of constructing a detection system for detecting a failure of a distribution line buried underground, comprising a distribution line exposure step of excavating the ground to form an excavation hole to expose the distribution line buried underground, and an inside of the excavation hole. A distribution line detection system arrangement step of arranging a detection system to be installed in the distribution line, an excavation hole blocking net installation step of arranging a blocking net while covering the upper part of an excavation hole formed in the ground, and placement inside the excavation hole. A distribution line detection system installation step of installing a detection system installed on the distribution line, a drilling hole blocking net removal step of removing the blocking net installed while covering the digging hole, and excavation by inserting soil into the digging hole. It consists of a construction finishing stage, and the distribution line detection system installation stage further includes a continuous confirmation work guidance stage to identify the work situation on site by continuous confirmation work guidance means and to transmit a danger signal when an emergency situation occurs. do.

The present invention is a detection system for detecting a failure of a distribution line buried underground, comprising an installation panel whose bottom is connected to and fixed to the outer surface of the distribution line, through holes formed in the installation panel, and a connection between the distribution line and the distribution line. a sensing casing that is fastened to cover the upper surface of the connected installation panel and has an installation space therein; a support shaft connected to and fixed to the upper surface of the installation panel installed in the distribution line and disposed inside the sensing casing; A guide shaft connected to and fixed to the upper end of the holding shaft, the lower end of which is connected to the installation panel, detection sensors formed on the guide shaft, connected to and fixed to the upper surface of the installation panel, and receiving a detection signal from the detection sensor. It consists of a transmitter and a receiver that receive and transmit the signal, and the installation panel is further provided with support and fixing means to support the sensing casing and prevent the sensing casing from moving due to external force or vibration, and the support and fixing means include: An extension bar whose ends are connected and fixed to both sides of the installation panel, a support bar whose lower ends are connected and fixed to the other end of the extension bar installed on the installation panel, and which supports both sides of the sensing casing, and is formed at an upper end of the support bar. It is characterized by consisting of a hitch bar supporting the upper surface of the sensing casing.

The present inventor's method of installing a fault section detection system for an underground distribution line is to provide a fault section detection system in a distribution line buried underground, detect faults such as short circuits and fires occurring in the distribution line, and transmit a detection signal. , rapid maintenance is possible and it is easy to identify damaged sections of distribution lines, which has the effect of enabling accurate and effective maintenance.

Figure 1 is a cross-sectional view showing a system for detecting a fault section of an underground distribution line according to the present invention.
Figure 2 is an exploded view showing a system for detecting a fault section of an underground distribution line according to the present invention.
Figure 3 is an installation state diagram showing a system for detecting a fault section of an underground distribution line according to the present invention.
Figure 4 is an exploded view showing the support and fixing means of the system for detecting a fault section of an underground distribution line according to the present invention.
Figure 5 is a cross-sectional view showing the support and fixing means of the system for detecting a fault section of an underground distribution line according to the present invention.
Figure 6 is a diagram showing the elastic buffer support means of the fault section detection system for underground distribution lines according to the present invention.
Figure 7 is a diagram showing the continuous confirmation operation guidance means of the fault section detection system of the underground distribution line according to the present invention.
Figure 8 is a diagram showing another embodiment of the continuous confirmation work guidance means of the fault section detection system of the underground distribution line according to the present invention.
Figure 9 is a conceptual diagram showing the continuous confirmation operation guidance means of the fault section detection system of the underground distribution line according to the present invention.

Since the description of the present invention is only an example for structural or functional explanation, the scope of the present invention should not be construed as limited by the examples described in the text. In other words, since the embodiments can be modified in various ways and can have various forms, the scope of rights of the present invention should be understood to include equivalents that can realize the technical idea.

Meanwhile, the meaning of the terms described in the present invention should be understood as follows.

Terms such as “first” and “second” are used to distinguish one component from another component, and the scope of rights should not be limited by these terms. For example, a first component may be named a second component, and similarly, the second component may also be named a first component.

When a component is said to be “connected” to another component, it should be understood that it may be directly connected to the other component, but that other components may also exist in between. On the other hand, when a component is referred to as being “directly connected” to another component, it should be understood that there are no other components in between. Meanwhile, other expressions that describe the relationship between components, such as "between" and "immediately between" or "neighboring" and "directly neighboring" should be interpreted similarly.

Singular expressions should be understood to include plural expressions unless the context clearly indicates otherwise, and terms such as “comprise” or “have” refer to implemented features, numbers, steps, operations, components, parts, or them. It is intended to specify the existence of a combination, and should be understood as not excluding in advance the possibility of the presence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof.

For each step, identification codes (e.g., a, b, c, etc.) are used for convenience of explanation. The identification codes do not explain the order of each step, and each step clearly follows a specific order in context. Unless specified, events may occur differently from the specified order. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the opposite order.

All terms used herein, unless otherwise defined, have the same meaning as commonly understood by a person of ordinary skill in the field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as consistent with the meaning they have in the context of the related technology, and cannot be interpreted as having an ideal or excessively formal meaning unless clearly defined in the present invention.

Figure 1 is a cross-sectional view showing a system for detecting a fault section of an underground distribution line according to the present invention. Figure 2 is an exploded view showing a system for detecting a fault section of an underground distribution line according to the present invention. Figure 3 is an installation state diagram showing a system for detecting a fault section of an underground distribution line according to the present invention. Figure 4 is an exploded view showing the support and fixing means of the system for detecting a fault section of an underground distribution line according to the present invention. Figure 5 is a cross-sectional view showing the support and fixing means of the system for detecting a fault section of an underground distribution line according to the present invention. Figure 6 is a diagram showing the elastic buffer support means of the fault section detection system for underground distribution lines according to the present invention. Figure 7 is a diagram showing the continuous confirmation operation guidance means of the fault section detection system of the underground distribution line according to the present invention. Figure 8 is a diagram showing another embodiment of the continuous confirmation work guidance means of the fault section detection system of the underground distribution line according to the present invention. Figure 9 is a conceptual diagram showing the continuous confirmation operation guidance means of the fault section detection system of the underground distribution line according to the present invention.

As shown in the drawing, the present invention's installation method 10 of a fault section detection system for underground distribution lines (hereinafter referred to as section detection system for convenience of explanation) is a detection system for detecting faults in distribution lines buried underground. (10), this detection system (10) includes an installation panel (20), a through hole (21), a detection casing (30), a support shaft (40), a guide shaft (41), a detection sensor (50), and It consists of a transmitter and a receiver (60).

The installation panel 20 is fixed with its bottom connected to the outer surface of the distribution line 100, which is a cable.

The installation panel 20 is made of metal or synthetic resin, and is attached and fixed to the outer surface of the distribution line 100.

The installation panel 20 can also be formed into a curved panel structure.

The through holes 21 are formed in the installation panel 20.

The heat generated in the distribution line 100 by the through holes 21 is transmitted to the detection sensor 50 through the through holes 21.

The sensing casing 30 is fastened to cover the upper surface of the installation panel 20 connected to the distribution line 100, and an installation space is provided therein.

The sensing casing 30 is fixed to the upper surface of the installation panel 20 by attaching or screwing its lower part.

The detection casing 30 can protect the detection sensor 50 and the transmitter and receiver 60 from underground soil.

The holding shaft 40 is connected to and fixed to the upper surface of the installation panel 20 installed on the distribution line 100, and is disposed inside the sensing casing 30.

The support shaft 40 is formed as a circular or square rod structure, and its lower end is screwed and fixed to the upper surface of the installation panel 20.

The guide shaft 41 is fixed by screwing its middle portion to the upper end of the support shaft 40 as shown in the drawing.

The holding shaft 40 is made of metal.

Here, a buffer bracket bar is further screwed and fixed to the upper surface of the installation panel 20, lower ends of buffer coil springs are screwed and fixed to the buffer bracket bar, and upper ends of the buffer coil springs are connected to the guide shaft (41). ), it is desirable to support the guide shaft 41 by the elasticity of the buffer coil spring to prevent it from sagging and to cushion the shock transmitted from the outside.

The detection sensor 50 is fixed to the guide shaft 41 by screwing or attaching it at a certain distance.

The detection sensor 50 detects heat transmitted through the through hole 21 or heat transmitted from the installation panel 20 or the distribution line 100, and transmits the detection signal to the It is transmitted to the receiver 60.

At this time, the detection sensor 50 is a heat detection sensor 50, and when a fire occurs in the distribution line 100 due to overheating or external shock, it detects it and transmits it to the transmitter and receiver 60. A detection signal is transmitted to the terminal of the person in charge or resident through the transmitter and receiver 60, allowing prompt action to be taken.

In addition, by further screwing the position detection sensor 50 to the detection panel, it detects when the distribution line 100 is broken or moves due to an external force, and transmits a signal through the transmitter and receiver 60 for rapid maintenance. It is desirable to ensure that .

The transmitter and receiver 60 are connected and fixed to the upper surface of the installation panel 20, and receive and transmit the detection signal from the detection sensor 50.

The transmitter and receiver 60 are screwed and fixed to the upper surface of the installation panel 20, and receive and transmit signals from the detection sensor 50.

The installation panel 20 is further provided with support and fixing means 70 to support the sensing casing 30 and prevent the sensing casing 30 from moving due to external force or vibration.

The support and fixing means 70 includes an extension bar 71, one end of which is screwed or attached to both sides of the installation panel 20, and the other end of the extension bar 71 installed on the installation panel 20. The lower end is screwed and fixed to the support bar 72 that supports both sides of the sensing casing 30, and is formed on the upper end of the support bar 72 to support the upper surface of the sensing casing 30. It consists of a locking bar 73, and the support bar 72 and the locking bar 73 support both sides and the upper surface of the sensing casing 30, so that the sensing casing 30 is moved by external force or the installation panel. This prevents separation in (20).

Here, the support bar 72 is further provided with a pressure-type elastic support fixing means 80 to press and secure the inserted sensing casing 30 by elasticity and support it.

The pressure-type elastic support fixing means 80 includes an operating groove 81 formed on the inner surface of the support bar 72, and an elastic pressure coil spring whose one end is inserted into the operating groove 81 and fixed by screwing. (82), a pressure panel (83) whose one side is screwed and fixed to the other end of the elastic pressure coil spring (82), and a synthetic resin material with elasticity that is attached and fixed to the other side of the pressure panel (83). The elastic pressure support panel 84, the elastic pressure coil spring 82, and the elasticity of the elastic pressure support panel 84 pressurize and support the sensing casing 30, preventing it from being moved by external force. It is desirable to prevent and buffer external forces or vibrations from being transmitted.

The construction method of the detection system configured as above to detect a failure of a distribution line buried underground includes a distribution line exposure step (S1) in which the distribution line 100 buried underground is exposed by excavating the ground to form an excavation hole. ) and a distribution line detection system arrangement step (S2) of arranging the detection system 10 to be installed on the distribution line inside the excavation hole, and screwing a blocking net into the ground while covering the upper part of the excavation hole formed on the ground. When fastening or fixing with piles, it goes through the excavation hole blocking net installation step (S3).

Thereafter, a distribution line detection system 10 installation step (S4) of installing the detection system 10 disposed inside the excavation hole to the distribution line, and an excavation hole removing the blocking net installed while covering the excavation hole. A series of processes are completed through the blocking net removal step (S5) and the excavation hole finishing step (S6) by inserting soil into the excavation hole.

At this time, in the installation step (S4) of the distribution line detection system 10, the work situation on site is identified by the continuous confirmation work guidance means 90, and the continuous confirmation work guidance step (S4- 1) is further included.

The continuous confirmation operation guide means (90) includes a connection fixing module unit (91) screwed and fixed to the detection casing (30) or disposed on the bottom of the excavation hole, and an upper surface portion of the connection fixing module unit (91). A pair of guide shafts (92) whose lower ends are connected and fixed to the first panel transfer module (931) and a second panel that are inserted through the guide shaft (92) and guided along the guide shaft (92) A transfer module unit 93 consisting of a transfer module 932 and a third panel transfer module 933, and a lower end are screwed and fixed to the upper surface of the connection fixing module unit 91, and the lifting shaft is connected to the first panel. A first lifting guide unit 941 is screwed and fixed to the bottom of the transfer module 931, the lower end is screwed and fixed to the top of the first panel transfer module 931, and the lift shaft is connected to the second panel transfer. A second lifting guide unit 942 is screwed and fixed to the bottom of the module 932, the lower part is screwed and fixed to the top of the second panel transfer module 932, and the lift shaft is fixed to the third panel transfer module 932. A lifting guide unit 94 consisting of a third lifting guide unit 943 screwed and fixed to the bottom of the module 933, screwed and fixed to the bottom of the first panel transfer module 931, and connected to the rotation axis. The first rotation module unit (951-1) is screwed and fixed to the bottom of the first rotation guide units (951) and the second panel transfer module (932), and the second rotation module unit (952) is attached to the rotation axis. -1) The second rotation guide units 952 are screwed and fixed to the bottom of the third panel transfer module 933, and the third rotation module unit 953-1 is screwed to the rotation axis. A rotation guide unit 95 consisting of third rotation guide units 953, first situation photography units 961 screwed and fixed to the bottom of the first rotation module unit 951-1, and The second situation photography units 962 are screwed and fixed to the bottom of the second rotation module unit 952-1, and the third is screwed and fixed to the bottom of the third rotation module unit 953-1. A situation photography unit 96 consisting of situation photography units 963 is screwed and fixed to the connection fixing module unit 91, and is electrically connected to the lifting guide unit 94 and the rotation guide unit 95. A control unit 97 that is connected and controlled and receives shooting information of the first situation photography unit 961, the second situation photography unit 962, and the third situation photography unit 963, and the third panel transfer It is screwed and fixed to the module 933, and the shooting information of the first situation photography unit 961, the second situation photography unit 962, and the third situation photography unit 963 is transmitted from the control unit 97. A transmitting and receiving unit 98 that transmits and a status information speaker 99 that is screwed and fixed to the third panel transfer module 933 and receives a signal from the control unit 97 to guide a voice or generate an alarm. ).

The connection fixing module unit 91 is made of a panel structure made of metal and is placed on the ground.

The first panel transfer module 931, the second panel transfer module 932, and the third panel transfer module 933 are formed of metal or synthetic resin panels and are inserted into the guide shaft 92. A transfer hole is formed.

The first lifting guide unit 941, the second lifting guiding unit 942, and the third lifting guiding unit 943 are cylinders, and the first rotating guiding unit 951 and the second rotating guiding unit ( 952) and the third rotation guide unit 953 are motors, and the first situation photography units 961, the second situation photography units 962, and the third situation photography unit 963 are cameras.

Additionally, the first rotation module unit 951-1, the second rotation module unit 952-1, and the third rotation module unit 953-1 are formed in a circular or square panel structure.

The first situation photography units 961, the second situation photography units 962, and the third situation photography units 963 include the first lifting and lowering guidance unit 941 and the second lifting and lowering guidance unit 942. ) and the driving of the third lifting guide unit 943, the height can be changed, and it is possible to take pictures of field conditions or risk factors on the ground or ground.

The control unit 97 receives the signal received from the transmitter and receiver 98 through the administrator terminal and controls the status guide speaker 99 to transmit a voice or generate an alarm.

In other words, after recognizing the dangerous situation of the phenomenon through the shooting information, it is possible to prevent safety accidents in the field by transmitting a dangerous signal through the status information speaker 99.

In addition, the control unit 97 receives the signal received from the transmitting and receiving unit 98 through the administrator terminal and controls the operation of the lifting guide unit 94 and the rotation guiding unit 95, The positions of the situation photography units 961, the second situation photography units 962, and the third situation photography unit 963 can be changed.

Although the present invention has been described in detail so far, it is clear that the embodiments mentioned in the process are only illustrative and not limiting, and that the present invention is limited to the technical idea or field of the present invention provided by the following patent claims. Changes in components to the extent that they can be handled equally, within the scope of the above, will fall within the scope of the present invention.

10: detection system 20: installation panel
21: Through hole 30: Detection casing
40: Holding shaft 41: Guide shaft
50: Detection sensor 60: Transmitter, receiver
70: Support fixing means 71: Extension bar
72: support bar 73: hanging bar
80: Fixed elastic pressure support means 81: Operating groove
82: elastic pressurizing coil spring 83: pressurizing panel
84: Elastic pressure support panel 90: Continuous confirmation work guidance means
91: Connection fixing module unit 92: Guide shaft
93: Transfer module unit 931: First panel transfer module
932: 2nd panel transfer module 933: 3rd panel transfer module
94: Lifting guide unit 941: First lifting guidance unit
942: 2nd lifting guide unit 943: 3rd lifting guide unit
95: Rotation guide unit 951: First rotation guide unit
951-1: 1st rotation module unit 952: 2nd rotation guidance unit
952-1: 2nd rotation module unit 953: 3rd rotation guidance unit
953-1: Third rotation module unit 96: Situation photography unit
961: First situation photography unit 962: Second situation photography unit
963: Third situation photography unit 97: Control unit
98: Transmitter, receiver 99: Status information speaker

Claims (2)

A method of constructing a detection system for detecting failures in distribution lines buried underground,
A distribution line exposure step of excavating the ground to form an excavation hole and exposing the distribution line buried underground;
A distribution line detection system placement step of placing a detection system to be installed on the distribution line inside the excavation hole;
A digging hole blocking net installation step of arranging a blocking net while covering the upper part of the digging hole formed in the ground;
A distribution line detection system installation step of installing the detection system disposed inside the excavation hole to the distribution line;
A drilling hole blocking net removal step of removing the blocking net installed while covering the digging hole; and
It consists of the excavation hole finishing step of filling the excavation hole with soil,
The distribution line detection system installation step further includes a continuous confirmation work guidance step to identify the work situation on site by continuous confirmation work guidance means and to transmit a danger signal when an emergency situation occurs,
The detection system is,
An installation panel whose bottom is connected to and fixed to the outer surface of the distribution line,
Through holes formed in the installation panel,
A sensing casing that covers and fastens the upper surface of the installation panel connected to the distribution line and has an installation space therein,
a support shaft connected to and fixed to the upper surface of the installation panel installed on the distribution line and disposed inside the sensing casing;
A guide shaft connected to and fixed to the upper end of the holding shaft, the lower end of which is connected to the installation panel,
Detection sensors formed on the guide shaft,
It is connected and fixed to the upper surface of the installation panel and consists of a transmitter and receiver that receive and transmit the detection signal from the detection sensor,
The installation panel is further provided with support fixing means to support the sensing casing and prevent the sensing casing from moving due to external force or vibration,
The support and fixing means are,
An extension bar whose ends are connected and fixed to both sides of the installation panel,
A support bar whose lower end is connected and fixed to the other end of the extension bar installed on the installation panel and supports both sides of the sensing casing;
It is formed at the upper end of the support bar and consists of a locking bar that supports the upper surface of the sensing casing,
The support bar is further provided with pressure-type elastic support fixing means to press and secure the inserted sensing casing by elasticity and support it,
The pressurized elastic support fixing means,
An operating groove formed on the inner surface of the support bar, an elastic pressure coil spring whose end is inserted into the operating groove and fixed by screwing,
a pressurizing panel whose one side is screwed and fixed to the other end of the elastic pressurizing coil spring;
An elastic pressure support panel made of an elastic synthetic resin material that is attached and fixed to the other surface of the pressure panel;
Characterized in that the detection casing is pressed and supported by the elasticity of the elastic pressure coil spring and the elastic pressure support panel, preventing movement by external force and buffering the transmission of external force or vibration. Installation method of fault detection system for underground distribution lines.

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