KR101854903B1 - Installation structure for underground power distribution line - Google Patents

Abstract

The present invention relates to an installation structure of an underground buried distribution line, in which a humidity sensor, an insulation fluid injection pipe, an insulation fluid injection valve, a spacer, first and second packing, a pressurized fluid injection If a pipe and a pressurized fluid injection valve are installed and an underground water or a storm penetration occurs in the unit buried pipe to detect an increase in humidity, an alarm is generated. In addition, an insulator fluid is injected into the unit buried pipe, It is possible to prevent further intrusion of groundwater or rainwater before the action is taken and infiltration of groundwater or stormwater can be more reliably prevented by injecting the pressurized fluid by using the first and second packing having the expansion space portion Leakage current and power loss can be minimized.

Description

[Background Art] [0002] Installation structures for underground power distribution lines [0003]

More particularly, the present invention relates to an installation structure of an underground buried distribution line, and more particularly, to a structure in which a buried channel for protecting an underground buried distribution line is damaged, Installation of an underground buried distribution line that minimizes leakage or power loss by preventing the penetration of additional groundwater or stormwater before the manager takes action and injects pressure fluid into the buried pipeline .

Generally, a submerged distribution line has manholes installed at regular intervals, and a manhole and a manhole are connected to each other as a submerged channel, and underground distribution lines installed in the submerged channel are connected to each other at a manhole.

Since the underground pipeline is formed of concrete and can not be manufactured to a length corresponding to the distance between the manhole and the manhole in the manufacturing condition, a plurality of unit buried pipes are connected.

As the time elapses, the packing inserted between the end of the unit buried pipe and the socket is displaced due to the earth pressure, groundwater movement, vibration, or the like, so that the function of the packing is lost or partially punctured or cracked In this case, groundwater penetrating into the buried pipe leads to a short circuit in the underground buried power distribution line, resulting in a loss of electric power distributed through the power distribution line.

As a conventional prior art, Korean Registered Patent No. 10-0836215 (Registered on Mar. 2, 2008) "Embedded structure of a submarine electric power line" (hereinafter referred to as "prior art") is applied to the pressure applied to a buried pipe, And discloses a technique for quickly identifying damage.

However, the above-mentioned prior art is to promptly grasp the pressure applied to the buried pipe and whether or not the buried pipe is damaged. Since the penetration of the groundwater or the rainwater due to the damage of the buried pipe is continued until the worker dispatches it to the site for repair, There is a problem that the power loss is not minimized.

Therefore, it is possible to minimize leakage or power loss by detecting groundwater or stormwater in real time due to damage to the buried pipeline that protects the underground buried power distribution line and preventing the invasion of groundwater or rainwater from further proceeding. Development of a technology to make it possible is required.

Korean Registered Patent No. 10-0836215 (Registered on Mar. 2, 2008) "Embedment structure of submerged ground wire"

Accordingly, an object of the present invention is to provide a method and apparatus for detecting groundwater or stormwater infiltration caused by damage to a buried pipeline that protects an underground buried distribution line in real time, injecting pressure fluid into a buried pipeline, To prevent the groundwater or rainwater intrusion from occurring before the power is removed, thereby minimizing leakage or power loss.

According to an aspect of the present invention, there is provided a socket including a tubular portion, a socket portion extended from one end of the tubular portion, and a plurality of stepped portions formed between the tubular portion and the socket portion. An underground buried conduit including a unit buried pipe; A plurality of ground distribution lines installed in the underground buried channel; A first packing closely attached to the step portion and having an expanded space portion; A spacer provided closely to the first packing and having a plurality of through holes in which the outer circumferential surfaces of the plurality of underground distribution lines are closely attached to the inner circumferential surface in an airtight manner; A second packing inserted between the end of the tube portion of the adjacent unit buried pipe and the spacer and closely attached to the spacer and the end portion and having an expansion space portion; A humidity sensor installed inside the unit submerged pipe; an insulated fluid injection pipe inserted into the submerged pipe; An insulated fluid injection valve installed in the middle of the insulated fluid injection pipe corresponding to an inner space of the unit submerged pipe; A pressurized fluid injection tube installed in the underground pipe to inject pressurized fluid into the inflated space of the first and second packings; A branch pipe branching from the pressurized fluid injection pipe and connected to the inflated space portion of the first and second packings; A pressurized fluid injection valve installed in the branch pipe; And a control means for controlling the insulated fluid injection valve and the pressurized fluid injection valve, wherein the control means controls the control means to control the opening and closing of the insulated fluid injection valve in accordance with a sensing signal of the humidity sensor, An insulated fluid injection valve driver for sending an opening and closing drive signal to the insulated fluid injection valve in accordance with a control command of the controller; A pressurized fluid injection valve drive unit for sending an open / close drive signal to the fluid injection valve; and an alarm unit for generating an alarm according to a control command of the control unit.

According to the installation structure of the underground buried distribution line of the present invention, the humidity sensor, the insulation fluid injection pipe, the insulation fluid injection valve, the spacer, the first and second packing, the pressurized fluid injection pipe And a pressurized fluid injection valve is installed to detect an alarm when an underground water or rainwater intrudes into a unit buried pipe and the humidity rises. In addition, an insulator fluid is injected into the unit buried pipe, The infiltration of the groundwater or the rainwater can be prevented more surely by injecting the pressurized fluid by using the first and second packing having the inflated space portion, And power loss can be minimized.

1 to 4 show a first preferred embodiment of an installation structure of an underground buried distribution line according to the present invention,
1 is a schematic vertical sectional view of an installation structure of an underground buried distribution line according to the present embodiment,
2 is a sectional view taken along the line AA in Fig. 1,
3 is a perspective view of a spacer,
4 is a functional block diagram of the control means,
5 is an enlarged partial perspective view of a second preferred embodiment of an installation structure etc. of an underground buried distribution line according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

1 to 4 show a preferred embodiment of an installation structure of an underground buried power distribution line according to the present invention.

As shown in Figs. 1 to 4, an installation structure of an underground buried distribution line according to the present embodiment includes a sub-buried distribution line 10 connected to a plurality of unit buried pipes 20 30) installed in the subway.

The unit buried pipe 20 includes a tubular portion 21 having a predetermined diameter, a socket portion 22 extending and formed at one end of the tubular portion 21, and a socket portion 22 formed between the tubular portion 21 and the socket portion 22 And the unit buried pipes 20 adjacent to each other are connected to each other by inserting the end of the pipe portion 21 into the socket portion 22. [

The unit buried pipe 20 is inserted into the socket portion 22 of the unit buried pipe 20 adjacent to the end portion of the pipe portion 21, A packing for preventing intrusion is inserted.

A spacer 50 is provided in close contact with the first packing 40 and an end portion of the tube portion 21 and a spacer 50 And a second packing 60 that is closely installed between the first packing 60 and the second packing 60.

The first packing (40) and the second packing (60) are made of an elastic material packing used in a conventional buried pipe.

Since the spacer 50 has a plurality of distribution line fixing holes 51 and functions as a partition, it is preferable that the spacers 50 are formed of a metal base coated with an elastic material.

That is, it is preferable that the spacer 50 is formed of a metal base, and the outer surface and the inner circumferential surface of the distribution line fixing hole 51 are covered with an elastic material.

The spacer 50 is formed with an insulator fluid injection tube fixing hole 52 for fixing the insulated fluid injection tube 80 to be described later. The outer circumferential surface of the insulated fluid injection tube (80) is closely attached to the inner circumferential surface of the insulated fluid injection tube fixing hole (52).

A humidity sensor (70) is installed in each of the unit buried pipes (20) constituting the submerged channel (10).

The humidity sensor 70 is connected to a power supply unit (not shown) and a control unit 91 installed in a manhole (not shown) through a power supply and a signal cable 71.

The spacer 50 is also provided with a power supply connected to the humidity sensor 70 to be described later and a power supply connected to a cable passage hole 53 through which the signal cable 71 passes, And a cable passage hole 54 through which the through hole 82 passes.

The humidity sensor 70 is configured to measure the humidity in each unit submerged pipe 20 in real time and transmit the measured humidity value to the control means 90 described later.

An insulated fluid injection pipe (80) is installed in the underground pipe (10) for inserting insulation fluid for each unit submerged pipe (20).

The insulated fluid injection pipe 80 is connected to an insulated gas supply means (not shown) installed throughout the underground pipe 10 and installed in a manhole (not shown).

An insulated fluid injection valve (81) corresponding to each unit submerged pipe (20) is installed in the middle of the insulated fluid injection pipe (80).

The insulated fluid injection valve 81 is connected to a power supply unit (not shown) and a control unit 90 installed in a manhole (not shown) through a power supply and a signal cable 82.

The control unit 91 compares a humidity value measured and transmitted by the humidity sensor 70 with a preset humidity value while memorizing a preset humidity value and opens and closes the insulation fluid injection valve 81 An insulation fluid injection valve driver 92 for sending an opening and closing drive signal to the insulation fluid injection valve 81 in accordance with a control command of the controller 91, And an alarm unit 93 for generating an alarm when the humidity value measured by the sensor 70 is higher than the set humidity value.

The set humidity value can be set to the humidity value in each unit submerged pipe 20 at the time of the initial construction, or it can be set to a proper humidity value by actual inspection by region.

The control unit 91 and the insulated fluid injection valve driving unit 92 may be configured to be operated by receiving power from a power supply unit (not shown) installed in a manhole (not shown).

Hereinafter, the operation of the installation structure of the underground buried distribution line according to the present embodiment will be described.

The humidity value measured by the humidity sensor 70 provided in each unit buried pipe 20 constituting the underground buried channel 10 is transmitted to the control unit 91. When the humidity value is lower than a predetermined set humidity value The control unit 91 outputs a closing control command for the insulated fluid injection valve 81 so that the insulated fluid injection valve drive unit 92 outputs a closed drive signal to the insulated fluid injection valve 81 So that the insulated fluid injection valve 81 is kept closed.

When the humidity value measured by the humidity sensor 70 and transmitted to the control unit 91 is higher than the set humidity value, the control unit 91 regards groundwater or rainwater as intruding into the unit buried pipe 20, The insulated fluid injection valve drive unit 92 outputs an open drive signal to the insulated fluid injection valve 81 so that the insulated fluid injection valve 81 The insulating fluid that is opened and supplied through the insulating fluid injection pipe 80 is injected into the unit buried pipe 20 through the insulating fluid injection valve 81.

This operation can be performed for each unit buried pipe 20 since each unit buried pipe 20 is provided with the humidity sensor 70 and the insulated fluid injection valve 81.

As the insulating fluid, it is possible to use insulating gas such as air or SF6, or to use insulating oil.

When the insulator fluid is injected into the unit buried pipe 20, the pressure in the unit buried pipe 20 is increased. By this pressure, the groundwater or the excellent penetration is blocked, Or the intrusion of the storm does not occur, and as a result, the leakage current and the power loss can be minimized.

In addition, the control unit 91 outputs an alarm control command, thereby causing the alarm unit 93 to generate an alarm, so that the groundwater or the storm enters the unit submerged pipe 20 and the electric leakage and power loss occur And will be able to take action.

Fig. 5 shows a second preferred embodiment of the installation structure of an underground buried distribution line according to the present invention.

The installation structure of the underground buried distribution line according to the present embodiment is configured to expand the first and second packings 40 and 60 so that the intrusion of the groundwater or the rainwater is prevented on the connection portion between the unit buried pipes 20 .

That is, the first and second packings 40 and 60 are formed with the expansion space portions 41 and 61, the pressurized fluid injection tube 100 installed in the underground buried conduit 10, (101, 102) branched from the pipe (100) and connected to the expansion space (41, 61) and a pressurized fluid injection valve (103, 104) installed on the way of the branch .

The control section 91 of the control means 90 is configured to output an opening and closing control command for the pressurized fluid injection valves 103 and 104 in accordance with the humidity value measured and transmitted by the humidity sensor 70 , And a pressurized fluid injection valve driver (94) for sending an open / close drive signal to the pressurized fluid injection valves (103, 104) in accordance with a control command of the control unit (91).

When the humidity value measured by the humidity sensor 70 and the humidity value transmitted to the control unit 91 is higher than the set humidity value, the control unit 91 controls the pressure fluid injection valve 103 104 to open the pressurized fluid injection valves 103, 104 to release the first and second packings (103, 104) The pressurized fluid is injected into the expansion space portions 41 and 61 of the first and second packing portions 40 and 60 so that the first and second packings 40 and 60 expand while the step portion 23 and the spacer 50 and the tube portion 21 So that the penetration of the groundwater or the rainwater on the connecting portion of the unit buried pipes 20 can be blocked.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or essential characteristics thereof. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: Underground pipeline 20: Unit buried pipe
21: tube portion 22: socket portion
23: step jaws 30: underground power distribution lines
40: First packing 41: Expansion space part
50: Spacer 51: Distribution line fixing hole
52: insulated fluid injection tube fixing hole 53, 54: cable passing hole
60: second packing 70: humidity sensor
71: Power and signal cables 80: Insulation fluid injection tube
81: Insulation fluid injection valve 82: Power and signal cable
90: Control means 91:
92: Insulating fluid injection valve drive part 100: Pressurized fluid injection tube
101, 102: branch pipes 103, 104: pressurized fluid injection valve

Claims (1)

A socket portion 22 extended in one end of the tube portion 21 and a step portion 23 formed between the tube portion 21 and the socket portion 22, A plurality of unit buried pipes (20) provided with a plurality of unit buried pipes (20);
A plurality of submerged power distribution lines (30) installed in the underground buried pipeline (10);
A first packing (40) closely attached to the step (23) and having an expansion space (41);
A spacer (50) provided closely to the first packing (40) and having a plurality of distribution line fixing holes (51) in which the outer peripheral surfaces of the plurality of underground embedded distribution lines (30) hermetically contact with the inner peripheral surface;
A second packing 60 inserted between the end of the tube portion 21 of the adjacent unit buried pipe 20 and the spacer 50 and closely attached to the spacer 50 and the end portion thereof and having an expansion space portion 61, and;
A humidity sensor 70 installed inside the unit buried pipe 20,
An insulated fluid injection pipe (80) inserted into the underground pipe (10);
An insulated fluid injection valve (81) disposed in the middle of the insulated fluid injection pipe (80) corresponding to an inner space of the unit submerged pipe (20);
A pressurized fluid injection pipe 100 installed in the underground pipeline 10 for injecting a pressurized fluid into the inflation space portions 41 and 61 of the first and second packings 40 and 60, (101, 102) branching from the pressurized fluid injection pipe (100) and connected to the inflation space portions (41, 61) of the first and second packings (40, 60) A pressurized fluid injection valve 103, And
And control means (90) for controlling the insulation fluid injection valve (81) and the pressurized fluid injection valves (103, 104)
The control means 90 controls the opening and closing of the insulated fluid injection valve 81 according to the sensing signal of the humidity sensor 70 and the control command for opening and closing the pressurized fluid injection valves 103 and 104, An insulated fluid injection valve drive unit 92 for sending an opening and closing drive signal to the insulated fluid injection valve 81 according to a control command of the control unit 91, A pressurized fluid injection valve driver 94 for delivering an opening and closing drive signal to the pressurized fluid injection valves 103 and 104 in response to a control command of the control unit 91 and an alarm unit 93) installed in the underground-type distribution line.

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