KR100772171B1 - Cable's service wire structure for underground pipe laying - Google Patents

Abstract

A wire structure of an underground wire cable is provided to support an underground pipe continuously by upwardly supporting an upper support through the extension of a spring when the ground under an underground pipe sinks. A supporting instrument(100) has a cylinder with opened upper/lower ends, an upper support supporting an underground pipe(2), a lower support supported by the underground earth, and a spring compressed and arranged between the upper and the lower supports. An outer case(200) has an upper plate made of light transmitting material, and a receiving unit. First and second measuring instruments are installed at the outer case, and include first and second protective cases inside the outer case, first and second guide bars installed inside the first and second protective cases, first and second moving plates coupled at the first and second guide bars, first and second springs pressing the first and second moving plates, first and second permanent magnets installed at the first and second moving plates, and a plurality of first and second magnetic proximity switches inside the first and second protective cases. First and second wires(400) have one end connected to the lower support, and the other end fixed at the moving plates. A controlling unit transmits data to a central control center by receiving a location signal from the first and second magnetic proximity switches, and controls first and second winders. A light emitting unit(600) is installed in the outer case, and is turned on/off by the controlling unit.

Description

Cable's Service Wire Structure for Underground Pipe Laying

The present invention relates to a wiring structure of underground cables for stably protecting underground pipes and cables when soil is scoured or settled by groundwater.

In general, underground lines of residential, commercial and industrial complexes are laid with conduits containing transmission and distribution cables.

The underground line is composed of underground pipes embedded in the ground and cables disposed inside the underground pipes, and the cables are protected from external forces.

When underground soil is submerged or scoured by water, the middle line of the underground pipe is struck downward, and the underground pipe may be damaged, resulting in a lot of damage due to cable damage. In addition, there is a problem that the maintenance of the underground pipe can not be easily grasped from the ground and the maintenance is delayed.

The present invention has been invented to solve the above problems, it is possible to immediately grasp the broken state of underground pipes and cables, thereby providing a wiring structure of underground cables for underground cables that are quickly repaired damaged cables There is this.

The present invention is a wiring structure of underground cable, which is embedded in the ground, the cable for underground distribution comprising a cable (C) disposed inside the underground pipe, the cylinder with the upper and lower ends open, the lower end is elevated above the cylinder An upper support capable of being inserted and having an upper end supporting the underground pipe, a lower support having an upper end inserted and lowered at the lower side of the cylinder and supported by the underground soil, and disposed between the upper support and the lower support in a compressed state Support mechanisms with springs; An outer case having an upper plate made of a light-transmitting material, and having an accommodating portion therein, and having an upper surface embedded in the ground so as to be exposed to an upper side of the ground; First and second protective cases respectively provided on both sides of the outer case, the first and second guide bars respectively installed in the up and down direction inside the first and second protection cases, and the first and second guide bars respectively coupled to the lifting and lowering. The first and second moving plates, the first and second springs for upwardly pressing the first and second moving plates, and the first and second permanent plates respectively installed on the first and second moving plates to move together with the first and second moving plates. A first installed in the outer case with a magnet and a plurality of first and second magnetic proximity switches installed on the inner wall of the first and second protective cases in the vertical direction and acting on the magnetic force of the first and second permanent magnets; 2 measuring instruments; First and second wires having one end connected to the lower support and the other end fixed to the moving plate; A control unit which receives the position signal of the first and second moving plates from the first and second magnetic proximity switches and transmits the data to the receiver of the central control room; It is built in an outer case and is connected to the control unit and is configured as a light emitting unit that is controlled ON and OFF by the control unit.

According to the present invention, in the wiring structure of the underground pipe (2) embedded in the ground (1) and a cable (C) disposed inside the underground pipe (2), it is buried in the ground Support mechanism 100 disposed below the underground pipe (2), the outer case 200 embedded in the ground (1) to be located above the underground pipe (2), and is installed in the outer case (200) left and right First and second measuring devices 300 and 300 'installed symmetrically, and first and second wires 400 and 400' having one end connected to the support device 100 and the other end connected to the first and second measuring devices 300 and 300 '. And a control unit 500 receiving up and down position information from the measuring device 300 and 300 ', and a light emitting unit 600 connected to the control unit 500 and controlled ON / OFF by the control unit 500. When the earth and sand located below the underground pipe (2) is subsided, scoured or subsided by groundwater, the situation worker in the central control room It can be confirmed immediately, and there is an effect that the underground pipe (2) is continuously supported until the arrival of the recovery team.

Hereinafter will be described in detail with reference to the accompanying drawings.

1 is an overall schematic view showing the wiring structure of the underground distribution cable according to the present invention, Figure 2 is a cross-sectional view showing the wiring structure of the underground distribution cable according to the present invention, Figure 3 is a underground distribution cable according to the present invention Figure 4 is another cross-sectional view showing a wiring structure of Figure 4 is a block diagram of a measuring unit and a control unit according to the present invention.

1 to 4, the wiring structure of the underground distribution cable according to the present invention will be described.

The wiring structure of the underground distribution cable according to the present invention is the same as the conventional one composed of the underground pipe (2) embedded in the ground (1), and the cable (C) disposed inside the underground pipe (2).

In the wiring structure of the underground distribution cable of the present invention, the support mechanism 100 is disposed in the ground, and is disposed in the ground 1 so as to be located above the underground pipe 2. First and second measuring mechanisms 300 and 300 'which are installed in the outer case 200 and are installed in the outer case 200 and are symmetrically installed, one end of which is connected to the supporting mechanism 100 and the other end of the first and second measurement. First and second wires 400 and 400 'connected to the apparatus 300 and 300', a control unit 500 that receives up and down position information from the first and second measuring instruments 300 and 300 ', and a control unit 500, Further provided is a light emitting unit 600 which is controlled ON / OFF by the control unit 500.

 The support mechanism 100 includes a cylinder 110 having an upper and lower openings, an upper support 120 inserted into an upper portion of the cylinder 110 so as to be elevated, and a lower support inserted into a lower portion of the cylinder 110. 130 and a spring 140 disposed between the upper support 120 and the lower support 130.

The upper support 120 is composed of an upper support plate 121 for supporting the underground pipe (2) exposed to the outside of the upper cylinder 110, and a lower insertion portion 122 is inserted into the cylinder 110 to be elevated. do.

The lower support 130 is composed of an upper inserting portion 131 that is inserted into the cylinder 110 to be elevated, and a lower support plate 132 exposed to the lower portion of the cylinder 110 to be supported by soil.

The spring 140 is inserted into the cylinder 110 in a compressed state in the up and down direction so that the lower end is fixed to the upper insertion part 131 of the lower support 130, and the upper end is the lower insertion part of the upper support 120. 122 is fixed to, when the lower support 130 of the support mechanism 100 is lowered as the soil of the lower portion of the underground pipe (2) is lost, the spring 140 is extended to continue the upper support 130 By pressing upward, the underground pipe (2) is supported so as not to fall. Meanwhile, when installing the support mechanism 100, the spring 140 may be compressed by pressing the upper support 130 downward while the lower support 130 is seated on the soil.

The outer case 200, the upper plate 210 is made of a light-transmissive material, the receiving portion 220 is formed on both inner sides, is embedded in the ground (1) so that the upper surface is exposed to the upper side of the ground (1).

The first and second measuring mechanisms 300 and 300 ′ include first and second protective cases 310 and 310 ′ respectively installed in the receiving portion 220 of the outer case 200, and first and second protective cases 310 and 310 ′. First and second guide bars 320 and 320 'which are installed in the up and down direction, respectively, and the first and second moving plates 340 and 340' coupled to the first and second guide bars 320 and 320 ', respectively. First and second springs 330 and 330 'for upwardly pressing the first and second travel plates 340 and 340' and first and second moving plates 340 and 340 ', respectively. The first and second permanent magnets 350 and 350 'ascending and descending are spaced apart at regular intervals along the vertical direction on the inner walls of the first and second permanent cases 350 and 350'. It consists of a plurality of first and second magnetic proximity switches 360 and 360 'acting on the magnetic force.

The first and second magnetic proximity switches 360 and 360 'are normal magnetic proximity switches which are turned on and off by the first and second permanent magnets 350 and 350' when the first and second permanent magnets 350 and 350 'are close to each other.

Therefore, when the first and second moving plates 340 and 340 'are moved up and down, the first and second magnetic proximity switches closest to the first and second permanent magnets 350 and 350' which are elevated together with the first and second moving plates 340 and 340 '. 360, 360 'is operated, whereby a position signal indicating the position of the first and second moving plates 340 and 340' is sent to the control unit 500.

 The first and second wires 400 and 400 ′ are connected to the first and second moving plates 340 and 340 ′ through upper ends of the first and second wires 400 and 400 ′, and lower ends of the lower support 130. It is fixed to both ends of the support plate 132, respectively.

The control unit 500, when the first and second moving plates 340 and 340 'are lowered from the reference position and the position signal is output from the first and second measuring instruments 300 and 300', receives the light emitting unit 600. Lights up.

The light emitting unit 600 uses LEDs, lamps, and the like, and is accommodated in the accommodating part 220 of the outer case 200, and is turned on and off under the control of the control unit 500.

5 and 6 illustrate the operating state of the wiring structure of the underground distribution cable according to the present invention. Referring to FIGS. 5 and 6, the operation state of the wiring structure of the underground distribution cable according to the present invention will be described below. Same as

As shown in FIG. 1, the support mechanism 100 supports the underground pipe 2 in a state in which the spring 140 is compressed, and the first and second moving plates 340 and 340 'are raised to the reference height. When the earth and sand located in the lower portion of the underground pipe 2 is swept away by the water flowing to the bottom of 2), the lower support 130 is lowered to the lower side. At this time, even if the lower support 130 is lowered, the spring 140 is extended to continuously press the upper support 120, thereby supporting the underground pipe (2) continuously.

Then, as the lower support 130 is lowered, the first and second moving plates 340 and 340 'connected to the first and second wires 400 and 400' and the first and second wires 400 and 400 'are lowered and lowered. The first and second measuring mechanisms 300 and 300 'detect this and output a position signal indicating to the control unit 500 that the first and second moving plates 340 and 340' are lowered. Therefore, the control unit 500 turns on the light emitting unit 600 and transmits a position signal to the receiver H of the central control room.

 Therefore, the situation workers in the central control room can immediately determine whether the soil is lost at any point of the underground pipe (2) can take a quick action, and the worker near the lost point through the light emitting unit 600 to quickly confirm It may be.

As described above, the wiring structure of the underground distribution cable according to the present invention immediately informs the central control room (H) of the situation when the earth or sand located below the underground pipe (2) is scoured or settled by the groundwater. The underground pipe 2 is continuously supported until the recovery team arrives, and a worker in the vicinity can easily find the settled position through the lighted light emitting unit 600. In addition, by installing a plurality of control units 200, it can be confirmed at which point of the underground pipe (2) the settlement occurs.

1 is an overall schematic view showing the wiring structure of the underground distribution cable according to the present invention,

2 is a cross-sectional view showing the wiring structure of the underground distribution cable according to the present invention,

3 is another cross-sectional view showing the wiring structure of the underground distribution cable according to the present invention;

4 is a configuration diagram of a measuring unit and a control unit according to the present invention;

5 and 6 show the operating state of the wiring structure of the underground distribution cable according to the present invention.

Explanation of terms for main parts of attached drawings

One ; Ground 2; Underground piping

C; Cable 100; Support mechanism

200; Outer case 300,300 '; 1st and 2nd measuring instrument

400,400 '; First and second wires 500; Control unit

600; Light emitting unit

Claims (1)

In the wiring structure of a cable for underground distribution, which includes a underground pipe (2) embedded in the ground (1), and a cable (C) disposed inside the underground pipe (2), The upper and lower ends of the cylinder 110, the lower end is inserted into the upper and lower sides of the cylinder 110, the upper support 120 for supporting the underground pipe (2), and the upper end of the cylinder 110 Support mechanism 100 having a lower support 130 is inserted into the lift and supported by the underground soil, and the spring 140 is disposed between the upper support 120 and the lower support 130 in a compressed state Wow ; The upper plate 210 is made of a light-transmissive material, the receiving portion 220 is formed therein, the outer case 200 embedded in the ground (1) so that the upper plate 210 is exposed to the upper side of the ground (1); First and second protective cases 310 and 310 'provided at both sides of the outer case 200, and first and second guide bars 320 and 320' respectively installed in the first and second protective cases 310 and 310 'in the vertical direction. ) And the first and second movable plates 340 and 340 'coupled to the first and second guide bars 320 and 320', respectively, and the first and second movable plates 340 and 340 ', respectively. First and second permanent magnets 350 and 350 'installed in the two springs 330 and 330' and the first and second moving plates 340 and 340 ', respectively, and moving together with the first and second moving plates 340 and 340', and the first and second permanent magnets 350 and 350 '. 2 A plurality of first and second magnetic proximity switches 360 and 360 'installed on the inner walls of the protective cases 310 and 310' to be spaced apart in the vertical direction to act on the magnetic force of the first and second permanent magnets 350 and 350 '. First and second measuring mechanisms 300 and 300 'internally installed in the outer case 200; First and second wires 400 and 400 'having one end connected to the lower support 130 and the other end fixed to the moving plates 340 and 340'; A control unit 500 which receives the position signals of the first and second moving plates 340 and 340 'from the first and second magnetic proximity switches 360 and 360' and transmits the data to the receiver H of the central control room; A light emitting unit 600 installed in the outer case 200 and connected to the control unit 500 and controlled ON / OFF by the control unit 500;  The wiring structure of the underground distribution cable, characterized in that consisting of.

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