KR102167874B1 - Cable structure for underground power lines with earthquake function - Google Patents

Abstract

Provided is a distribution underground power cable structure having seismic performance which can prevent disconnection accidents in advance. The distribution underground power cable structure having seismic performance comprises: a plurality of unit protection tubes in which an underground power cable is disposed; flexible tubes connecting the plurality of unit protection tubes; a posture control unit fixed to an inner wall of the plurality of unit protection tubes and rotating an underground power cable to reach a set reference position; a sensor unit installed in the plurality of unit protection tubes and measuring impact force from the outside; and a length shifter installed in the posture control unit and controlling tension to loosen a predetermined length of the underground power cable when the measured impact force exceeds set reference impact force.

Description

Cable structure for underground power lines with earthquake function

The present invention relates to a structure of an underground power cable for distribution with seismic performance, and more particularly, by connecting both ends of the protection pipes in which the power cable is accommodated through tubes having a certain thickness, horizontal, vertical, and rotational It has a seismic performance that prevents disconnection accidents in advance by allowing the position to be changed according to the direction to prevent damage to the protective tube itself, and to be able to rotate so that the original position is always maintained so that the cable is not twisted inside the protective tube. It relates to the structure of an underground power cable for distribution.

Usually, underground cables are buried in each city to supply power to each customer.

The underground electric wire makes the aesthetic of the city more beautiful than the underground installation of the power line.

In addition, underground electric wires can efficiently utilize space. Therefore, the use trend of underground electric wire is gradually increasing.

The underground electric wire is generally installed in an underground tunnel through a shelf on which the underground electric wire is arranged.

When an earthquake occurs in such a structure, the shelf shakes along the underground tunnel, and a considerable external force acts on the connection between the underground tunnel and the shelf, causing problems such as disconnection of the underground electric wires arranged on the shelf.

In addition, when a disconnection occurs in the underground electric wire, there is no way to immediately check it, and thus it takes a long time to restore the underground electric wire from the ground.

Accordingly, conventionally, a corrugated pipe is installed between the protective pipes that protect the underground wires to respond to bending, but in the case of an earthquake, if the protective pipes are rotated and twisted, including left and right, up and down, the cable in the protective pipe may be twisted and disconnection may occur There are also problems.

Korean Patent Registration No. 10-144014 (Registration Date: 2014.09.03)

Therefore, in order to solve the above problems, the present invention connects both ends of the protection tubes in which the power cables are accommodated through tubes having elasticity having a certain thickness so that the positions are changed according to the horizontal, vertical, and rotational directions due to earthquakes. Provides an underground power cable for distribution with seismic performance that prevents disconnection accidents in advance by making it possible to rotate so that the original position is always maintained so that the cables are not twisted inside the protective tube as well as prevent damage to the protection tube itself. It is aimed at.

In addition, the present invention ensures that the support members automatically protrude from the periphery of the protective tube in case of an earthquake with an impact force greater than a certain level to secure a certain amount of support, and also check the linear position information of the protective pipes and underground power cables in real time. Another object is to provide an underground power cable for distribution with seismic performance that can accurately identify the maintenance location by checking the position of the protective tube and the power cable in the event of an earthquake and after the earthquake. .

In order to achieve the above object, the present invention provides a plurality of unit protection pipes in which an underground power cable is disposed; Flexible tubes connecting between the plurality of unit protection tubes; A posture control unit fixed to an inner wall of the plurality of unit protection tubes and rotating the underground power cable to a set reference position; A sensor unit installed in the plurality of unit protection tubes and measuring an impact force from the outside; And, a length variator installed in the attitude control unit and configured to control a tension to loosen the underground power cable by a predetermined length when the measured impact force exceeds a set reference impact force. Provides a dedicated underground power cable structure.

Here, the posture control unit,

A body fixed to the inner periphery of each of the plurality of unit protection tubes and having a through hole through which the underground power cable passes,

A rotating ring installed inside the body and contacting the outer periphery of the underground power cable passing through the through hole;

A rotating gear connected in a gear manner with a gear tooth formed on the outer circumference of the rotating ring,

A motor connected in an axial manner to the center of the rotating gear,

And a controller for rotating the rotation gear by driving the motor,

A protruding line is formed on the outer periphery of the underground power cable,

In the inner circumference of the rotating ring, a protruding groove into which the protruding line is fitted is formed,

In the controller,

The reference position is set.

And the length variable part,

A variable part body in which an inner space is formed and a moving hole through which the underground power cable is moved is formed at both ends,

A pair of guide rollers disposed in the inner space of the variable part body and disposed in the vicinity of each of the moving holes to guide the movement of the underground power cable,

A moving roller located below the center of the pair of guide rollers to guide the movement of the underground power cable,

It is fixed to the upper wall of the inner space of the variable part body, and has an elevating cylinder having an elevating shaft to elevate,

The end of the lifting shaft is connected to the rotation center of the moving roller,

The controller controls the lifting of the lifting shaft through the lifting cylinder.

In addition, the plurality of unit protection tubes,

It is placed inside the outer tube,

Rail grooves formed along the length direction are formed in the inner circumference of the outer tube,

Rail protrusions are formed on the outer periphery of the plurality of unit protection tubes to enable sliding movement by being coupled to the rail grooves in a rail manner.

In particular, on the outer periphery of each of the plurality of unit protection tubes,

Mounting grooves are formed,

In the seating grooves, the rail protrusions are disposed.

Elastic springs are interposed between the rail protrusions and the seating grooves,

The plurality of unit protection tubes are elastically movable.

In addition, in a plurality of locations on the outer periphery of the outer tube,

Cylinders with a shaft that stretches and contracts are fixed,

Support members having a pointed end are installed at the ends of the shaft of each of the cylinders,

The controller,

When the measured impact force achieves more than the set reference impact force,

The cylinders are used to protrude the shaft so that the support members are driven into the ground.

In addition, first position sensors are installed in the cover of the underground power cable to measure the first position values by being buried at intervals,

The plurality of unit protection tubes are provided with second position sensors that measure second position values at intervals,

The controller,

Among the measured first and second position values, when there is an abnormal position value out of the set range or more from the set reference position values,

The position of the moving roller is further changed so that the underground power cable is loosened by a predetermined length by using the length variable part, which is disposed near the ideal position value.

As described above, the present invention prevents damage to the protection tube itself by connecting both ends of the protection tubes in which the power cables are accommodated through flexible tubes having a certain thickness so that the positions are changed according to the horizontal, vertical, and rotational directions due to earthquakes. In addition, there is an effect of preventing a disconnection accident in advance by allowing the cable to be rotated to always maintain its original position so as not to twist the cable inside the protective tube.

In addition, the present invention ensures that the support members automatically protrude from the periphery of the protective tube in case of an earthquake with an impact force greater than a certain level to secure a certain amount of support, and also check the linear position information of the protective pipes and underground power cables in real time. Therefore, it is effective to accurately identify the maintenance location by checking the position of the protective tube and the power cable changed during and after the earthquake.

In addition to the above-described effects, specific effects of the present invention will be described together while describing specific details for carrying out the present invention.

1 is a diagram showing a structure of an underground power cable for distribution with seismic performance of the present invention.
2 is a diagram showing a configuration of a posture control unit according to the present invention.
3 is a view showing an example of a combination of an underground power cable and a rotary ring according to the present invention.
4 is a diagram showing a configuration of a length variable part according to the present invention.
5 is a view showing an example in which unit protection tubes according to the present invention are arranged inside an outer tube.
6 is a view showing another example in which the unit protection tubes according to the present invention are arranged inside the outer tube.
7 is a view showing an example in which a configuration in which support members protrude is added to an outer tube according to the present invention.
8 is a diagram showing an example in which position sensors are installed in unit protection tubes and underground power cables according to the present invention.

A preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings. Here, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description will be omitted. In addition, the same reference numerals in the drawings are used to indicate the same or similar elements.

1 is a diagram showing a structure of an underground power cable for distribution with seismic performance of the present invention.

Referring to FIG. 1, the structure of an underground power cable for distribution with seismic performance of the present invention connects a plurality of unit protection pipes 100 in which an underground power cable 10 is disposed inside, and the plurality of unit protection pipes 100 The flexible tubes 200 are fixed to the inner wall of the plurality of unit protection tubes 100, and the posture control unit 300 rotates the underground power cable 10 to reach a set reference position, and the plurality of It is installed in the unit protection tube 100, the sensor unit 400 for measuring the impact force from the outside, and the posture control unit 300, when the measured impact force exceeds a set reference impact force, the underground power cable ( 10) is composed of a length variator 500 that controls the tension to loosen a certain length.

2 is a diagram showing a configuration of a posture control unit according to the present invention.

Referring to FIG. 2, the attitude control unit 300 according to the present invention is fixed to the inner circumference of each of the plurality of unit protection tubes 100, and a through hole 311 through which the underground power cable 10 passes is formed. 310), a rotating ring 320 installed inside the body 310 and contacting the outer circumference of the underground power cable 10 passing through the through hole 311, and the rotating ring 320 A rotation gear 330 connected in a gear manner with a gear tooth formed on the outer periphery, a motor 340 connected in an axial manner with a center of the rotation gear 330, and the rotation gear 340 by driving the motor 340 It consists of a controller 350 to rotate 330.

3 is a view showing an example of a combination of an underground power cable and a rotary ring according to the present invention.

Referring to FIG. 3, a protruding line 11 is formed on the outer periphery of the underground power cable 10.

A protruding groove 321 into which the protruding line 11 is fitted is formed on the inner periphery of the rotary ring 320. In the controller 350, the reference position is set.

When the rotary ring 320 is rotated through the above configuration, the underground power cable 10 is rotated according to the rotation of the rotary ring 320.

In addition, a multi-stage pipe 360 is installed on the inner periphery of the plurality of unit protection pipes 100. The multi-stage pipe 360 is configured to allow elastic flow along the top and bottom by springs (not shown) installed therein.

Accordingly, the body 310 according to the present invention is connected to the lower end of the multistage pipe 360 so that the shock can be easily absorbed by external elasticity and the original position can be easily maintained.

4 is a diagram showing a configuration of a length variable part according to the present invention.

Referring to FIG. 4, the variable length part 500 according to the present invention includes an inner space, and a variable part body 510 in which a moving hole 511 through which the underground power cable 10 moves is formed at both ends. ), and a pair of guide rollers 520 disposed in the inner space of the variable body 510 and disposed in the vicinity of each of the moving holes 511 to guide the movement of the underground power cable 10 And, a moving roller 530 located below the center of the pair of guide rollers 520 to guide the movement of the underground power cable 10, and an upper wall of the inner space of the variable body 510 It is fixed to and consists of a lifting cylinder 540 having a lifting shaft 541 that is elevated.

The variable part body 510 is integrally coupled to the vicinity of the through hole 311 on one side of the body 310. The moving hole 511 communicates with the through hole 311.

Here, the end of the lifting shaft 541 is connected to the rotation center of the moving roller 530.

The controller 350 controls the lifting of the lifting shaft 541 through the lifting cylinder 540.

5 is a view showing an example in which unit protection tubes according to the present invention are arranged inside an outer tube.

Referring to FIG. 5, a plurality of unit protection tubes 100 according to the present invention are disposed inside the outer tube 600.

Rail grooves 610 formed along the length direction are formed on the inner periphery of the outer tube 600.

Rail protrusions 110 are formed on the outer periphery of the plurality of unit protection tubes 100 to enable sliding movement by being coupled to the rail grooves 610 in a rail manner.

6 is a view showing another example in which the unit protection tubes according to the present invention are arranged inside the outer tube.

Referring to FIG. 6, seating grooves 120 are formed on the outer periphery of each of the plurality of unit protection tubes 100.

The rail protrusions 110 are disposed in the mounting grooves 120.

Elastic springs 130 are interposed between the rail protrusions 110 and the seating grooves. Accordingly, the plurality of unit protection tubes 100 are elastically movable.

7 is a view showing an example in which a configuration in which support members protrude is added to an outer tube according to the present invention.

Referring to FIG. 7, cylinders 620 having a shaft 621 that expand and contract are fixed at a plurality of positions on the outer periphery of the outer tube 600.

Support members 630 with sharp ends are installed at the ends of the shaft 621 of each of the cylinders 620.

When the measured impact force exceeds the set reference impact force, the controller 350 protrudes the shaft 621 using the cylinders 620 so that the support members 630 are stuck in the ground. do.

8 is a diagram showing an example in which position sensors are installed in unit protection tubes and underground power cables according to the present invention.

Referring to FIG. 8, first position sensors 710 are installed in the cover of the underground power cable 10 to measure the first position values by being buried at intervals.

The plurality of unit protection tube 100 and the outer tube 600 are provided with second position sensors 720 that measure second position values at intervals.

The controller 350 is arranged in the vicinity of the abnormal position value when there is an abnormal position value deviating from a set range or more from the set reference position values among the measured first and second position values. By using the variable part, the position of the moving roller 530 is further changed so that the underground power cable 10 is loosened by a predetermined length.

According to the above configuration and operation, the present invention connects both ends of the protection tubes in which the power cables are accommodated through flexible tubes having a certain thickness, so that the positions of the protection tubes are changed according to the horizontal, vertical, and rotational directions due to earthquakes. In addition to preventing damage, there is an effect of preventing a disconnection accident in advance by allowing the cable to be rotated to always maintain its original position so that the cable is not twisted inside the protective tube.

In addition, the present invention ensures that the support members automatically protrude from the periphery of the protective tube in case of an earthquake with an impact force greater than a certain level to secure a certain amount of support, and also check the linear position information of the protective pipes and underground power cables in real time. Therefore, it is effective to accurately identify the maintenance location by checking the position of the protective tube and the power cable changed during and after the earthquake.

100: unit protection tube
200: tube
300: posture variable part
400: sensor unit
500: length variable part
600: outer tube

Claims (4)

A plurality of unit protection tubes in which underground power cables are disposed;
Flexible tubes connecting between the plurality of unit protection tubes;
A posture control unit fixed to an inner wall of the plurality of unit protection tubes and rotating the underground power cable to a set reference position;
A sensor unit installed in the plurality of unit protection tubes and measuring an impact force from the outside; And,
Including; is installed in the posture control unit, a length variable for controlling the tension to loosen a predetermined length of the underground power cable when the measured impact force exceeds a set reference impact force;
The posture control unit,
A body fixed to the inner periphery of each of the plurality of unit protection tubes and having a through hole through which the underground power cable passes,
A rotating ring installed inside the body and contacting the outer periphery of the underground power cable passing through the through hole;
A rotating gear connected in a gear manner with a gear tooth formed on the outer circumference of the rotating ring,
A motor connected in an axial manner to the center of the rotating gear
And a controller for rotating the rotation gear by driving the motor,
A protruding line is formed on the outer periphery of the underground power cable,
In the inner circumference of the rotating ring, a protruding groove into which the protruding line is fitted is formed,
In the controller,
Underground power cable structure for distribution with seismic performance, characterized in that the reference position is set. delete The method of claim 1,
The length variable part,
A variable part body in which an inner space is formed and a moving hole through which the underground power cable is moved is formed at both ends,
A pair of guide rollers disposed in the inner space of the variable part body and disposed in the vicinity of each of the moving holes to guide the movement of the underground power cable,
A moving roller located below the center of the pair of guide rollers to guide the movement of the underground power cable,
It is fixed to the upper wall of the inner space of the variable part body, and has an elevating cylinder having an elevating shaft to elevate,
The end of the lifting shaft is connected to the rotation center of the moving roller,
The controller is a power distribution underground power cable structure having seismic performance, characterized in that controlling the lifting of the lifting shaft through the lifting cylinder. ◈ Claim 4 was abandoned upon payment of the set registration fee. The method of claim 3,
The plurality of unit protection tubes,
It is placed inside the outer tube,
Rail grooves formed along the length direction are formed in the inner circumference of the outer tube,
An underground power cable structure for distribution with seismic performance, characterized in that rail protrusions are formed on the outer circumferences of the plurality of unit protection tubes to enable sliding movement by being coupled to the rail grooves in a rail manner.

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