KR102223212B1 - Structure of protective pipe for underground cable - Google Patents

Abstract

The present invention provides a structure of a protective pipe of a power cable in an underground pipeline in complex. The structure comprises: an outer protective tube with a hollow shape buried in the ground; an inner protective tube disposed in the hollow of the outer protective tube; elastic members installed between the outer protective tube and the inner protective tube to elastically support the outer protective tube and the inner protective tube; and, a cable protection tube slidably disposed in the hollow of the inner protection tube and supporting the power cables.

Description

Structure of protective pipe for underground cable in the complex

The present invention relates to a structure of a power cable protection pipe for an underground pipe in a complex, and more particularly, by securing support in the underground, forming a double protective pipe, and elastically supporting each other through elastic members between the double-formed protective pipes. It prevents the transmission of external shocks to the inner protective pipe, and the cable protective pipe where the power cable is located can be slipped from the inner protective pipe, and a corrugated pipe is installed between the cable protective pipes to allow variable flow to a certain length when the condition of the ground changes. It relates to an underground power cable protection pipe structure in a complex that enables it to prevent damage to the cable protection pipe itself.

In general, the underground construction of overhead distribution lines in Korea began in 1973 by relocating the electric poles along the arterial road to the back alleys in terms of maintenance of the complex distribution lines from Hyoja-dong to the Gwanghwamun section, and supplying nearby customers from a pole transformer using a low-voltage cable. , The trend is continuously expanding.

The underground line construction method can be largely divided into a direct sale type, a pipeline type, an old electric power type, and a bridge addition type. Among them, the old power type is also called the culvert type or the copper chain type, and in such an old power type, it is composed of a protective tube and a shelf that protects the distribution lines to arrange them.

Conventional distribution line protection pipes consist of a tubular concrete structure buried in the ground and a shelf embedded in the concrete structure.

The shelf is fixedly disposed perpendicular to the floor by in close contact with the wall on the left and right inner wall surfaces of the concrete structure, and distribution lines are installed on the shelf.

On the other hand, a passage is provided between the shelves so that workers can pass. In such an old-fashioned construction, the shelves are simply fixed in layers from the inside of the concrete structure to both side walls. There is a problem that moisture moves along the installed shelf to wet the distribution line, and if this situation is continuously repeated, oxidation is promoted and the life of the distribution line is shortened.

In addition, when the distribution line is wet, there is a problem in that it does not dry out easily due to its nature installed in a closed space in the basement, making it inconvenient to work.

As the oxidized distribution line increases the possibility of exposing the conductors through which current flows through the oxidized portion, there is also a problem in that the incidence of electrical accidents such as power outages or electric shocks increases.

Conventionally, since the shelf is firmly fixed to both side walls of the concrete structure, when an earthquake or vibration occurs, the shelf is not only separated from the wall, it is bent or cut, and other damage of the shelf is caused.

In order to solve this problem, a protective tube that does not use a shelf has been proposed.

However, since the conventional protective pipe has an integral structure, when earth pressure is applied to a part, external force is transmitted to all parts, so that the protective pipe itself is extremely deformed, and thus, there is a problem in that the distribution line cannot be safely protected.

In addition, even if only a part of the protective pipe is damaged, there is also a problem that is not economical because the entire protective pipe must be replaced.

Korean Patent Registration No. 10-0853674 (2008.08.18)

The present invention has been devised to solve the above-described problems, and the object of the present invention is as follows.

First, by forming a double protective tube and supporting each other through elastic members between the double-formed protective tubes, external shocks are prevented from being transmitted to the inner protective tube, and the cable protective tube where the power cable is located is slipped from the inner protective tube. It is possible, and a corrugated pipe is installed between the cable protection pipes to enable variable flow in a certain length when the condition of the ground changes, thereby preventing damage to the cable protection pipe itself.

Second, the cable protection tube is composed of a plurality of unit protection tubes, and they are bonded to each other with elastic wires to prevent damage to the cable protection tube due to a certain amount of flow that varies in the longitudinal direction, so that the power cable can be safely protected.

Third, the outer and inner protective pipes are arranged in a grid shape to form a structure that can be combined and separated, so that when a part of the protective pipe is damaged, only the grid protective pipe at the corresponding position can be replaced.

In order to achieve the above objects, the present invention provides a power cable protection pipe structure for an underground pipe in a complex.

The underground power cable protection tube structure in the complex includes a hollow outer protection tube buried in the ground; An inner protective tube disposed in the hollow of the outer protective tube; Elastic members installed between the outer protective pipe and the inner protective pipe to elastically support the outer protective pipe and the inner protective pipe; And a cable protection tube that is slidably disposed in the hollow of the inner protection tube and supports power cables.

Here, on the inner periphery of the inner protective tube,

A moving rail is formed,

On the outer periphery of the cable protection tube,

A rail groove is formed that is coupled with the movable rail in a rail manner,

The moving rail,

It is formed on the moving rail tube, the moving rail tube is rotatably coupled to the inner periphery of the inner protective tube.

And the cable protection tube,

Multiple unit protective tubes,

Including corrugated pipes connecting the plurality of unit protection pipes to each other,

Grid-shaped holes are formed in the plurality of unit protection tubes,

A plurality of power cables are provided and disposed through each of the holes.

In addition, the cable protection tube,

Multiple unit protective tubes,

Including elastic wires connecting the plurality of unit protection pipes to each other,

Grid-shaped holes are formed in the plurality of unit protection tubes,

A plurality of power cables are provided and disposed through each of the holes.

Moreover, each of the lattice-shaped holes,

Forming a rectangular partition wall to form the grid shape,

In the partition wall,

When the power cable is positioned in each of the holes, a buffer member is provided to surround the power cable by being swollen by air supplied from the outside.

In addition, on the partition wall,

The buffer member is installed,

In the interior of the partition wall, an air line for supplying air to the buffer member is formed,

The air line is connected to an air supply driven by a control unit,

In the partition wall,

Proximity sensors for detecting the insertion of the power cable are installed in the holes,

The control unit,

When the proximity sensor detects that the power cable is inserted, air is supplied to the buffer member using the air supply to inflate the power cable to be wrapped.

In addition, at the lower end of the outer protective tube,

A plate-shaped support is arranged,

Protrusions having an uneven shape are formed on the outer surface of the support part to form a contact area of a certain or more with the underground,

At the top of the support on the plate,

Elevating cylinders having an elevating shaft to be elevated are installed,

The lifting cylinders are disposed inside the auxiliary corrugated pipes, and the auxiliary corrugated pipes are connected to an upper end of the support part and a lower part of the outer protective pipe.

In addition, each of the outer protective pipe and the inner protective pipe,

It is composed of coupling unit tubes that form a lattice-like bond that can be detached from each other,

Each of the coupling unit pipes is installed with impact sensors that detect external impact,

The impact sensors transmit the detected impact to the control unit,

The control unit,

It is determined whether the detected impact is greater than or equal to the pre-stored reference impact,

Selecting an impact sensor in which the impact is sensed, which makes up more than the reference impact,

The selected location information of the impact sensor is transmitted to an external server using a wireless communication method.

As described above, the present invention forms a double protective tube and elastically supports each other through an elastic member between the double-formed protective tubes to prevent the transmission of external shocks to the inner protective tube, and the cable protective tube in which the power cable is located is provided with the inner protective tube. It is possible to slip in, and a corrugated pipe is installed between the cable protection pipes to allow variable flow in a certain length when the condition of the ground changes, so that the cable protection pipe itself can be prevented from being damaged.

The cable protection tube is composed of a plurality of unit protection tubes, and they are bound with elastic wires to prevent damage to the cable protection tube by a constant amount of flow that varies in the longitudinal direction, so that the power cable can be safely protected.

The outer and inner protective pipes are arranged in a lattice shape to form a structure that can be combined and separated, so that when a part of the protective pipe is damaged, only the lattice protective pipe at the corresponding position can be replaced.

1 is a view showing a power cable protection pipe structure in an underground pipeline in a complex according to the present invention.
2 is a view showing a combined state of a moving rail and a moving groove.
3 is a view showing an inner protective tube in which a moving rail tube according to the present invention is installed.
4 is a view showing a cable protection tube according to the present invention.
5 is a view showing another example of a cable protection tube according to the present invention.
6 is a view showing an example in which a buffer member is provided in a hole according to the present invention.
7 is a view showing an example in which the lifting cylinders are installed at the lower end of the outer protective tube according to the present invention.
8 is a view showing a configuration in which each of the outer protective pipe and the inner protective pipe can be separated or combined according to the present invention.
9 shows another example of the outer and inner protective tubes according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those of ordinary skill in the art may easily implement the present invention.

The present invention may be implemented in various different forms and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description have been omitted, and the same reference numerals are attached to the same or similar components throughout the specification.

Hereinafter, it means that an arbitrary configuration is provided or disposed on the "top (or bottom)" of the base material or the "top (or bottom)" of the base material is provided or disposed in contact with the top (or bottom) of the base material. Means that.

In addition, it is not limited to not including other configurations between the base material and any configurations provided or disposed on (or under) the base material.

The following describes the present invention with reference to the accompanying drawings.

1 is a view showing a power cable protection pipe structure in an underground pipeline in a complex according to the present invention. 2 is a view showing a combined state of a moving rail and a moving groove.

1 and 2, the underground power cable protection pipe structure in the complex of the present invention includes a hollow outer protective pipe 100 buried in the underground 1 and an inner protective pipe disposed in the hollow of the outer protective pipe 100 (200) and elastic members 300 disposed between the outer protective pipe 100 and the inner protective pipe 200 to elastically support the outer protective pipe 100 and the inner protective pipe 200, It is disposed to be slidably movable in the hollow of the inner protection tube 200, and is configured to include a cable protection tube 400 for supporting the power cables 10.

Here, a moving rail 210 is formed on the inner periphery of the inner protective tube 200.

A rail groove 401 coupled to the moving rail 210 in a rail manner is formed on the outer periphery of the cable protection tube 400.

3 is a view showing an inner protective tube in which a moving rail tube according to the present invention is installed.

Referring to FIG. 3, the movable rail 201 is formed on the movable rail pipe 220, and the movable rail pipe 220 is rotatably coupled to the inner periphery of the inner protective pipe 200. Through this, the cable protection tube 400 is prevented from being damaged by twisting in the rotational direction.

4 is a view showing a cable protection tube according to the present invention.

Referring to FIG. 4, the cable protection tube 400 includes a plurality of unit protection tubes 410 and corrugated tubes 420 connecting the plurality of unit protection tubes 410 to each other.

Holes 411 on a grid are formed in the plurality of unit protection tubes 410.

The power cables 10 are provided in plural and disposed through each of the holes 411.

5 is a view showing another example of a cable protection tube according to the present invention.

Referring to FIG. 5, the cable protection tube 400 includes a plurality of unit protection tubes 410 and elastic wires 430 connecting the plurality of unit protection tubes 410 to each other.

Holes 411 on a grid are formed in the plurality of unit protection tubes 410.

The power cables 10 are provided in plural and disposed through each of the holes 411.

6 is a view showing an example in which a buffer member is provided in a hole according to the present invention.

Further, referring to FIG. 6, each of the lattice-shaped holes 411 is formed with a rectangular partition wall 410a to form the lattice shape.

In the partition wall 410a, when the power cable 10 is positioned in each of the holes 411, a buffer member 500 is provided to surround the power cable 10 by being inflated by air supplied from the outside.

In addition, the buffer member 500 is installed on the partition wall 410a.

An air line 410b for supplying air to the buffer member 500 is formed inside the partition wall 410a.

The air line 410b is connected to an air supply 510 driven by the control unit 600.

A proximity sensor 610 is installed in the partition wall 410a to detect the insertion of the power cable 10 into the holes 411.

When the proximity sensor 610 detects that the power cable 10 is inserted, the controller 600 supplies air to the buffer member 500 using the air supply 510 to inflate it. Wrap the power cable (1).

7 is a view showing an example in which the lifting cylinders are installed at the lower end of the outer protective tube according to the present invention.

In addition, referring to FIG. 7, a plate-shaped support part 700 is disposed at the lower end of the outer protective tube 100.

Protrusions 710 having a concave-convex shape are formed on the outer surface of the support part 700 to form a contact area of a certain amount or more with the ground.

At the upper end of the support part 700 on the plate, lifting cylinders 800 having a lifting shaft 810 are installed.

The lifting cylinders 800 are disposed inside the auxiliary corrugated pipes 820, and the auxiliary corrugated pipes 820 are connected to an upper end of the support part 700 and a lower part of the outer protective pipe 100.

8 is a view showing a configuration in which each of the outer protective pipe and the inner protective pipe can be separated or combined according to the present invention.

In addition, referring to FIG. 8, each of the outer protective pipe 100 and the inner protective pipe 200 is composed of coupling unit pipes 20 that form a lattice-like coupling detachable to each other.]

The coupling unit pipes 20 are configured in a coupling method (A) in which both ends and both ends are fitted with each other.

Each of the coupling unit pipes 20 is provided with shock sensors 30 for sensing an external shock.

The impact sensors 30 transmit the detected impact to the control unit 600.

The control unit 600 determines whether the detected shock is greater than or equal to a pre-stored reference shock, selects the shock sensor 30 from which the shock, which is greater than or equal to the reference shock, is sensed, and the selected shock sensor 30 ) Location information is transmitted to the external server 50 using a wireless communication method.

Here, as described above, the outer protective pipe 100 and the inner protective pipe 200, which form a hollow in a state in which the coupling unit pipes 20 are coupled to each other, may be manufactured in advance in a module type in a manufacturing plant in a state of being fitted to each other.

In this way, the outer protective pipe 100 and the inner protective pipe 200 manufactured in a module type can be easily installed when installed in the field.

In addition, a seal (not shown) may be interposed between the coupling unit pipes 20 to achieve watertightness.

9 shows another example of the outer and inner protective tubes according to the present invention.

Referring to FIG. 9, each of the outer and inner protective pipes 100 and 200 includes a support pipe 21 having a semicircular cross-section and covers 22.

Openings 21a are formed in the support pipe 21 at intervals. The openings 21a form a structure in which each of the covers 22 is inserted and covered. Here, a seal (not shown) is interposed between the outer circumference of the cover 22 and the inner circumference of the openings 21a to achieve watertightness. Can be combined. This makes it possible to achieve an order.

Therefore, by opening the cover 22 of the part where the problem has occurred, the power cable in the part can be repaired.

With such a configuration, the present invention provides a double protective tube and elastically supports each other through elastic members between the double-formed protective tubes to prevent external shock from being transmitted to the inner protective tube, and the cable protection tube in which the power cable is located. It is possible to slip in the inner protective pipe, and by installing a corrugated pipe between the cable protective pipes, it enables variable flow to a certain length when the condition of the ground changes to prevent damage to the cable protective pipe itself.

The cable protection tube is composed of a plurality of unit protection tubes, and they are bound with elastic wires to prevent damage to the cable protection tube by a constant amount of flow that varies in the longitudinal direction, so that the power cable can be safely protected.

The outer and inner protective pipes are arranged in a lattice shape to form a structure that can be combined and separated, so that when a part of the protective pipe is damaged, only the lattice protective pipe at the corresponding position can be replaced.

The present invention is not limited to the specific preferred embodiments described above, and any person having ordinary knowledge in the technical field to which the design belongs without departing from the gist of the present invention claimed in the claims can implement various modifications. Of course, such changes are intended to be within the scope of the description of the claims.

100: outer protective tube
200: inner protective tube
300: elastic member
400: cable protection tube

Claims (4)

A hollow outer protective tube buried in the ground;
An inner protective tube disposed in the hollow of the outer protective tube;
Elastic members installed between the outer protective pipe and the inner protective pipe to elastically support the outer protective pipe and the inner protective pipe; And,
Including; a cable protection tube that is slidably disposed in the hollow of the inner protection tube and supports power cables
On the inner periphery of the inner protective tube,
A moving rail is formed,
On the outer periphery of the cable protection tube,
A rail groove is formed that is coupled with the movable rail in a rail manner,
The moving rail,
It is formed on the movable rail tube, the movable rail tube is rotatably coupled to the inner periphery of the inner protective tube,
The cable protection tube,
Multiple unit protective tubes,
Including corrugated pipes connecting the plurality of unit protection pipes to each other,
The plurality of unit protection tubes are formed with holes on a grid,
The power cable is provided in plural and disposed through each of the holes,
The cable protection tube,
Multiple unit protective tubes,
Including elastic wires connecting the plurality of unit protection pipes to each other,
The plurality of unit protection tubes are formed with holes on a grid,
The power cable is provided in plural and disposed through each of the holes,

Each of the grid-shaped holes,
Forming a rectangular partition wall to form the grid shape,
In the partition wall,
When the power cable is positioned in each of the holes, a buffer member is provided to surround the power cable by being swollen by air supplied from the outside,
In the partition wall,
The buffer member is installed,
In the interior of the partition wall, an air line for supplying air to the buffer member is formed,
The air line is connected to an air supply driven by a control unit,
In the partition wall,
Proximity sensors that detect the insertion of the power cable are installed in the holes,
The control unit,
When the proximity sensor detects that the power cable is inserted, air is supplied to the buffer member using the air supply to inflate the power cable,
At the lower end of the outer protective tube,
A plate-shaped support is arranged,
Protrusions having an uneven shape are formed on the outer surface of the support part to form a contact area of a certain or more with the underground,
At the top of the support on the plate,
Elevating cylinders having an elevating shaft to be elevated are installed,
The lifting cylinders are disposed inside of the auxiliary corrugated pipes, and the auxiliary corrugated pipes are connected to an upper end of the support part and a lower part of the outer protective pipe,
Underground pipeline power cable protection pipe structure in the complex.
The method of claim 1,
Each of the outer protective pipe and the inner protective pipe,
It is composed of coupling unit tubes that form a lattice-like bond that can be detached from each other,
Each of the coupling unit pipes is installed with impact sensors that detect external impact,
The impact sensors transmit the detected impact to the control unit,
The control unit,
It is determined whether the detected impact is greater than or equal to the pre-stored reference impact,
Selecting an impact sensor in which the impact is sensed, which makes up more than the reference impact,
Transmitting the selected location information of the impact sensor to an external server using a wireless communication method,
Underground pipeline power cable protection pipe structure in the complex. delete delete

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