KR101484722B1 - Fastening cleat assembly sturucture for underground power cable - Google Patents

Abstract

The present invention relates to a cleat structure for securing an underground power cable, and more particularly, to a cleat structure for securing an underground power cable for absorbing underground power cable thermal copper and preventing a power cable from being damaged by thermal conduction.
The fixed cleat assembly for an underground power cable according to the present invention comprises an upper cleat having an inner diameter and a hemispherical shape and a lower cleat, wherein when the underground power cable is installed, the power cable is fixed A fixed cleat having a fastening through which fixing bolts can be inserted at both ends of the upper and lower cleats, respectively, and fastened to a lower fixed hanger; Wherein at least one rectangular hole is formed in a surface of the fixed cleat which abuts on the lower cleat, and the fixing bolt is passed through the rectangular hole to be fastened to the fixed cleat And a fixed hanger.

Description

[0001] FASTENING CLEAT ASSEMBLY STURUCTURE FOR UNDERGROUND POWER CABLE [0002]

The present invention relates to a cleat structure for securing an underground power cable, and more particularly, to a cleat structure for securing an underground power cable for absorbing underground power cable thermal copper and preventing a power cable from being damaged by thermal conduction.

Generally, power cables for transmission and distribution are buried underground, installed in underground power sheds, or installed on the ground using steel towers.

The underground power cable installed in the power conduit connects the power cable to the intermediate location every fixed length, and since the power cable is formed on the terminal side, the power cable is installed in the horizontal portion, the inclined portion and the granular portion.

The installation of the power cable is arranged in three phases, and the power cable arranged in three phases is laid out in multiple layers using a tray.

There are various types of installation such as three-phase power cable installation, regular triangular arrangement, horizontal arrangement, vertical arrangement and offset section.

Fig. 5 shows a conventional arrangement of horizontally arranged three-phase underground power cables.

The three-phase underground power cable is installed in a regular triangular arrangement and horizontally offset in a certain section to be installed in a horizontal arrangement as shown.

In the installation, the vertical tray 51 and the horizontal tray 52 are installed at predetermined intervals, and a fixed cleat 53 is provided thereon to fix the power cable 54. In some areas, the support 55 is installed, The cable 54 is arranged in a form in which it is placed on top.

The fixed cleat 53 fixes the power cable 54 to the horizontal tray 52 by the bolt 56 and the support 55 is of a type having a predetermined radius and the power cable 54 And a straight cut portion is formed at the lower end so as to be able to be inserted into the horizontal tray 52.

FIG. 6 shows a configuration of an offset section of a conventional three-phase underground power cable.

The three-phase ground power cable 54 arranged in the right triangle is offset in a certain section as shown in FIG. In the positive triangular arrangement, the three-phase power cable 54 is installed in the right triangular shape by the triangular cleat 65, and the power cable 54 of three phases in the offset section is offset while being separated from each other by a predetermined angle.

At this time, the offset power cable 54 is positioned by the 'A' panel 62, the side tray 61, and the support 63 in the horizontal section.

The 'A' panel 62 is fixed to the side tray 61 and is horizontal. The 'A' panel 62 is fixed on the 'A' panel 62, And three power cables 54 offset on the support 63 are placed and positioned, respectively.

Underground power cables installed in this form are installed due to electrical review and structural review according to the power system.

Underground power cables are essential and constantly increasing in the transmission field in terms of stable supply of power, improved reliability of supply, and beautification of power supply in densely populated areas in urban areas.

However, it is also true that there are various problems due to the limited use of the underground space.

There are electrical accidents such as 1-wire ground fault, 2-wire ground fault, line-to-line fault, and 3-phase fault in underground fault condition.

Energization due to fault currents occurring in a fixed situation causes severe fluctuation of the power cable and causes the power cable to be energized by the fault current at the same time striking the adjacent power cable or hitting the installed tray, Often resulting in secondary accidents.

Particularly, as shown in Figs. 5 and 6, in a place where the power cables 54 are laid on the pedestals 55 and 63, a phenomenon that the power cable 54 is sprung upward in the direction of the energetic movement occurs.

5 does not cause the above-described overheating phenomenon, the fixing cleats 53 are fixed to the fixing holes 57 formed in the horizontal tray 52, And the fixing bolt 56 is fitted to fix the power cable 54. This fixing structure can not absorb the heat generated at this portion when the fault current is generated, In this case, there is a structural contradiction in which the enumeration occurs severely.

Likewise, in the case of FIG. 6 as well, the triangular cleat 65 is completely fixed so that there is no fluidity, and when the fault current is generated, energetic copper absorption is not performed at this portion, and severe heat conduction occurs in the region of the beam 63.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a method of fixing a power cable stably according to a method of installing a power cable, The present invention provides a fixed cleat assembly for an underground power cable capable of preventing a secondary accident caused by an electric power cable.

According to an aspect of the present invention, there is provided a fixed cleat assembly for an underground power cable, the cleat assembly including an upper cleat having an inner diameter and a hemispherical shape and a lower cleat, A fixed cleat having a fastening hole through which the power cable is fixed and both ends of each of the upper and lower cleats can be inserted with a fastening bolt and fastened to a lower fixed hanger; Wherein at least one rectangular hole is formed in a surface of the fixed cleat which abuts on the lower cleat, and the fixing bolt is passed through the rectangular hole to be fastened to the fixed cleat And a fixed hanger.

Here, the fixed hangers may be formed in the shape of an 'A' panel to have a horizontal plane and a vertical plane, and the rectangular holes may be formed in the horizontal plane.

It is preferable that the fixed cleats and the hanger are installed at predetermined positions in the horizontally aligned installation area of the power cable or at positions in the offset section so as to absorb heat generated by the fault current.

Here, the width of the rectangular hole may be smaller than the outer diameter of the head of the fixing bolt and the outer diameter of the fixing nut, and the rectangular cable hole may be formed by the power cable and the fixed cleat at the same time, And the fixing bolt may be a guide bar moving along the guide rail.

According to the structure of the present invention described above, the power cable can be stably fixed according to the installation method of the power cable, and at the same time, when the power generation due to the fault current occurs, It is possible to provide a fixed cleat assembly for an underground power cable.

1 is an exploded perspective view of a fixed cleat assembly for an underground power cable according to the present invention.
FIG. 2 is a perspective view illustrating a horizontal arrangement of a fixed cleat assembly for an underground power cable according to the present invention.
FIG. 3 is a view illustrating an embodiment of an offset section using a fixed cleat assembly for an underground power cable according to the present invention.
FIG. 4 shows the thermal copper absorption phenomenon at a fixed position by a fixed cleat assembly when a thermal current is generated by a fault current. FIG.
FIG. 5 shows a horizontal arrangement of a conventional underground power cable.
FIG. 6 is a view illustrating an exemplary embodiment of an offset section of a conventional underground power cable.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a cleat structure for fixing an underground power cable according to the present invention, a construction mode using the same, and effects thereof will be described with reference to the accompanying drawings.

1 is an exploded perspective view of a fixed cleat assembly for an underground power cable according to the present invention.

1, a fixed cleat assembly 10 for an underground power cable according to the present invention includes a fixed cleat 11, a fixing bolt 14, a fixing nut 15, a washer 16, and a fixed hanger 17 ).

The fixed cleat 11 is composed of an upper cleat 12 and a lower cleat 13 and is formed in a semicircular shape so that a power cable is inserted into the fixed cleat 11 and the power cable is connected by fastening the upper cleat 12 and the lower cleat 13 Respectively.

The upper and lower cleats 12 and 13 are fastened by fastening bolts 14 inserted into fastening holes 12a and 13a formed on both sides of the upper and lower cleats 12 and 13, .

At this time, the fixing bolts 14 and the fixing nuts 15 fix the fixing bolts 14 in a state where the fixing bolts 14 are inserted into the rectangular holes 19 of the fixing hanger 17 when fastened.

The fixed hanger 17 has a panel structure of the 'a' type and includes a horizontal plane 17a and a vertical plane 17b and a rectangular hole 17d in a horizontal plane 17a. On the side surface of the fixed hanger (17), a fastening member (17c) fixed to the side tray is formed.

The rectangular holes 17d may be formed as a pair in accordance with the number of fasteners 12a, 13a formed on both sides of the fixed cleat 11, or may be formed in the shape of a single rectangular hole.

The width of the rectangular hole 17d is smaller than the outer diameter of the fixing bolt 14, the outer diameter of the fixing nut 15 and the outer diameter of the washer 16, to which the fixing bolt 14 can be inserted.

The length of the rectangular hole 17d is such that the power cable and the fixed cleat 11 can flow simultaneously along the rectangular hole 17d in the state where the fixed hanger 17 is fixed, The bolt 14 serves as a guide bar for left and right flow and the rectangular hole 17d serves as a guide rail.

FIG. 2 is a perspective view illustrating a horizontal arrangement of a fixed-power cable assembly for an underground power cable according to the present invention, and FIG. 3 is a view illustrating an installation of an offset section using a fixed- .

As shown in FIG. 2, the three-phase underground power cable 21 indicates a region arranged in a horizontal arrangement in the form of a right triangle arrangement. The power cables 21 are arranged side by side at regular intervals, (21) is fixed by the fixed cleat (11) at every predetermined distance.

The side tray 22 is mounted on the wall surface in the power conduit and the fixed hanger 17 is fastened by the bolt to the side tray 22 via the fastening member 17c.

In this state, the lower cleat 13, the electric power cable 21 and the upper cleat 12 are positioned on the fixed hanger 17, and the fixing bolt 14 is fixed to the fastening hole 12a of the upper cleat 12, Is fastened to the fixing nut 15 through the fastening hole 13a of the fastening hanger 17 and the rectangular hole 17d of the fastening hanger 17. [

3, the three-phase ground power cable 31 is fixed at a predetermined position after being fixed by the triangular cleat 33 in the form of a right triangular arrangement, and in the offset period, each of the power cables 31 And the offset power cable 31 is fixed by the fixed cleat 11. As shown in Fig.

The side tray 32 is attached to the wall surface in the power conduit and the fixing hanger 17 is fastened by the bolt to the side tray 32 via the fastening member 17c.

In this state, the lower cleat 13, the electric power cable 31 and the upper cleat 12 are positioned on the fixed hanger 17. The fixing bolt 14 is fixed to the fastening hole 12a of the upper cleat 12, Is fastened to the fixing nut 15 through the fastening hole 13a of the fastening hanger 17 and the rectangular hole 17d of the fastening hanger 17. [

In the power cable horizontal arrangement section of FIG. 2 and the power cable offset arrangement section of FIG. 3, the power cables 21 and 31 are fixed by the fixed cleat assemblies of the fixed cleat 11 and the fixed hanger 17, respectively.

The power cables 21 and 31 fixed by the fixed cleat assembly are fastened and fixed by the upper and lower cleats 12 and 13 and the fixed hanger 17 while the rectangular holes 17d of the fixed hanger 17, The power cables 21 and 31 are in a state of securing a certain degree of fluidity in the direction in which the rectangular holes 17d are formed by the electric wires 21 and 31. [

When an electrical accident such as a 1-wire ground fault, a 2-wire ground fault, a line-to-line fault, or a 3-phase fault occurs under a fault condition due to an underground line, enumeration due to a fault current occurring in such a fault situation, The power cables 21 and 31 are caused to flow to the left and right so that the heat generated by the fault current can be completely absorbed at the fixed portion.

This will be described in more detail with reference to FIG.

FIG. 4 shows the thermal copper absorption phenomenon at a fixed position by a fixed cleat assembly when a thermal current is generated by a fault current. FIG.

Referring to FIG. 4, first, a portion indicated by a solid line indicates a position where an initial power cable is installed.

When a fault current is generated in such a state, a tripping current is generated due to a fault current, and a tripping due to a fault current causes a mechanical shock such as a fading phenomenon of the power cable 41a and a right / left tilting phenomenon. The power cable 41a is moved by the rectangular hole 17d formed in the fixed hanger 17 like the dashed line (the power cables 41b and 41c at the left and right dotted lines) along the rectangular hole 17d do.

At this time, while moving left and right along the rectangular hole 17d, most of the heat generated by the fault current is absorbed at that position.

Therefore, it is possible to prevent a secondary accident from occurring due to a fault current.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, As will be understood by those skilled in the art. Therefore, it should be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

10: Fixed cleat assembly 11: Fixed cleat
12: upper cleat 12a, 13a: fastener
13: Lower cleat 14: Fixing bolt
15: Fixing nut 16: Washer
17: Fixing hanger 17a: Horizontal plane
17b: vertical surface 17c: fastening member
17d: a rectangular hole 22, 32: a side tray
21, 31, 41a, 41b, 41c:
33: Triangular cleats

Claims (4)

Wherein the power cable is fixed by engagement of the upper cleat and the lower cleat when the underground power cable is installed, and the power cable is fixed to both ends of the upper and lower cleats, A fixed cleat having a fastener through which a bolt can be inserted and fastened to a lower fixed hanger;
Wherein at least one rectangular hole is formed in a surface of the fixed cleat which abuts on the lower cleat, and the fixing bolt is passed through the rectangular hole to fasten the fixed cleat A fixed hanger,
Wherein the rectangular hole is a guide rail so that the power cable and the fixed cleat move simultaneously to the left and right, the fixing bolt becomes a guide bar moving along the guide rail,
Wherein the rectangular hole is formed in a direction perpendicular to a longitudinal direction of the power cable, and the fixing bolt is formed in a direction perpendicular to the rectangular hole. The method according to claim 1,
Wherein the fixed hanger is formed in the shape of an A-shaped panel and has a horizontal plane and a vertical plane, and the rectangular hole is formed in the horizontal plane. The method according to claim 1,
Wherein the fixed cleats and the hanger are installed at predetermined positions in a horizontally arrayed area of the power cable or at positions in the offset section to absorb heat generated by fault currents.





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