KR100940521B1 - Fixer of jumper wire connecting the transmission line - Google Patents

Abstract

PURPOSE: A jumper wire fixing stand for a transmission line is provided to prevent interference or a short circuit between transmission lines by constantly maintaining an space between the transmission lines regardless of an external force. CONSTITUTION: A base frame is horizontally fixed on a pylon or electric pole and includes a tube-shaped case(110). A damper support is arranged on the front side and the rear side of the base frame and has a hollow tube shape. The damper support rotatably fixes a plurality of suspension insulators(310,310',310''). The jumper insulator is vertically arranged on the upper side of the base frame. A rotation structure rotatably fixes the jumper insulator.

Description

Fixer of jumper wire connecting the transmission line}

The present invention relates to a jumper wire fixture for transmission line connection.

Transmission electricity flowing along the transmission line is transformed to extra high pressure for efficient long-distance transmission of generated electricity. In addition, in consideration of power transmission efficiency and distribution distribution, power is distributed through a plurality of power transmission lines.

However, in order to maintain a stable transmission state, interference between power lines arranged in parallel with a plurality of dogs should be minimized, and the proximity within the allowable distance between power lines should be prevented even when rotating by external force. In addition, damage to the insulator should also be prevented by the transmission line moving in the lateral direction by minimizing the lateral force received by the insulator during the lateral movement of the transmission line by the wind.

However, in the conventional transmission line structure installed in the steel tower, no technique for maintaining the spacing of the multiple transmission lines arranged side by side has not been applied, and the structure for preventing insulator damage is not applied at all, so that the interference of the transmission line due to strong wind power and Short circuits and breaks in insulators holding power transmission lines frequently occurred.

Therefore, the present invention has been devised to solve the above problems, and always maintains a plurality of transmission lines arranged side by side at a constant interval, to prevent problems caused by short circuits and interference, and the transmission line due to the transverse force received by the transmission line Technical problem is to provide a jumper wire holder for connecting transmission lines to minimize breakage of insulators connected in line.

The present invention to achieve the above technical problem,

Base frame 100 having a through-hole 111 is formed on the upper surface and having a tubular case 110 having a hollow,

A tubular shape of a rectangular parallelepiped having a hollow housing, each of which is fixed to the front and rear surfaces of the base frame 100 and has a sloped base table 211 that forms an inclined inner wall at an inner corner thereof; Equipped with a rotational fixed shaft 221, it is movably embedded in the housing 210, forms a threaded portion formed through the inner surface of the threaded portion 222, while having a thread corresponding to the nut portion 222 A first movable table 220 having a bolt part 223 threadedly coupled through the nut part 222 and a swivel table 224 rotatably fixed to both ends of the bolt part 223; A carbide body having a rotatable fixed shaft 251, which is internally movably in the corner of the housing 210, and forms one surface facing in parallel with the slope-shaped base 211, and is pulled and fixed from the one surface ( 252 and a second movable table 250 having a mover 253 fixed to the distal end of the carbohydrate 252 and movably engaged with the inner wall of the slope-shaped foundation 211; Rotatingly fixed to the housing 210 via the rotating shaft 231, one end is connected to the suspension insulator (310, 310 ', 310 ") and the other end is rotatable to the rotating fixed shaft (221, 251) A fixing piece 230 connected to the first and second moving parts 220 and 250 via a guide 232 cut in the longitudinal direction so as to be engaged with each other; first and second moving parts 220 and 250 adjacent to both ends thereof; Fixed to each), a damper support 200 having a coil spring 240 that is rotatably fixed to the bolt portion 223 and connected to the first movable table 220 and the rotating table 224, and

A through hole 411 communicating with the through hole 111, and a fixed body 410 embedded in the case 110; A rotating guide body 420 fixed to the fixed body 410 while forming a curved sliding surface 421; The drawer is fixedly drawn out at the lower end of the jumper insulator 320 fixed on the case 110 to penetrate through the through hole 111, the through hole 411, and the sliding surface 421, respectively, and slides in engagement with the sliding surface 421. The center of gravity of the spherical sliding sphere 431, the shaft 432 drawn out below the sliding sphere 431, and the jumper insulator 320 to be fixed so as to be below the sliding sphere 431 A linker 430 having a circular center weight 433; Rotating structure 400 having a circular buffer 440 disposed between the pivoting guide 420 and the center weight 433 while wrapping the shaft 432.

Jumper wire fixture for transmission line connection including a.

The present invention is to maintain a plurality of transmission lines arranged side by side at regular intervals regardless of the presence or absence of external force, and to minimize the breakage of the insulator itself by dispersing the lateral force while rotating the insulator even during the transverse movement of the transmission line It works.

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

1 is a perspective view showing a state of the fixing rod according to the present invention, Figures 2 and 3 is a view showing a cross-sectional view of the fixing rod according to the present invention, will be described with reference to this.

Fixture according to the present invention is the base frame 100 and horizontally fixed and supported on a steel tower or pole, and the front and rear of the base frame 100 respectively disposed opposite to each other at least three suspension insulator (310, 310 ', 310 ") ) A damper support 200 for fixing in a row and a pivot structure 400 (see FIG. 4) rotatably fixing the jumper insulator 320 placed on the upper surface of the base frame 100.

As shown, the suspension insulators 310, 310 ′ and 310 ″ disposed to face each other support the transmission line L, and the jumper insulator 320 installed in the base frame 100 is the suspension insulator 310. And the jumper wires 330 drawn out from the wires 310 'and 310 "are fixed, and the transmission line L disconnected about the base frame 100 is electrically connected to each other.

The base frame 100 is a tubular shape in which the hollow is formed, and forms a skeleton of a pylon or electric pole for firmly fixing the transmission line (L).

The damper support 200 is fixed to the front and rear of the base frame 100, respectively, rotatably fixing a plurality of suspension insulators 310, 310 ', 310 ".

One end of the suspension insulator 310, 310 ′, 310 ″ is fixed in a row, and the fixing piece 230 is inserted into the opening 212 of the housing 210 to mediate the rotation shaft 231. It is rotatably fixed to the housing 210 of the low damper support 200. That is, the fixing piece 230 is rotated about the rotation shaft 231, through which the suspension insulators 310, 310 ', 310 ". ) Is rotatably fixed to the housing 210. For reference, the housing 210 forms a tubular shape having a hollow, and the fixing piece 230 is inserted through the opening 212 formed on the side, and the first and second movable tables 220 and 250 are movable. Accept.

Subsequently, at the distal end of the fixing piece 230, a guide 232 cut in the longitudinal direction of the fixing piece 230 is formed, and the rotating type fixed shaft 221 is rotatably inserted into the guide 232 to be engaged. , 251 is fixed to the first and second mobile units 220 and 250. As a result, the first and second moving tables 220 and 250 are connected to the fixed piece 230 in a straight line as well as to allow rotation.

For reference, the first mobile unit 220 indicates a configuration in which the first mobile unit 220 or the second mobile unit 250 faces in both directions, and the second mobile unit 250 has one side of the first mobile unit ( The other side facing 220 indicates the configuration facing the inner wall of the housing 210.

Subsequently, the first and second moving tables 220 and 250 are mutually supported by the coil spring 240. That is, while both ends of the coil spring 240 are respectively connected to the first and second movable stages 220 and 250 facing each other, the interval between the first and second movable stages 220 and 250 facing each other may be kept constant. To make it possible. Therefore, the coil spring 240 has the elasticity to push the first and second mobile units 220 and 250, as well as the tension to pull each other.

On the other side of the second moving table 250 facing the inner wall of the housing 210, both ends are fixed by the carbbody 252 is fixed to the other side and the inner wall, respectively. At this time, the end of the carburetor 252 is connected to the mover 253, the mover 253 is fixed to the inner wall so as to be movable. As a result, the carcass 252 is to be movably connected to the inner wall of the housing 210 via the mover 253. In addition, the inner wall is formed to be inclined to form a slope-shaped base stage 211, and corresponding to one side of the second movable stage 250 is arranged and fixed facing the slope-shaped base stage 211, the body 252 is correspondingly Inclined. Here, the sloped base 211 may be located at an inner corner portion of the housing 210 having a rectangular parallelepiped shape.

This is clearly explained below.

As shown in FIG. 3, when the transmission line L receives a lateral force and a change occurs in the drawing direction, the fixing piece 230 which is rotatably fixed around the rotation shaft 231 rotates according to the lateral force, thereby suspending the insulator ( 310, 310 ', 310 "are rotated.

On the other hand, the end of the fixed piece 230 is rotated so as to transfer power to the first and second mobile units (220, 250), the first and second mobile units (220, 250) received this end of the fixed piece (230) Will move along the direction of travel. However, since the first and second moving tables 220 and 250 adjacent to each other are connected by the coil spring 240 having elasticity and tension, the first and second moving tables 220 and 250 are fixed pieces 230. The first and second moving bases 220 and 250 are fixed to move along a rotation path of the first and second moving bases 220 and 250 to maintain a connection state with other adjacent first and second mobile stations 220 and 250 via the coil spring 240. Will be rotated with (230). Of course, since the rotation of the first and second moving tables 220 and 250 is to maintain a straight line parallel with the linear housing 210, regardless of the rotation angle of the suspension insulators 310, 310 ', 310 ". The first and second mobile units 220 and 250 and the coil springs 240 maintain a straight line in a row, on the other hand, a guide 232 cut along the longitudinal direction is formed at the end of the fixing piece 230. , The first and second moving tables 220 and 250 and the fixing piece 230 are fixed to each other through the guide 232 and the pivoting fixed shaft 221. That is, as shown, the suspension insulator 310, When the fixing piece 230 is rotated by the rotation of the 310 'and 310 ", the first and second moving tables 220 and 250 connected to the fixing piece 230 move the guide 232 to maintain a straight line. Along the straight line.

As a result, since the first and second moving tables 220 and 250 maintain the straight state of the line while maintaining the straight state of the coil spring 240, the coil spring 240 has elasticity and tension corresponding to its elastic modulus. And the possibility of interference of the transmission line L connected to the adjacent suspension insulators 310, 310 ', 310 "so that the rotation angle between the suspension insulators 310, 310', 310" is accurately made according to the set design. Minimize.

For reference, the drawing of FIG. 3 shows the transmission line L rotated by the lateral force, the suspension insulator located on the left side rotated at a rotational angle of 30 degrees, and the suspension insulator in the middle rotated at a rotation angle of 20 degrees. The suspension insulator on the right side is rotated at a rotational angle of 10 degrees. This is because the coil spring 240 having the same elastic modulus is disposed between the first and second moving tables 220 and 250 and the coil spring 240 is kept in a straight line, thereby providing suspension insulators 310 and 310 '. , 310 "), the plurality of first and second mobile stages 220, 250 arranged in a line is always spaced at regular intervals, and thus between the suspension insulators 310, 310 ', 310" The angles are in a direction in which the power transmission lines L are separated from each other.

On the other hand, in order to maintain the linear state of the line of the coil spring 240 described above, the carburetor 252 connecting the second base 250 and the sloped base stage 211 of the housing 210 also has a sloped base It is movably connected via a stand 211 and a mover 253. To this end, the upper surface of the slope-shaped base 211 is formed a straight rail (not shown) for the common, forgiving, the mover 253 forms a structure that is connected to the rail so as to be movable.

One surface to which the carburetor 252 is connected to be drawn out from the second moving table 250 is formed in parallel with the inner wall of the slope-shaped base 211. However, since the second movable base 250 moves randomly according to the rotation angles of the suspension insulators 310, 310 ′ and 310 ″, the position directly facing the slope base stage 211 may be changed. If the carburetor 252 remains fixed to the slope type base 211, the carburetor 252 is bent in accordance with the position of the second moving table 250 to generate a difference in the elasticity, thereby This impedes the maintenance of the uniform rotation angle of the suspension insulators 310, 310 ', and 310 ".

However, when the carburetor 252 is connected to the slope base stage 211 via the mover 253 connected in a linear manner, the mover 253 moves together according to the position of the second mover 250. In this way, the carbohydrate 252 is elastically supporting the second moving table 250 and the slope-shaped base 211 while maintaining a straight state at all times. Of course, the elastic modulus of the elastic body 252 is accurately applied between the second moving table 250 and the sloped base stage 211 and the suspension springs 310, 310 ′, 310 ″ together with the coil spring 240. Optimize the angle of rotation.

Unexplained drawing number "212" shows the opening 212 of the housing 210 with which the fixing piece 230 is drawn out.

Figure 4 is an exploded perspective view showing the appearance of the rotating structure according to the present invention, Figure 5 is a cross-sectional view showing the operation of the rotating structure according to the present invention, will be described with reference to this.

When the transmission line L receives the lateral force, the suspension insulators 310, 310 ', 310 "rotate by the lateral force, and the jumper wire 330 is connected to the suspension insulators 310, 310', 310" for the jumper. The insulator 320 receives a force in the rotational direction of the suspension insulators 310, 310 ′, 310 ″.

Therefore, in order to prevent the jumper insulator 320 from being damaged by the force transmitted to the jumper wire 330, the jumper insulator 320 is also preferably rotatably fixed. However, the jumper wire 330 is connected to the other suspension insulator 310 'facing the suspension insulator 310, not the one suspension insulator 310, and thus the force and the direction of movement of the jumper line 330. May be random, and in order to stably fix the jumper wire 330, the jumper insulator 320 may be rotated in various directions according to the rotation angles of the suspension insulators 310 and 310 ′.

To this end, the jumper insulator 320 is fixed to the base frame 100 via the pivot structure 400 according to the present invention.

Rotating structure 400 is provided with a through hole 411 communicating with the through-hole 111 perforated on the upper surface of the case 110 of the base frame 100, and the fixed body 410 is installed in the case 110, The rotating guide body 420 fixed to the case 110 through the fixing body 410 and the inner surface is curved, and is fixed to the lower end of the jumper insulator 320 and drawn out to communicate with each other. Shafts 432 which penetrate through the through holes 411 and the sliding surface 421, respectively, and have a spherical sliding hole 431 slidably engaged with the sliding surface 421, and are drawn out below the sliding hole 431. A linker 430 having a center weight 433 formed to be spaced apart from the sliding hole 431 and a center of the shaft 432 to be positioned between the center weight 433 and the pivoting guide 420. The buffer 440 is fixed.

That is, when the jumper insulator 320 receives a force from the jumper wire 330, the force is transmitted to the linker 430, and the linker 430 is fixed to the sliding hole 431 by slidingly engaging the sliding surface 421. ) Is inclined in the rotational direction of the jumper insulator 320 by the force. At this time, the center weight 433 located at the bottom of the linker 430 moves the center of gravity of the jumper insulator 320 and the pivot structure 400 under the sliding hole 431, so that the transmission line L is subjected to an external force. In a situation where the jumper insulator 320 is always upright.

Subsequently, the central weight 433 forms a circle having a larger diameter than the shaft 432, and the buffer body 440 positioned between the central weight 433 and the pivoting guide 420 while surrounding the shaft 432. Forms a circle corresponding to a circular center weight 433. As a result, when the jumper insulator 320 is inclined by the force transmitted from the jumper wire 330, the shock absorber 440 prevents sudden rotation to minimize the impact, and when the external force is not large, the jumper insulator 320. ) To maintain the upright state at all times.

Meanwhile, as described above, the center weight 433 and the buffer 440 are circular, and the buffer body 440 is the center weight 433 and the guide for rotation 420 regardless of the rotation direction of the linker 430. Make sure the elastic force applied to) is constant.

Unexplained drawing number "321" is a grabper 321 for fixing the jumper wire 330 to the jumper insulator 320, is fixed to the top of the jumper insulator 320.

Figure 6 is an exploded perspective view showing the connection of the fixing piece and the first mobile according to the present invention, Figure 7 is a view showing a cross-sectional view of the fixed base adjusted through the operation of the first mobile according to the present invention. , With reference to this.

The first movable table 220 which is rotatably fixed to the fixing piece 230 has a nut part 222 having a thread formed therein, and a bolt part 223 linearly moving by thread binding while penetrating the nut part 222. ) And the coil springs 240 are connected to both ends of the bolt part 223. At this time, the coil spring 240 is fixed via the swivel 224 that is rotatably fixed to both ends of the bolt portion 223 to maintain the current state regardless of the rotation of the bolt portion 223.

For reference, the swivel 224 is rotatably inserted into the fixing grooves 223a respectively formed at both ends of the bolt portion 223 to form a fixing protrusion 224a to be engaged, and known and publicly applied technology is rotatable. Is fixed. On the other hand, an engaging groove 224b for fixing the coil spring 240 may be formed on one surface of the rotating table 224 connected to the coil spring 240.

Coil spring 240 is applied to the stator according to the present invention is a constant modulus of elasticity will be applied, but long-term use and deformation may occur in the length and shape of the coil spring 240. That is, the first and second mobile units 220 and 250 which maintain a constant distance by the elastic force and tension of the coil spring 240 may have a difference in the distance between them due to the deformation of the coil spring 240. . Of course, since the first and second mobile units 220 and 250 are connected to the suspension insulators 310, 310 ′ and 310 ″, respectively, the change in the spacing of the first and second mobile units 220 and 250 is directly suspended. , 310 ', 310 ") are damaged.

Therefore, the fixing stand according to the present invention allows the position of the fixing piece 230 to be corrected by adjusting the positions of the first and second moving tables 220 and 250 without replacing the deformed coil spring 240.

In more detail, as described above, the bolt part 223 is inserted into the nut part 222 and moves while being thread-bound through its own rotation. That is, the bolt portion 223 itself moves along the longitudinal direction to adjust the degree of protrusion in both directions of the first movable table 220. Of course, since the bolt part 223 forms a body, when the bolt part 223 is drawn out to one side of the first moving table 220, the bolt part 223 is drawn out to the other side. Therefore, the length of the coil spring 240 connected to both sides of the first movable table 220 is adjusted along the movement of the bolt portion 223, so that the first and second movements may be performed regardless of the change in the length of the coil spring 240. The intervals of the suspension insulators 310, 310 ′ and 310 ″ fixed by the stands 220 and 250 are parallel to each other.

1 is a perspective view showing a state of the fixing rod according to the present invention,

2 and 3 is a view showing a cross-sectional view of the fixture according to the invention,

Figure 4 is an exploded perspective view showing the appearance of the rotating structure according to the present invention,

5 is a cross-sectional view showing the operation of the rotating structure according to the present invention,

Figure 6 is an exploded perspective view showing the connection of the fixing piece and the first movable table according to the present invention,

7 is a view showing a cross-sectional view of the fixed base adjusted by the first mobile unit operation according to the present invention.

Claims (1)

Base frame 100 having a through-hole 111 is formed on the upper surface and having a tubular case 110 having a hollow, In the tubular shape of a rectangular parallelepiped having a hollow, an opening 212 for opening the hollow is formed along the longitudinal direction, and is fixed to the front and rear surfaces of the base frame 100, respectively, and forms a sloped inner wall inclined inside the corner. A housing 210 having a stand 211; Equipped with a rotational fixed shaft 221, it is movably embedded in the housing 210, forms a threaded portion formed through the inner surface of the threaded portion 222, while having a thread corresponding to the nut portion 222 A first movable table 220 having a bolt part 223 threadedly coupled through the nut part 222 and a swivel table 224 rotatably fixed to both ends of the bolt part 223; A carbide body having a rotatable fixed shaft 251, which is internally movably in the corner of the housing 210, and forms one surface facing in parallel with the slope-shaped base 211, and is pulled and fixed from the one surface ( 252 and a second moving table 250 having a mover 253 fixed to the distal end of the carburetor 252 and movably engaged with the inner wall of the slope-shaped base 211; One end penetrates through the opening 212 while being rotatably fixed to the hollow of the housing 210 via the rotation shaft 231, and one end is connected to the suspension insulators 310, 310 ′ and 310 ″ and the other end is rotated. A fixing piece 230 connected to the first and second moving bases 220 and 250 via a guide 232 cut in the longitudinal direction so that the mold fixing shafts 221 and 251 are movably engaged; Coil springs 240 are fixed to the neighboring first and second mobile units 220 and 250, respectively, and are rotatably fixed to the bolt unit 223 via the swivel table 224 with the first mobile unit 220. A damper support 200 having a), and A through hole 411 communicating with the through hole 111, and a fixed body 410 embedded in the case 110; A rotating guide body 420 fixed to the fixed body 410 while forming a curved sliding surface 421; The drawer is fixedly drawn out at the lower end of the jumper insulator 320 fixed on the case 110 to penetrate through the through hole 111, the through hole 411, and the sliding surface 421, respectively, and slides in engagement with the sliding surface 421. The center of gravity of the spherical sliding sphere 431, the shaft 432 drawn out below the sliding sphere 431, and the jumper insulator 320 to be fixed so as to be below the sliding sphere 431 A linker 430 having a circular center weight 433; Rotating structure 400 having a circular buffer 440 disposed between the pivoting guide 420 and the center weight 433 while wrapping the shaft 432. Jumper wire fixture for connecting the power transmission line comprising a.

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