KR102118128B1 - Fanel structure of high voltage distribution line - Google Patents

Abstract

The present invention relates to a panel structure of an extra-high voltage overhead distribution line. More specifically, the present invention relates to a panel structure of an extra-high voltage overhead distribution line which prevents a short circuit, interference and the like by maintaining a plurality of distribution lines disposed in parallel to each other at regular intervals, prevents an insulator connected in a row to the distribution line from being damaged due to a lateral force applied on the distribution line, and smoothly performs restoration to an original state in accordance with left and right tilting of the insulator for a jumper by a force transferred to a jumper line and the like, thereby easily coping with the force transferred from the outside through a stable state.

Description

Panel structure of high voltage distribution line

The present invention relates to a panel structure of a special high-voltage overhead power distribution line among distribution technology fields, and more specifically, maintains a plurality of distribution lines arranged side by side at regular intervals to prevent short circuits and interference, and the distribution line due to the lateral force received by the distribution line It prevents the insulator connected in line from being damaged, while restoring to the original state as the insulator for the jumper inclines by the force transmitted by the jumper wire, etc., so that it can be smoothly restored and transmitted from the outside through a stable state. It relates to a special high-voltage overhead power distribution panel structure to easily respond to the force.

The distribution electricity flowing along the distribution line is transformed into a special high voltage for efficient long-distance distribution of the generated electricity. In addition, distribution is performed through a plurality of distribution lines in consideration of distribution efficiency and distribution.

However, in order to maintain a stable power distribution state, interference between power distribution lines in which a plurality of dogs are arranged side by side is minimized, and adjacent rotation within an allowable interval between power distribution lines should be prevented even when rotating by external force.

In addition, damage to the insulators should also be prevented by the distribution lines moving in the lateral direction by minimizing the lateral force received by the insulator during the lateral movement of the distribution line by wind power.

However, in the conventional distribution line structure installed in the processed distribution tower, any technique for maintaining the spacing of multiple distribution lines arranged side by side is not applied, and a structure for preventing insulator damage is also not applied at all. There is a problem in that interference, short circuit, and damage to the insulator fixing the distribution line are frequently generated.

As a prior art that partially improves these problems, Korean Patent Registration No. 10-0936285 (2010.01.13.) discloses a'suspended insulator support panel for structural reinforcement of a transmission line'.

However, such a conventional support panel has a problem that it is difficult to smoothly restore the original state as the left and right tilt of the insulator for the jumper by the force transmitted to the jumper wire.

Republic of Korea Patent Registration No. 10-0936284 (Jan. 13, 2010)'Suspension insulator support panel for structural reinforcement of transmission line'

The present invention was devised to solve the above-mentioned problems, and the object of the present invention is to maintain a plurality of distribution lines arranged side by side at regular intervals to prevent short circuits and interference, and to line up with the distribution lines due to the lateral force received by the distribution lines. It prevents the insulator connected to the product from being damaged, and the power transmitted from the outside through the stable state by enabling the restoration to the original state smoothly as the insulator for the jumper inclines by the force transmitted by the jumper wire, etc. It is to provide a special high-voltage overhead power distribution panel structure to easily respond to.

The problem to be solved of the present invention is not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention is a foundation frame 100 having a hollow tube 111 and a tubular case 110 having a hollow on the upper surface: a tubular shape of a rectangular parallelepiped having a hollow, the foundation frame An opening 212 is formed at regular intervals to be fixed to the front and rear surfaces of (100), and the suspension insulators (310, 310', 310") are drawn out, and a sloped foundation ((2) forming an inclined inner wall inside the corner ( 211), a housing 210 having a roller 213b at one end and a door 213 movably fixed along the opening 212; and a housing 210 having a pivoting fixed shaft 221 A first movable platform 220 that is movably installed in the body; a rotating fixed shaft 251, which is movably installed inside the corner of the housing 210, and faces in parallel with the sloped base 211 To form a surface to be, but is fixed to the withdrawal from the one side of the ball body 252 and the mover 253 fixed to the end of the ball body 252 and movably engaged with the inner wall of the sloped base 211 Equipped with a second movable platform 250, and pivotably fixed to the housing 210 via the rotation shaft 231, one end is connected to the suspension insulator (310, 310', 310") and the other end is fixed to the rotation type The shafts 221 and 251 are respectively connected to the first and second movable platforms 220 and 250 via guides 232 that are cut in the longitudinal direction so as to be movably engaged, and rollers 213b are inserted and moved on the side surfaces. A fixing piece 230 having a guide groove 233 formed in an incision along a longitudinal direction while a jaw is formed at an entrance side to enable engagement; A damper support 200 having coil springs 240 fixed to the first and second movable platforms 220 and 250 adjacent to both ends: and a through hole 411 communicating with the through hole 111, , The fixed body 410 that is installed in the case 110; A rotating guide body 420 fixed to the fixed body 410 while forming a curved sliding surface 421; It is fixedly pulled out at the bottom of the insulator 320 for the jumper fixed to the case 110 and penetrates the through hole 111, the through hole 411, and the sliding surface 421, respectively, and slides in engagement with the sliding surface 421 When connecting the spherical sliding mechanism 431 that is fixed as possible, the shaft 432 that is drawn downward from the sliding mechanism 431, and the insulator 320 for the jumper, the center of gravity is set to be below the sliding mechanism 431. A linker 430 having a circular central weight 433; In the high-voltage overhead power distribution panel panel structure composed of a rotating structure 400 having a circular buffer 440 disposed between the pivoting guide body 420 and the central weight 433 while surrounding the shaft 432 , The jumper insulator 320 further includes a support portion 500 for smoothly restoring to the original state as the left and right tilt, but the support portion 500 protrudes downward from the central weight 433 A hemisphere-shaped rotating member 510; Guide means 520 for supporting the rotation member 510 from the inner bottom surface of the case 110; And support means 530 for supporting both sides of the center weight 433 from the inner bottom surface of the case 110, and inducing restoration to the original state according to the left and right rotation of the jumper insulator 320, the guide The means 520 includes a plurality of wheels 521 in contact with the rotation member 510; A fixed frame 522 to which the wheel 521 is rotatably fixed; And a support frame 523 rotatably supporting the fixed frame from the inner bottom surface of the case 110, the support means 530 having one end connected to both sides of the central weight 433 and the other end outside The flange 531 is formed to extend, the hollow 531a penetrating in the vertical direction extending from the other end in one direction; A support bar 532 having a lower portion passing through the inner bottom of the case 110 and an upper portion passing through the hollow 531a; Includes a spring 533 coupled to the outside of the support bar 532 so as to be located between the flange 531 and the inner bottom surface of the case 110, the spring 533 is rotated left and right of the insulator 320 for the jumper According to the contraction and relaxation, press the flange 531 so that the insulator 320 for the jumper is restored to its original state smoothly, and the support part 500 includes an anti-friction plate provided between the spring 533 and the flange 531 ( 540) provides a panel structure of a special high-voltage overhead power distribution line characterized in that it further comprises.

According to the present invention, it is possible to minimize the damage of the insulator itself by dispersing the lateral force while the insulator rotates even when the plurality of power distribution lines arranged side by side at regular intervals are maintained regardless of the presence or absence of external force, and even when the power distribution line moves in the lateral direction. There is.

In addition, as the left and right tilt of the jumper insulator due to the force transmitted to the jumper line, etc. can be smoothly restored, the state that can easily respond to the force transmitted from the outside through the stable state is maintained. It has the effect.

The effects of the present invention are not limited to those mentioned above, and other solutions not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a perspective view showing a special high voltage overhead power distribution panel panel structure according to the present invention.
2 and 3 is a cross-sectional view showing the panel structure of the extra-high voltage overhead power distribution line according to the present invention.
Figure 4 is an exploded perspective view showing a rotating structure in the panel structure of the extra-high voltage overhead power distribution line according to the present invention.
Figure 5 is a longitudinal cross-sectional view showing the operating state of the rotating structure in the panel structure of the extra-high voltage overhead power distribution line according to the present invention.
Figure 6 is an exploded perspective view showing the fixed piece and the first mobile station in the special high voltage overhead power distribution panel structure according to the present invention.
7 is a longitudinal cross-sectional view showing a state in which the support is provided in the special high voltage overhead power distribution panel panel structure according to the present invention.
8 is a longitudinal sectional view showing an operating state of the support in FIG. 7.
9 is an enlarged exploded view showing a guide means in FIG. 7.
And
10 is a partially enlarged cross-sectional view showing a support portion in the panel structure of the extra-high voltage overhead power distribution line according to the present invention.

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

Referring to Figures 1 to 6, the special high-voltage overhead power distribution panel panel structure according to the present invention is horizontally fixedly supported on the overhead power distribution tower and the base frame 100, the front and rear surfaces of the base frame 100, each facing each other It is arranged and three or more suspension insulators (310, 310', 310") to support the damper support 200 for fixing in a line, and the jumper insulator 320 placed on the upper surface of the base frame 100 is rotatable It includes a rotating structure 400 to be fixed.

Suspension insulators 310, 310', 310" disposed to face each other support the distribution line L, and jumper insulators 320 placed in the base frame 100 are suspension insulators 310, 310', 310 ") While the jumper wire 330 drawn out is fixed, the disconnected power distribution line L around the base frame 100 is electrically connected.

The foundation frame 100 is a hollow tube shape, and forms a skeleton of a processed distribution tower that securely fixes the distribution line L.

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

At one end of the suspension insulators 310, 310', 310", the fixing piece 230 is fixed in a row, and is rotatably fixed to the housing 210 of the support 200 for dampers via the rotation shaft 231. .

That is, the fixing piece 230 is rotated around the rotation shaft 231, through which the suspension insulators 310, 310', 310" are fixed to the housing 210 to be rotatable.

The housing 210 has a hollow tube shape, and the first and second movable units 220 and 250 are movably accommodated.

At the end of the fixed piece 230, a guide 232 cut in the longitudinal direction of the fixed piece 230 is formed, and the rotation-type fixed shafts 221 and 251 interlocked by being rotatably and movable in the guide 232 The first and second mobile platforms 220 and 250 are fixed through.

The first and second movable platforms 220 and 250 are connected to the linear movement of the fixed piece 230 as well as rotation.

The first mobile station 220 refers to a configuration in which the first mobile station 220 or the second mobile station 250 faces in both directions, and the second mobile station 250 has one side with the first mobile station 220. Points to a configuration facing the other side facing the inner wall of the housing 210.

The first and second mobile platforms 220 and 250 are supported by mutual bullets through the coil spring 240.

That is, while the both ends of the coil spring 240 are respectively connected to the first and second mobile units 220 and 250 facing each other, the intervals between the first and second mobile units 220 and 250 facing each other may be kept constant. To make.

The coil spring 240 has elastic force to push the first and second movable units 220 and 250 to each other, as well as tension to pull each other.

The other side of the second movable platform 250 facing the inner wall of the housing 210 is fixed to each other by bullets 252 fixed to the other side and the inner wall, respectively.

At this time, the distal end of the elastic body 252 is connected to the mover 253, the mover 253 is fixed by being movably engaged with the inner wall.

The elastic body 252 is movably connected to the inner wall of the housing 210 via the mover 253.

The inner wall is formed to be inclined to form a sloped base stand 211, and correspondingly, one side of the second movable stand 250 to which the elastic body 252 is disposed and fixed while facing the sloped base stand 211 is also inclined side by side. Lose.

The oblique base 211 is located in the inner corner portion of the housing 210 having a rectangular parallelepiped shape.

This will be explained clearly below.

As shown in FIG. 3, when the distribution line L receives a lateral force and a change occurs in the withdrawal direction, the fixed piece 230 fixedly rotatable around the rotation shaft 231 rotates according to the lateral force, and the suspension insulator 310 , 310', 310").

The end of the rotated fixed piece 230 transmits power to the first and second movable units 220 and 250, and the received first and second movable units 220 and 250 move the end of the fixed piece 230 It will move along the direction.

Since the first and second movable platforms 220 and 250 adjacent to each other are connected by a coil spring 240 having an elastic force and tension, the first and second movable platforms 220 and 250 rotate the fixed piece 230 It moves along the path, but is rotated with the fixing piece 230 to maintain a connection state with other neighboring first and second mobile platforms 220 and 250 via the coil spring 240.

Since the rotation of the first and second movable platforms 220 and 250 is to maintain a straight state parallel to the linear housing 210, the first and second movable stands 310, 310', and 310" are rotated regardless of the rotational angle. ,2 The mobile table (220, 250) and the coil spring 240 is to maintain a straight line of a line.

A guide 232 cut along the longitudinal direction is formed at the end of the fixing piece 230, and is fixed with the first and second movable units 220 and 250 via the guide 232 and the rotating fixed shaft 221. The pieces 230 are fixed to each other.

That is, when the fixed piece 230 is rotated by the rotation of the suspension insulators 310, 310', 310", the first and second movable tables 220 and 250 connected to the fixed piece 230 maintain a straight line in a line. In order to do this, it moves linearly along the guide 232.

As a result, the coil spring 240 maintains a straight state without bending, while the first and second movable bands 220 and 250 maintain a straight line in a row, so that the coil spring 240 has elastic force and tension suitable for its elastic modulus. And the rotation angle between the suspension insulators 310, 310', 310" is made to match the set design, so that the possibility of interference of the distribution lines L connected to the adjacent suspension insulators 310, 310', 310" To minimize.

The drawing of FIG. 3 shows that the distribution line (L) is rotated by receiving a lateral force, and the suspension insulator located on the left side rotates at a rotation angle of 30 degrees, and the suspension insulator located in the middle rotates at a rotation angle of 20 degrees, and on the right side. The present insulator was rotated at a rotation angle of 10 degrees.

This is by placing the coil spring 240 having the same modulus of elasticity between the first and second carriers 220 and 250, and maintaining the coil spring 240 in a straight line in a row, thereby making the suspension insulators 310 and 310' , 310"), the plurality of first and second mobile units 220 and 250 arranged in a line regardless of the rotation angle are always spaced apart at regular intervals, thereby interposing the suspension insulators 310, 310', 310". The angles are in a direction in which the distribution lines L are spaced apart from each other.

On the other hand, in order to maintain the linear state of the line of the above-described coil spring 240, the elastic body 252 connecting the second movable platform 250 and the sloped foundation 211 of the housing 210 is also sloped. The stage 211 and the mover 253 are movably connected via a medium.

To this end, the upper surface of the slope-type base stand 211 is formed with a linear rail (not shown) for public and common use, and the mover 253 is movably engaged and connected to the rail.

One surface to which the elastic body 252 is drawn out from the second movable platform 250 is formed parallel to the inner wall of the slope-based foundation 211.

However, since the second movable platform 250 moves randomly according to the rotation angle of the suspension insulators 310, 310', 310", the position facing the slope-based foundation 211 must be changed.

That is, if the elastic body 252 is maintained in a fixed state on the slope-based base 211, the elastic body 252 is bent according to the position of the second movable platform 250, causing a difference in the elastic force, This impedes the maintenance of the uniform rotation angle of the suspension insulators 310, 310', 310".

When the elastic body 252 is connected via the mover 253 connected to the slope-type base 211 in a straight line, the mover 253 moves together according to the position of the second mover 250, and Through the elastic body 252, while maintaining a straight state at all times, the second movable platform 250 and the slope-based foundation 211 are supported.

The elastic modulus of the elastic body 252 is accurately applied between the second movable base 250 and the sloped base base 211, and the rotation angle of the suspension insulators 310, 310', 310" together with the coil spring 240 is applied. Optimize.

Unexplained withdrawal number "212" shows the opening 212 of the housing 210 through which the fixing piece 230 is withdrawn.

Unexplained withdrawal number "213" shows the shape of the door 213 closing the opening 212, the guide grooves 233 and rollers formed along the longitudinal direction on the side of the fixing piece 230 ( 213b) is connected by a medium to move in conjunction with the rotation of the fixing piece 230, thereby allowing the opening 212 to maintain a closed state at all times.

When the distribution line (L) receives a lateral force, the suspension insulators (310, 310', 310") are rotated by the lateral force, and jumpers connected to the suspension insulators (310, 310', 310") via the jumper wire (330). The insulator 320 receives the 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, it is preferable that the jumper insulator 320 is also fixed to be rotatable.

By the way, the jumper wire 330 is also connected to the other insulator 310' facing the suspension insulator 310, not one suspension insulator 310, so the force received by the jumper wire 330 and its moving direction Is bound to be random, and in order to stably fix the jumper wire 330, the jumper insulator 320 must be able to 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 rotation structure 400 according to the present invention.

The rotating structure 400 is provided with a through hole 411 communicating with a through hole 111 drilled on the upper surface of the case 110 of the foundation frame 100, and the fixed body 410 installed in the case 110 and the inner surface The rotating guide body 420, which is formed in the curved shape and fixed to the case 110 via the fixing body 410, and through the through hole 111, which is fixedly pulled out at the bottom of the insulator 320 for the jumper and communicates with each other. The sphere 411 and the sliding surface 421 are to pass through, respectively, but the sliding surface 421 is provided with a spherical sliding hole 431 that is slidably engaged with the sliding surface 421, and the axle 432 drawn downward from the sliding hole 431 is provided. Fixed around the axle 432 so as to be positioned between the linker 430 having a central weight 433 formed spaced apart from the sliding sphere 431 and the central weight 433 and the rotational guide 420 as a medium. It becomes a buffer body 440.

That is, when the insulator 320 for the jumper receives a force from the jumper wire 330, the force is transmitted to the linker 430, and the sliding hole 431 is slidably engaged with the sliding surface 421 and fixed with the linker 430 ) Is inclined in the rotational direction of the jumper insulator 320 by the force.

The central weight 433 located at the bottom of the linker 430 moves the center of gravity of the insulator 320 for the jumper and the rotating structure 400 below the sliding hole 431, so that the distribution line L does not receive external force. In so that the jumper insulator 320 is always upright.

The central weight 433 forms a circle having a larger diameter than the shaft 432, and the buffer 440 positioned between the central weight 433 and the rotation guide 420 while surrounding the shaft 432 is circular. It forms a circle corresponding to the central weight 433.

After all, when the insulator 320 for a jumper is inclined by the force transmitted from the jumper wire 330, the shock absorber 440 prevents sudden rotation to minimize the impact, and if the external force is not large, the insulator for the jumper 320 ) To maintain the upright condition at all times.

 Meanwhile, as described above, while the central weight 433 and the buffer body 440 are circular, the buffer body 440 is the central weight 433 and the rotation guide body 420 regardless of the rotational direction of the linker 430. ) So that the elastic force to be applied is constant.

Unexplained withdrawal number "321" is a gripper 321 that fixes the jumper wire 330 to the insulator 320 for jumpers, and is disposed and fixed on the top of the insulator 320 for jumpers.

Referring to Figure 3 and Figure 6, the side of the fixing piece 230 is formed with a guide engaging groove 233 on the side of the entrance is formed in the longitudinal direction along the longitudinal direction.

A guide rail 214 for guiding in the direction corresponding to the rotational direction of the fixing piece 230 along the edge is formed in the opening 212, and the door 213 closing the opening 212 is guide rail 214 ) And is movably engaged and fixed.

The door 213 moves linearly along the guide rail 214 while a guide groove 213a is formed for movable engagement and fixing with the guide rail 214. The movement of the door 213 is made corresponding to the longitudinal direction of the opening 212.

The roller 213b is rotatably fixed to one end of the door 213 connected to the fixing piece 230.

The roller 213b is inserted into the engaging groove 233 for the guide, and is engaged with the chin at the entrance side of the engaging groove 233 for the guide, and can move along the chin.

Since the door 213 moves linearly along the guide rail 214, and the fixed piece 230 rotates around the rotation shaft 231, a difference occurs in the movement paths of the door 213 and the fixed piece 230. .

Therefore, regardless of the difference in the movement path, the fixing piece 230 rotates stably, and the door 213 has a length of the fixing piece 230 for the guide locking groove 233 as described above in order to stably move in a straight line. It is formed in a predetermined length along the direction, and in addition, the door 213 is movably fitted in the guide engaging groove 233 through a roller 213b.

On the other hand, since these doors 213 are connected to both sides of the fixed piece 230 and move along the fixed piece 230, the openings 212 opened in the direction of the suspension insulators 310, 310', 310" are It is always closed by (213), it is possible to block the inflow of various foreign matter scattering into the support 200 for the damper through the opening 212.

The special high voltage overhead power distribution panel panel structure according to the present invention further includes a support portion 500 to smoothly restore the original state as the left and right tilts of the insulator 320 for jumpers as shown in FIGS. 7 to 10. do.

The support part 500 can be restored to the original state smoothly as the left and right tilts of the jumper insulator 320 due to the force transmitted to the jumper line 330 or the like, to the force transmitted from the outside through a stable posture. Make it easy to respond.

The supporting part 500 is a hemispherical pivoting member 510 protruding downward from the central weight 433, guide means 520 and a case supporting the pivoting member 510 from the inner bottom surface of the case 110 ( While supporting both sides of the central weight (433) from the inner bottom surface of the 110, and includes support means (530) for inducing the restoration to the original state according to the left and right rotation of the jumper insulator (320).

The rotating member 510 is connected to the lower surface of the central weight 433 while the upper surface is horizontal, and the lower part forms a hemispherical shape protruding downward and rotates with the inclination of the insulator 320 for the jumper 400 ) To make the inclination smooth.

The rotation member 510 may smoothly return to its original state due to rotation while the lower surface forms a hemispherical shape.

The guide means 520 is capable of rotating a fixed frame from a plurality of wheels 521 contacting the rotation member 510, a fixed frame 522 to which the wheels 521 are rotatably fixed, and an inner bottom surface of the case 110. It includes a support frame 523 to support.

The fixed frame 522 is formed so as to have an'c' shape in which the upper part is opened so that the wheel is rotatably supported inward.

The support frame 533 is fixed to the inner bottom surface of the case 110 and the upper portion is formed to extend upward, while the fixing frame 522 is rotatably fixed by a bearing 524 or the like.

Accordingly, the guide means 520 stably supports the rotating member 510 from the inner bottom surface of the case 110, and for the jumper due to the force transmitted to the jumper wire 330 while minimizing the contact area. As the insulator 320 is inclined, the phenomenon that the rotation structure 400 is separated from the case 110 can be prevented.

The support means 530 has one end connected to both sides of the central weight 433, the other end extending outwardly, and a hollow 531a in which a hollow penetrating in the vertical direction extends in one direction from the other end is formed. Flange 531, the support bar 532 extending upward from the inner bottom surface of the case 110, the outside of the support bar 532 to be located between the inner bottom surface of the flange 531 and the case 110 It includes a spring 533 coupled to.

The flange 531 is provided on both sides of the central weight 433 in a pair, and the hollow 531a is formed extending from one end of the flange 531 in one direction, and when viewed from the top, the other end is open It forms the shape of'U'.

When the sliding hole 431 is rotated, the flange 531 does not contact the support bar 532 by the hollow 531a.

The spring 533 is not rotated together when the sliding hole 431 is rotated while the upper part is in contact with it without being fixed to the flange 531, and the flange 531 is contracted and relaxed according to the left and right rotation of the jumper insulator 320. ) To ensure that the jumper insulator 320 is restored to its original state smoothly.

The support part 500 further includes an anti-friction plate 540 provided between the spring 533 and the flange 531.

The friction preventing plate 540 is formed in a hemisphere shape and a through hole 541 through which the support bar 532 passes is formed in the central portion.

The friction preventing plate 540 allows the contact area with the flange 531 to be minimal compared to the spring 533 so that the rotation of the flange 531 according to the rotation of the sliding hole 431 can be smoothly performed.

The support means 530 further includes a binding member 534 for binding the support bar 532 to the case 110.

The case 110 is formed with a hole 110a through which a lower portion of the support bar 532 passes on the bottom surface.

The binding member 534 is made of a nut or the like on which the thread is formed on the inner circumferential surface, and is fixed to the lower portion of the case 110 to communicate with the hole 110a.

The support bar 532 is formed with a thread on the outer circumferential surface and is screwed so as to be elevated and lowered to the binding member 534.

The support means 530 further includes a pressure plate 535 provided on the support bar 532 and an adjustment lever 536 provided on the lower part of the support bar 532 to be positioned under the spring 533.

The adjustment lever 536 is connected to rotate together with the support bar 532 and transmits rotational force to the support bar 532 while being rotated by artificial rotation of an operator or the like.

The pressure plate 535 is fixed to the support bar 532 so as to be positioned at the lower portion of the spring 533 while stably supporting the spring 533, and is lifted together with the support bar 532 according to the rotation of the adjustment lever 536. , As it descends, presses or releases the spring 533.

Accordingly, the adjustment lever 536 allows the pressure plate 535 to be raised and lowered together with the support bar 532 according to rotation to properly adjust the elastic force of the spring 533.

For this reason, the support part 500 is transmitted from the outside through a stable state by allowing the restoration to the original state smoothly as the left and right tilts of the jumper insulator 320 by the force transmitted to the jumper line 330, etc. It is possible to maintain a state that can easily respond to the force being applied.

100: foundation frame 110: case
200: damper support 210: housing
220: first mobile station 230: fixed piece
240: coil spring 250: second mobile
310,310',310": Suspension insulator 320: Jumper insulator
330: jumper 400: rotating structure
410: fixed body 420: rotating guide body
430: linker 440: buffer
500: support 510: rotating member
520: guide means 530: support means

Claims (1)

The base frame 100 having a through-hole 111 formed on the upper surface and having a tubular case 110 having a hollow:
A rectangular parallelepiped having a hollow shape, fixed to the front and rear surfaces of the base frame 100, and openings 212 are formed at regular intervals so that the suspension insulators 310, 310', 310" are drawn out, and inside the corners. A housing 210 having a sloped foundation 211 which forms an inclined inner wall, and a door 213 formed at one end with a roller 213b and movably fixed along the opening 212; A first moving table 220 having a shaft 221 and movably installed in the housing 210; a rotating fixed shaft 251, and movably installed inside an edge of the housing 210, Forming one surface facing in parallel with the slope-like foundation (211), the elastic body 252 is drawn out and fixed from the one surface, and fixed to the end of the elastic body 252 and the inner wall of the slope-like foundation (211) A second movable platform 250 having a movable member 253 which is movably engaged and fixed, and is fixed to be rotatable with the housing 210 via a rotating shaft 231, one end being a suspension insulator 310, 310', 310"), and the other end is connected to the first and second movable platforms 220 and 250 via the guides 232 formed in the longitudinal direction so that the rotatable fixed shafts 221 and 251 are movably engaged. , The side of the roller (213b) is inserted into the fixed piece 230 is formed with a guide groove (233) formed incision along the longitudinal direction while the jaw is formed on the inlet side to be movably engaged; Damper support 200 having coil springs 240 fixed to the first and second movable platforms 220 and 250 adjacent to both ends, respectively: and
A through-hole 411 communicating with the through-hole 111, and a fixed body 410 installed in the case 110; A rotating guide body 420 fixed to the fixed body 410 while forming a curved sliding surface 421; It is fixedly pulled out at the bottom of the insulator 320 for the jumper fixed to the case 110 and penetrates the through hole 111, the through hole 411, and the sliding surface 421, respectively, and slides in engagement with the sliding surface 421 When connecting the spherical sliding ball 431 that is fixed as possible, the shaft 432 that is drawn downward from the sliding ball 431, and the insulator 320 for the jumper, the center of gravity is below the sliding ball 431. A linker 430 having a circular central weight 433; In the high-voltage overhead power distribution panel panel structure including a rotating structure 400 having a circular buffer 440 disposed between the pivoting guide body 420 and the central weight 433 while surrounding the shaft 432. In,
The jumper insulator 320 further includes a support portion 500 to allow the restoration to the original state smoothly as the left and right tilt,
The support part 500,
A hemispherical rotating member 510 protruding downward from the central weight 433;
Guide means 520 for supporting the rotation member 510 from the inner bottom surface of the case 110; And
While supporting both sides of the center weight 433 from the inner bottom surface of the case 110, and includes support means 530 for inducing the restoration to the original state according to the left and right rotation of the insulator 320 for the jumper,
Guide means 520,
A plurality of wheels 521 in contact with the rotating member 510;
A fixed frame 522 to which the wheel 521 is rotatably fixed; And
It includes a support frame 523 rotatably supporting the fixed frame from the inner bottom surface of the case 110,
Support means 530,
A flange 531, one end of which is connected to both sides of the central weight 433, the other end of which extends outward, and a hollow 531a penetrating in the vertical direction extends from the other end in one direction;
A support bar 532 having a lower portion passing through the inner bottom of the case 110 and an upper portion passing through the hollow 531a;
A spring 533 coupled to the outside of the support bar 532 to be located between the flange 531 and the inner bottom surface of the case 110;
A binding member 534 that is coupled to the support bar 532 to the case 110 while being screwed to the support bar 532 to be located at the bottom of the case 110;
A pressure plate 535 provided on the support bar 532 to support the spring 533 so as to be located at the bottom of the spring 533; And
It is provided on the lower portion of the support bar 532 and includes an adjustment lever 536 to adjust the elastic force of the spring 533 by allowing the pressure plate 535 to rise and fall with the support bar 532 according to rotation,
The spring 533,
The insulator 320 for the jumper is pressed and contracted and relaxed according to the left and right rotation of the insulator 320 so that the insulator 320 for the jumper is restored to its original state smoothly,
The pressure plate 535,
Pressing or releasing the spring 533 as it moves up and down with the support bar 532 according to the rotation of the adjustment lever 536,
The support part 500,
It forms a hemisphere projecting upward, and a through hole 541 is formed in the center. While being coupled with the support bar 532 so as to be positioned between the spring 533 and the flange 531, the contact area with the flange 531 is minimized, so that the rotation of the flange 531 according to the rotation of the sliding hole 431 is smooth. Special high pressure overhead power distribution panel panel structure further comprises a friction preventing plate 540 to be made.

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