KR100847476B1 - Protecting hanging down electric power distribution connecting structure - Google Patents

Abstract

A connection structure for preventing a power distribution cable from sagging is provided to maintain the tight power distribution cable by rotating a disk based on a length change of the power distribution cable. A connection structure for preventing a power distribution cable from sagging includes a fixing bar(100), a disk(200), a spring(300), a stopper(400), an insulator fixing unit(500), a hanger(600), and a tension spring(700). The fixing bar is fixed on an arm, and has a rotation axis. An axis rotatably fixes a circular plate from the rotation axis. A guide groove is formed along an outer circumference plane. A plate body is fixed on the circular plate to cover the rotation axis. A center of the spring is fixed on the rotation axis. The spring rotatably supports the disk. An end of the stopper is fixed on the fixing bar or an arm to confine a rotation angle of the disk within a range of a guide. The other end of the stopper is movably geared with the guide. The insulator fixing unit is fixed on an end of an insulator. The hanger is movably penetrated to a guide groove. An end of the tension spring is fixed on a fixed body withdrawn from the fixing bar. The other end of the tension spring is coupled to the hanger. The tension spring pulls the hanger elastically.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a power line connecting structure,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a distribution line connection structure that prevents sagging of a distribution line connected to a support.

Electricity generated at a remote power plant is supplied to the industry and the home via distribution lines. However, since the electricity passing through the distribution line is transformed to a high pressure for efficient supply, if the distribution line is installed at a low position on the ground, an electric shock accident through the distribution line may occur.

Therefore, the distribution line is embedded in the ground or wired at a high position where the human hand does not reach through the strut.

FIG. 1 is a perspective view showing a distribution line connected to a support, and will be described with reference to FIG.

1, in order to wire the power distribution line 30 at a high position, struts 20 and 20 'supporting the power distribution line 30 are arranged at regular intervals, and the struts 20 and 20' and the power distribution lines 30 are connected via insulators 40 for insulation. Since the plurality of distribution lines 30 may be wired between the supports 20 and 20 ', the bridges 10 and 20' may be connected to the support posts 20 and 20 ' . ≪ / RTI >

The power distribution line 30 is made of a metal material having excellent conductivity and is expanded and contracted frequently according to the external temperature. Due to the large variation of the length of the power distribution line 30 between the adjacent power lines 30 and 20 ' Sagging may occur.

This sagging lowers the wiring position of the power distribution line 30, thereby increasing the possibility of electric shock of a person passing under the power distribution line.

In order to solve such a problem, conventionally, a large load (not shown) is provided at the end of the power distribution line so that the power distribution line 30 is prevented from being slackened so that it can always be maintained in a tense state. Stop.

However, such a conventional technique is utilized in a wiring structure for supplying electric power to a train or the like, and it is not preferable to apply it to an urban center or a residential area where human beings are concentrated, and it is not preferable in terms of aesthetics and efficiency. The length of the power distribution line is permanently increased, and the width of the power distribution line is relatively narrowed, thereby increasing the electrical resistance of the power distribution line.

It is an object of the present invention to provide a distribution line connection structure for preventing a sagging of a distribution line by reducing a length variation width of a distribution line provided between a support and a support, .

According to an aspect of the present invention, A disk having a shaft hole formed in the central portion, a groove formed in a long direction in the radial direction and having a groove formed with a groove for engaging with the inner surface and a guide formed to be curved around the shaft hole, a disk shaft inserted into the shaft, A disk having a guide groove formed along an axis and an outer circumferential surface, and a tube having a passage groove extending rearward at one end of the guide groove, A spring having a center end fixed to a rotating shaft, an end edge fixed to the shaft by being wound in one direction, and elastically supporting the disk so as to rotate in one direction; A stopper, one end of which is fixed to a fixed or rigid iron to limit the rotation angle of the disk within the range of the guide, and the other end is movably engaged with the guide; An insulator fixed to one end of the insulator and fixed to the other end of the insulator through the recess so as to be rotatable and movable; A first ring formed so as to movably penetrate through the guide groove so as not to be separated and to be separated from the guide groove so as to be fixed to the inner surface of the tube by hooking and inserting through the passage groove; A latch with a second collar; And a tension spring having one end fixed to the fixed body drawn out from the fixed base and the other end connected to the latch so as to elastically pull the latch.

According to the present invention, it is expected that the disk is rotated in accordance with the change of the length of the power distribution line, so that the power distribution line is always kept in tension.

Hereinafter, the present invention will be described in detail with reference to FIGS. 2 and 3 which are illustrated in the accompanying drawings.

FIG. 2 is a perspective view of a distribution line connection structure for preventing sagging according to the present invention, and FIG. 3 is an exploded perspective view of a distribution line connection structure for preventing sagging according to the present invention.

The upper end of the fixing table 100 is fixed to the bare iron 10 and the lower end of the fixing table 100 is formed with a tube-shaped rotary shaft 110 protruding forward. The rotary shaft 110 according to the present embodiment is integrally formed with the fixing table 100 but may be manufactured separately from the fixing table 100 and fixed to the fixing table 100 by various fixing means such as a bolt (not shown) and a nut ).

The disk 200 includes a disk 210, a shaft 220, and a tube 230. The disk 210 is formed with a shaft hole 211 passing through the central portion thereof and a groove 212 is formed to be long in the radial direction of the disk 210. On the other hand, a plurality of locking protrusions 212a are formed on the inner surface of the groove 212. A guide 213 is formed in the circular plate 210 so as to be curved around the shaft hole 211 at the outer periphery of the groove 212. The shaft 220 is inserted into the shaft hole 211 by inserting the rotating shaft 110 and the spring 300 and is fixed to the rotating shaft 110. Accordingly, the shaft 220 fixes the disk 210 so as to be rotatable about the rotation axis 110. The tubular body 230 has a shaft 220 disposed at the center thereof and is fixedly disposed on the rear surface of the circular plate 210 so as to surround the rotary shaft 110. A guide groove 231 is formed along the outer circumferential surface of the tube 230 and a through groove 232 is formed at one end of the guide groove 231 to extend rearward.

The spiral spring 300 is well known in the art and is also referred to as a spiral spring. The spiral spring 300 is formed by spirally winding a thin, long band-shaped, high-strength steel plate. The center of the spring 300 according to the present invention is fixed to the rotary shaft 110 and the edge of the spring 300 is wound clockwise to be fixed to the shaft 220. When there is no tension, Meanwhile, in the present invention, although the spring 300 is used, a torsion spring (not shown) may be used instead of the spring 300.

One end of the stopper 400 is fixed to the fixing base 100 or the wrought iron 10 and the other end thereof is movably engaged with the guide 213 to limit the rotation angle of the disk 200. That is, the stopper 400 stops the rotation of the disc 200 when the disc 200 is rotated clockwise or counterclockwise and reaches the end of the guide 213. In other words, if the stopper 400 is not provided, the length of the power distribution line 30 can not be efficiently adjusted because the disk 200 will continue to rotate past the optimum section for adjusting the length of the power distribution line 30. Therefore, by appropriately adjusting the length of the guide 213, it is possible to more effectively control the length of the power distribution line 30 within the range of the length of the guide 213. The stopper 400 according to the present invention is formed in a 'one' shape and fixed to the fixing table 100 in a threaded manner. However, the stopper 400 according to the present invention has a "B" shape and one end is fixed to the wrought iron 10, May be movably engaged with the guide 213.

The insulator fixing unit 500 includes a plurality of fixing plates 521, 522, and 523 that fix the moving axis 510 and the moving axis 510. The moving shaft 510 protrudes from the front surface and the rear surface of the circular plate 210 through the grooves 212. The first and second fixing plates 521 and 522 are installed on the moving shaft 510 protruding from the front surface and the rear surface of the circular plate 210 so that the first and second fixing plates 521 and 522 are in close contact with the groove 212, Prevent and ensure stable movement. The third fixing plate 523 is spaced apart from the second fixing plate 522 on the moving shaft 510 protruding from the rear surface of the circular plate 210 and is fixed in the tubular body 230 so as to be rotatable and movable.
The latch (600) has a first ring (610) and a second ring (620). The first ring 610 is formed so as to be movably passed through the guide groove 231 and is bent so as not to be separated so as to be fixed on the inner surface of the tube 230 and to be able to enter and exit through the passage groove 232. The second ring 620 extends from the first ring 610 and protrudes upward so as to catch the moving shaft 510. Therefore, the disc 200 is rotated in the counterclockwise direction, and the second ring 620 is positioned below the moving shaft 510 to hang the moving shaft 510.

One end of the tension spring 700 is connected to the clamp 600 and the other end of the tension spring 700 is connected to the clamp 600. The tension spring 700 is formed in a ' Possibly pulled back. Accordingly, when the disc 200 rotates counterclockwise, the first ring 610 moves along the guide groove 231, and when the disc 200 reaches the through groove 232, the tension spring 700 is elastically stretched to form the passage groove 232 to pull the latch 600 to the left. When the latch 600 is pulled to the left, the second hook 620 is positioned on the lower side of the moving shaft 510, so that the latch 600 pulls the engager fixing portion 500 to the left So that the tension of the power distribution line 30 is increased.

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Meanwhile, the fixed body (a) according to the present embodiment bends in a 'C' shape so that one end of the fixed body 100 is fixedly coupled to the fixed base 100 while the other end thereof is fixed to the tension spring 700, And the tension spring 700 may be fixed by being fixed to the barrel 10 at one end in a 1 'shape.

FIG. 4 is a front view sequentially illustrating an operation of a distribution line connection structure for preventing slack according to the present invention, and FIG. 5 is a rear view of a distribution line connection structure for preventing a sagging according to the sequence of FIG. And FIG. 6 is another front view sequentially illustrating an operation of a power line connection structure for preventing slack according to the present invention, and will be described with reference to FIG.

The spring 300 may be wound so as to have an appropriate elastic force so that the both ends of the spring 300 are connected to the rotating shaft 110 in the same manner as the tension of the power distributing line 30, And the shaft 220, respectively. At this time, the disc 200 has a plurality of grooves 212a formed in a long length in the radial direction and is fixed to the rotary shaft 110 so as to be directed upward with respect to the shaft hole 211, The insulator fixing part 500 is located at the edge of the circular plate 210 in the inside of the groove 212 across the latching protrusion 212a (FIGS. 4 and 5A).

In the present invention, the groove 212 has a plurality of latching protrusions 212a and is formed to be long from the central portion of the circular plate 210 to the edge in the radial direction. If the grooves 212 are formed only on the edge of the circular plate 210, the radius of the grooves 212 is increased by the rotation of the disk 200. However, since the distance is away from the center, It decreases. That is, when the power distribution line 30 is extended in a state where only the edge of the disk 210 is formed, the tension of the power distribution line 30 is small so that the elastic force of the spiral spring 300 is less than the load of the power distribution line 30, The disk 200 is rotated normally, but when the disk 200 is rotated for a predetermined interval, the power line 30 is pulled and the tension is increased. However, the groove 212 is formed at the edge of the circular plate 210, so that the load and the tension of the power distribution line 30 are larger than the elastic force of the spring springs 300. Therefore, although the disc 200 continuously rotates in the counterclockwise direction to pull the power distribution line 30, the groove 212 is provided at the edge of the disc 210, Can be stretched. On the other hand, when the groove 212 is formed only in the central portion of the circular plate 210, the force of pulling the electric distribution line 30 is increased and the disk 200 smoothly rotates, but the moving radius of the circular groove 212 becomes relatively small . Therefore, it is necessary to adjust the turning radius of the disk 200 and the degree of pulling the power line 30 according to the tension change of the power line 30. If the insulator fixing unit 500 is fixed in only one place as described above, There is a disadvantage in that it is impossible to adjust the degree of pulling the power distribution line 30. Therefore, even though the groove 212 is formed to be long in the radial direction, the insulator fixing part 500 moves from the edge of the circular plate 210 to the center part in response to the expansion of the power distribution line 30, . However, if the grooves 212 are formed only long, the insulator fixing part 500 is positioned at one of the edges or the central part of the disc 210 according to the rotation of the disc 200, As the tension changes, it becomes impossible to respond step by step. Therefore, when the plurality of latching protrusions 212a are reinforced in the groove 212 according to the present invention, as the tension of the power distribution line 30 is increased, the insulator fixing part 500 moves from the outside to the center of the disc 210 It is possible to move stepwise beyond the latching jaw 212a in accordance with the change of the tension, so that it is possible to effectively cope with a change in the tension of the power distribution line 30, thereby effectively pulling the power distribution line 30. [

When the temperature rises and the power distribution line 30 is expanded, the tension of the power distribution line 30 is reduced, and the balance of the elasticity of the spring springs 300 is broken, and the disk 200 is rotated in the counterclockwise direction. Meanwhile, the insulator fixing unit 500 moves toward the central portion of the disc 210 beyond the latching protrusion 212a in the groove 212 (FIGS. 4 and 5B).

Meanwhile, when the temperature of the power distribution line 30 is continuously increased, the disk 200 is rotated in the counterclockwise direction, and the stopper 400 is caught by the edge of the guide 213, ). 5). At this time, the insulator fixing part 500 is moved as close as possible to the center of the disk 210 in the groove 212 (FIG. 5C). 5C, the fact that the insulator fixing part 500 is moved as close as possible to the central part of the circular plate 210 inside the groove 212 means that the distribution line 30 has been sufficiently inflated , Most of the rotational force of the disk 200 concentrates on pulling the power distribution line 30, so that the power distribution line 30 is easily pulled, but the pulling degree is less and pulled less.

In order to solve this problem, in the present invention, a passage groove 232 is formed in the body 230. When the disk 200 is sufficiently rotated counterclockwise, the passage groove 232 is formed in the left . Then, the moving shaft 510 is placed in the upward direction of the second ring 620. The first spring 610 is moved to the left through the passage groove 232 and moved along the groove 212 to the edge of the center of the circular plate 210 4 and 5D), the power distribution line 30 is pulled further.

When the temperature drops and the tension of the distribution line 30 becomes larger than the tension of the tension spring 700, the insulator fixing part 500 is moved from the inside of the groove 212 to the center of the disk 210 4 and c in FIG. 5), the disk 200 is rotated in the clockwise direction when the tension is further increased due to the falling temperature.

When the temperature further falls, the expanded distribution line 30 is contracted and the elastic force and the tension are parallel to each other (Fig. 6 (a)).

6A to 6C, when the temperature further falls and the shrinkage of the power distribution line 30 is further accelerated, the tension of the power distribution line 30 becomes larger than the elastic force of the spring springs 300 The balance is broken and the disc 200 rotates clockwise (Fig. 6 (b)).

Finally, the disc 200 rotates clockwise as the power distribution line 30 shrinks, and stops rotating when the stopper 400 reaches the guide 213 (FIG. 6C).

Therefore, the sagging structure according to the present invention prevents sagging due to contraction and expansion of the power distribution line 30 by the stopper 400, the guide 213 and the groove 212, There is an advantage that the power distribution line 30 can be adjusted to a predetermined length.

It is needless to say that the present invention is not limited to the above-described embodiment, and various modifications may be made without departing from the scope of the following claims.

1 is a perspective view showing a distribution line connected to a support,

2 is a perspective view of a distribution line connection structure for preventing slack according to the present invention,

3 is an exploded perspective view of a distribution line connection structure for preventing sagging according to the present invention,

4 is a front view of a power line connection structure for preventing slack according to the present invention,

Fig. 5 is a rear view of Fig. 4,

6 is another front view of a distribution line connection structure for preventing sagging according to the present invention.

* Description of the main parts of the attached drawings *

10: Wanchul, 20, 20 ': holding,

30: front, 40: insane,

100: fixed base, 110: rotating shaft,

200: disk, 210: original plate,

211: football yoke, 212: groove,

212a: latching jaw, 213: guide,

220: axis, 230: tube,

231: Guide groove, 232: Through groove,

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300: spring-loaded spring, 400: stopper,

500: insulator fixing unit, 510: moving axis,

521: first fixing plate, 522: second fixing plate,

523: third fixing plate, 600: latch,

610: first ring, 620: second ring,

700: Tension spring, a: Fixture.

Claims (1)

A fixing table (100) fixed to the barrel (10) and having a rotation axis (110); A groove 212 formed in the central portion and a groove 213 formed in the radial direction so as to have an engagement surface 212a and a guide 213 formed to be curved around the shaft hole 211, A shaft 220 inserted into the shaft hole 211 and rotatably fixing the disc 210 about the rotary shaft 110, a guide groove 231 formed along the outer circumferential surface of the shaft 210, A disc 200 having a tube 230 having a through-hole 232 formed at one end thereof extending rearward and fixed to the disc 210 so as to surround the rotating shaft 110; A spiral spring 300 having a center end fixed to the rotating shaft 110 and an edge end fixed to the shaft 220 by being wound in one direction to elastically support the disk 200 to rotate in one direction; A stopper 400 fixed at one end to the fixing table 100 or the wrought iron 10 to limit the rotation angle of the disk 200 within the range of the guide 213 and the other end movably engaged with the guide 213; An insulator fixing part (500) fixed at one end of the insulator (40) and the other end penetrating the groove (212) and being rotatably and movably fixed within the tube body (230); A first ring 610 which is formed so as to be movably passed through the guide groove 231 so as not to be separated and which is formed to be able to be inserted and removed through the passage groove 232 by fixing the inner surface of the tube 230, (600) having a second annulus (620) extending from the second annulus (610) and detachably coupling the detent fixture (500); And a tension spring (700) having one end fixed to the fixed body (a) drawn out from the fixed base (100) and the other end connected to the clasp (600) to elastically pull the clasp (600) Distribution line connection structure.

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