KR100851432B1 - Suspend insulator for a power-transmission line - Google Patents

Abstract

A suspension insulator for a power transmission line is provided to improve convenience and safety for maintenance by minimizing drooping of the power transmission line. A suspension insulator(10) for a power transmission line includes a pylon coupling plate(11), an insulator(13), a tension control unit(20), and a clamp(60). The pylon coupling plate has bolt coupling holes(12) to be coupled to a pylon with bolts and includes a supporter for the insulator. The insulator is coupled to the supporter of the pylon coupling plate and includes a first socket clevis(14). The tension control unit is coupled to the first socket clevis, supports the clamp, and maintains tension between power transmission lines. The clamp is coupled to the tension control unit and clamps the power transmission lines.

Description

Suspension insulator for transmission and distribution tower {suspend insulator for a power-transmission line}

The present invention relates to a suspension insulator of a transmission and distribution steel tower, and more particularly, to provide a good wire support and insulation, and to minimize the sagging of the transmission line due to the tension change, thereby providing convenience and safety in maintenance. It is about the suspension insulator of the transmission and distribution steel tower which could improve.

Generally, the type of steel tower used as a support for transmission and distribution wires depends on the transmission, distribution power, voltage, and topography of the track, and the height is 60m. The main material is steel with L-shaped cross section. In many cases, the horizontal cross section is square, so the foundation is also hardened by concrete at the corners of the square.

Steel towers of transmission and distribution wires usually support three-phase, two-wire, or six wires with insulators. The distance between the pylons is 20 to 30 m, and the minimum height from the surface of the electric wires installed on the pylon is determined by the electric equipment technology, for example, 6 m for a 150,000 V track.

In general, when crossing a wide river or deep valley, the span is long, and thus the tension of the wire is increased, so a particularly strong structure is required. Even transmission lines are small, or iron poles built on a single foundation as a support for distribution or telephone lines.

These transmission and distribution steel towers connect a plurality of transmission and distribution wires to each other, and these wires are installed at high altitudes, and thus are subject to vibration or amplitude as they are subjected to climatic influences such as wind, snow, and rain. Installed under easy conditions. Therefore, after a certain period of time, the cable may sag and strong winds may cause the wires to shake violently up and down, causing friction between them. It became.

Therefore, conventionally, in order to solve such a problem, the maintenance work that periodically adjusts the tension of the transmission / distribution wire is performed to prevent the above-mentioned safety accident due to the sagging of the wire.

However, the above method has to be accompanied by a power cut, but due to the possible work, power generation generations have caused great inconvenience and originality, and there are safety problems due to failing to carry out maintenance work from time to time.

The present invention has been made in view of the conventional problems as described above, the object of which is to provide good wire support and insulation, and to minimize the sagging of the transmission line due to the tension change, convenience in maintenance To provide suspension insulators for transmission and distribution steel towers to improve performance and safety.

Suspension insulator of the transmission and distribution pylon according to the present invention is a steel tower bracket that can be fastened and fixed to the transmission and distribution tower, the insulator is coupled to the lower portion of the steel tower bracket and provided with a first socket crevis at the bottom, 1 is coupled to a socket crevis and the outer surface is finished with a polymer synthetic rubber is provided with a tension control unit and a transmission line clamp coupled to both sides of the tension control unit and capable of fixing the connection of the power transmission line.

Each of the tension control units may be hinged to one end of each of the first and second socket bars, the first and second extension bars extending inclined downward to face each other, and one end of each of the first and second extension bars. Elastic biasing of the third and fourth extension bars and the first and second socket crews, the other ends of which are hinged to the second socket crews so as to be mutually rotatable, respectively, and in a direction away from each other. And a turnbuckle installed between the first and second shock absorbers and the first and second shock absorbers for adjusting the separation distance of the first and second socket crevices, wherein the turnbuckles are provided at an upper end and a lower end. A body having a threaded fastening hole, respectively, and screwed to penetrate the fastening hole at the upper and lower ends of the body, respectively, the first and the second are the opposite direction of the formation of the thread And a second screw member, wherein the first and second shock absorbing portions extend from the first and second socket crews in opposite directions toward the turnbuckle, respectively, and are installed at end portions of the rod and have a predetermined internal space. A cylindrical member having an outer diameter corresponding to the inner diameter of the cylindrical member, the first and second screws protruding from the disk portion to the outside of the cylindrical member; It is preferable to include a projecting portion respectively connected to the member and a spring installed inside the cylindrical member to elastically bias the disc portion toward the turnbuckles, respectively.

The transmission line clamp has a semicircular arc shape and an upper base for crimping an upper portion of the transmission line, a pair of ratchet parts formed at both edges of one side of the upper base and having a plurality of teeth continuously, and the other side of the upper base. Upper binding unit portions each having a pair of first and second flanges formed at both edges of the upper edge and having pin holes, respectively, and forming a semicircular arc shape corresponding to the upper base, and the first and third connections of the tension control unit. A lower base connected to a coupling part of the bar, a coupling bracket fastened to the coupling part of the second and fourth connection bars, and crimping the lower part of the transmission line, and along one side of the lower base along a semicircular arc trajectory of the lower base. A pair of ratchet fixing parts each formed at both edges and each having a passage through which the ratchet part can be drawn out; Locking / unlocking means for locking or releasing the ratchet portion introduced into the lower base, and a lower binding unit having a third flange formed on the other side of the lower base and having a pinhole, the upper binding unit portion and the lower binding The unit portion is preferably formed to be coupled by a rotation pin that sequentially passes through the pinholes of the first flange, the third flange, and the second flange.

Suspension insulator of the transmission and distribution tower according to the present invention having the above configuration can be made to support the wires of the transmission line installed between the transmission and distribution towers, and minimize the sagging of the transmission line due to the tension change It has the effect of improving the convenience and stability of maintenance.

Hereinafter, with reference to the accompanying drawings will be described in more detail the suspension insulator of the transmission and distribution tower according to the present invention.

1 to 5, the suspension insulator 10 of the transmission and distribution pylon 10 is a steel tower bracket (11) fastened and fastened to the transmission and distribution tower, and the insulator (13) installed in the lower portion of the steel tower bracket (11) ), A transmission line clamp 60 coupled to the tension control unit 20 and the tension control unit 20 installed at the lower portion of the insulator 13 to clamp the power transmission line.

Pylon bracket 11 is screwed to the angle of the transmission and distribution of the steel tower is formed with a plurality of bolt coupling holes (12) to which the fixing bolt can be fastened and the support portion that can support the insulator (13) ( Not shown) is formed.

The insulator 13 is coupled to the support provided in the lower portion of the steel tower bracket 11 and extends a predetermined length downward of the steel tower for transmission and distribution. In addition, the lower end of the insulator 13 is provided with a first socket crevis 14 for coupling the tension control oil knit.

The tension control unit 20 is installed on the lower portion of the insulator 13 to support the transmission line clamp 60 to fix the transmission line and to maintain the tension of the transmission lines, the hinge is coupled to the first socket crevis 14 The first and second extension bars 21 and 22 and the third and fourth ends of which are hinged to the first and second extension bars 21 and 22, respectively, and hinged to each other by the second socket crevis 15. The extension bars 23 and 24, the first and second buffer parts 41 and 42 supported by the first and second socket crews 14 and 15, respectively, and the first and second buffer parts 41, It is provided between the 42 and the turnbuckle 30 to elastically bias the first and second socket crews 14, 15 in a direction away from each other.

One end of each of the first and second extension bars 21 and 22 is hinged to the first socket crevis 14 and the other ends thereof extend in opposite directions. The first and second extension bars 21 and 22 extend inclined downward as they extend from one end to the other end. It is.

One end of each of the third and fourth extension bars 23 and 24 is hinged to the other end of the first and second extension bars 21 and 22, and the other end is rotated by the second socket crevis 15. Possibly hinged.

Accordingly, the first to fourth extension bars 21, 22, 23, and 24 have a rhombus shape as a whole, and when the first and second socket crabs 14 and 15 have a narrower or farther distance apart along the vertical direction, It is combined to rotate by interlocking.

The turnbuckle 30 is intended to maintain a constant distance along the vertical direction of the first and second socket crews 14 and 15.

As described above, since the first to fourth extension bars 21, 22, 23, and 24 are hinged to interlock with each other, the hinge coupling portions of the first and third extension bars 21 and 23 may be connected to the first. When the hinge coupling portion of the coupling portion 25 and the second and fourth extension bars 22 and 24 is referred to as the second coupling portion 26, the first and second socket crews 14 and 15 may have a separation distance. When the first and second coupling parts 25 and 26 become narrower, the first and second sockets crevices 14 and 15 move away from each other, whereas the first and second coupling parts 25 and 26 move away from each other. The parts 25 and 26 are moved in the direction in which the separation distance approaches.

Thus, the separation distance of the first and second coupling parts 25 and 26 may be adjusted through the separation distances of the first and second socket crews 14 and 15, thereby moving the transmission line clamp 60 to be described later. The tension of the transmission line can be adjusted.

The turnbuckle 30 includes a body 31 having a fastening hole 32 having threads formed at upper and lower ends thereof, and a first screw threaded to the fastening hole 32 at upper and lower ends of the body 31, respectively. Second screw members 33 and 34 are included.

The fastening holes 32 are formed in the body 31 so as to extend in the vertical direction, and the threads in the inner circumferential surface of the fastening holes 32 are all formed in the same extending direction.

The first and second screw members 33 and 34 are screwed to the body 31 to extend in the vertical direction through the fastening holes 32 at the upper and lower ends of the body 31, respectively. The threads formed on the outer circumferential surfaces of the screw members 33 and 34 are opposite in their forming directions.

Accordingly, when the body 31 is rotated while the first and second screw members 33 and 34 are coupled to the body 31, the first and second screw members 33 and 34 face each other. As it progresses in the direction, the separation distance is closer or farther away.

The first shock absorbing portion 41 is installed between the upper end of the first screw member 33 and the first socket crevis 14 and extends from the first socket crevis 14 and the rod ( A cylindrical member 44 provided at an end of the cylinder 43, and a disc portion 45 and a spring 46 and a disc portion 45, which are installed inside the cylindrical member 44, extend outwardly of the cylindrical member 44. It includes a protrusion 47 to protrude.

The cylindrical member 44 has a predetermined internal space and a sliding hole (not shown) is formed at a lower end of the cylindrical member 44 to allow the protrusion 47 to be pulled in and out of the cylindrical member 44.

The disc portion 45 has an outer diameter corresponding to the inner diameter of the cylindrical member 44 and is formed to be elevated in a restrained state inside the cylindrical member 44.

Protruding portion 47 is installed to be pulled in and out from the cylindrical member 44 through the sliding hole of the cylindrical member 44 as described above, when the disk portion 45 is lowered, the protruding portion 47 is also lowered When the protruding length is increased from the cylindrical member 44, and the disc portion 45 is elevated, the protruding portion 47 is also raised and drawn into the cylindrical member 44. The outer diameter of the protruding portion 47 is formed to correspond to the inner diameter of the sliding hole so that it can be raised and lowered along the sliding hole, and the first screw member 33 of the turnbuckle 30 is connected to the end of the protruding portion 47. It is. For reference, the outer diameter of the first screw member 33 is formed relatively larger than the sliding hole so that the first screw member 33 is not drawn into the cylindrical member 44 by the first screw member 33 It is preferable that the lifting height of the disc portion 45 is limited.

One end of the spring 46 is supported inside the upper end of the cylindrical member 44, and the lower end is supported on the upper part of the disc part 45 so that the disc part 45 is elastically biased toward the turnbuckle 30.

The second shock absorbing portion 42 is installed between the second screw member 34 and the second socket crevis 15, the technical configuration and each function of the first shock absorbing portion 41 and the installation direction is different only. Since the same, detailed description is omitted.

Operation of the tension control unit 20 having the above configuration is as follows.

When the transmission line is gripped by the transmission line clamp 60, the distance between the first and second screw members 33 and 34 is increased or narrowed while rotating the body 31 of the turnbuckle 30 in one direction or the other direction. do. When the turnbuckle 30 is rotated as described above, the separation distance between the first and second socket crews 14 and 15 becomes far or narrow, and the first and second coupling parts 25 and 26 to which the power line clamp 60 is coupled. The separation distance of) is also narrowed or farther away, and thus the tension can be adjusted as the transmission line is pulled or loosened.

When the power transmission line is vibrated or pulled in one direction by an external force such as a strong wind, the first and second socket parts 41 and 42 are temporarily spaced apart from the first and second socket crews 14 and 15. As the distance becomes narrower, the external force applied to the transmission line is attenuated to reduce the risk of breakage of the transmission line. When the external force disappears, the separation distance between the first and second socket crews 14 and 15 by the spring 46 is increased. Restoring the initial state allows the transmission line to regain tension before external forces are applied.

The transmission line clamp 60 is for holding a transmission line and includes an upper binding unit part 100 and a lower binding unit part 200.

The upper binding unit part 100 includes a pair of upper bases 110 for crimping the upper portion of the power transmission line 3, an upper protection member 120 for protecting the cover of the power transmission line, and a pair of upper bases 110. A ratchet 130 and a pair of first and second flanges 140a and 140b formed on the other side of the upper base 110 are provided.

The upper base 110 forms a semicircular arc shape and compresses an upper portion of the transmission line 3 placed on the lower binding unit part 200. In this case, since the coating of the power transmission line 3 may be damaged by the compression of the upper base 110, the upper protection member 120 is attached to the inner surface of the upper base 110 in contact with the power transmission line 3 at a predetermined thickness. . The upper protection member 120 uses a rubber material having elasticity and the thickness of the rubber is thick so that the transmission line having various diameters can be compressed.

Both edges of one side of the upper base 110 are provided with a pair of ratchets 130. The ratchet part 130 is introduced into the ratchet fixing part 230 of the lower binding unit 200 and fastened and fixed by the locking / release means 300 to allow the upper base 110 to compress the power transmission line from the top. A plurality of teeth 135 are formed on the outer surface of the ratchet 130.

Both edges of the other side of the upper base 110 are provided with a pair of first flange 140a and a second flange 140b each having a pinhole. The first pin 150 is inserted into the first and second flanges 140a and 140b to allow the upper binding unit part 100 to be rotatable about the first pin 150.

In addition, since the ratchet 130 and the first and second flanges 140a and 140b are formed integrally with the upper base 110, the structure is simple and the assembly time can be greatly reduced.

Meanwhile, the lower binding unit part 200 is connected to the fastening bracket 16 fixed to the first and second coupling parts 25 and 26, respectively, and the lower base 210 for pressing the lower side of the power transmission line 3 on the inner side thereof. ), A lower protection member 220 for protecting the power transmission line 3, a pair of ratchet fixing parts 230 formed on one side of the lower base 210, and the ratchet part 130 is locked or released. Locking / releasing means 300, and the third flange 240 is formed on the other side of the lower base (210).

The lower base 210 forms a semicircular shape corresponding to the upper base 110. The lower base 210 is connected to the tension control unit 20 by a fastening bracket 16 coupled to the first and second coupling parts 25 and 26 as described above. The lower base 210 is located at the lower portion of the transmission line to be crimped below the transmission line. In this case, since the transmission line may be damaged, the lower base member 210 is attached to the inner surface of the lower base 210. The lower protective member 220 uses a rubber material similarly to the upper protective member 120.

And a pair of ratchet fixing portion 230 is formed along the semicircular trajectory on both edges of one side of the lower base 210. The ratchet fixing part 230 has a passage formed at a predetermined depth therein, and the ratchet fixing part 230 enters the passage of the ratchet fixing part 230 when the power transmission line 3 is bound and terminates the binding. ) Is withdrawn from the passage. On one side of the ratchet fixing part 230, the latching piece 310 of the locking / release means 300 may be in contact with the teeth 135 of the ratchet part 130 introduced into the ratchet fixing part 230. A passage of the fixing part 230 and a through hole are formed.

Locking / releasing means 300 is installed on one side of the ratchet fixing portion 230 is formed through the groove.

The locking / release means 300 includes a locking piece 310 having a pole 313 formed thereon, an elastic member elastically biasing the locking piece 310, and a locking piece 310 pivotally coupled to the ratchet fixing part 230. The second pin 330 is provided.

The catching piece 310 prevents the ratchet part 130 introduced into the ratchet fixing part 230 from retreating from the ratchet fixing part 230. One side of the locking piece 310 is formed with a pawl 313 corresponding to the teeth 135 to be engaged with the teeth 135 of the ratchet 130.

And the torsion spring 320 is used as the elastic member. In addition, the spring or spring may be used as the elastic member. The torsion spring 320 is fixed by the second pin 330 to apply a force from the front to the rear of the locking piece 310. Therefore, when the power supply line is engaged, when the ratchet part 130 is introduced into the passage of the ratchet fixing part 230, the torsion spring 320 applies a force to the locking piece 310 so that the pole 313 is the teeth 135 of the ratchet part 130. ) To prevent the ratchet 130 from retreating. And upon release, the latching portion 310 may be pulled out to simply pull out the ratchet 130 from the ratchet fixing part 230.

The second pin 330 is fitted into the groove of the protrusion 340 of the ratchet fixing part 230 to pivotally couple the catching piece 310 and the torsion spring 320 to the ratchet fixing part 230. In addition, the split pin 335 is fastened to the hole formed at the longitudinal end of the second pin 330 to prevent the second pin 330 from being separated.

In addition, screwing holes 315 and 355 may be formed on the other side of the catching piece 310 and a part of the ratchet fixing part 230 corresponding thereto. This further reinforces the force applied by the elastic member 320 to the locking piece 310 so that the ratchet 130 is more firmly bound when the transmission line is fastened. Therefore, the screw 350 is inserted in the direction of the locking piece 310 to be tightened by tightening the screw coupling hole 355 of the ratchet fixing part 230.

On the other hand, the other side of the lower base 210 is formed with a third flange portion 240 having a pinhole.

The third flange part 240 is positioned in a straight line between the first flange 140a and the second flange 140b of the upper binding unit 100. Therefore, the first pin 150 is inserted into the first flange 140a and is inserted through the third flange 240 and the second flange 140b in order. In addition, the split pin 155 penetrates through the hole formed at the end of the first pin 150 to prevent the first pin 150 from being separated. In addition, although not shown, the pin may be fastened to the end of the first pin 150 using a snap ring or the like.

The ratchet fixing part 230 and the third flange part 240 are integrally formed on the lower base 210.

The above-described transmission line clamp 60 can be easily connected to the transmission line without a separate tool, because the separation of the transmission line can be made simply so that the operator can quickly and simply perform the fastening and disconnection of the transmission line in the air help.

1 is a perspective view showing an embodiment of a suspension insulator of a transmission and distribution steel tower according to the present invention,

Figure 2 is a partially cut perspective view of the tension control unit,

3 is an exploded perspective view showing a transmission line clamp;

4 is an exploded perspective view of the locking / release means of the power line clamp;

5 is a cross-sectional view showing the ratchet portion of the transmission line clamp is fixed to the ratchet fixing portion by the locking / unlocking means.

Claims (2)

Steel tower brackets capable of fastening and fixing to transmission and distribution steel towers; An insulator coupled to a lower portion of the pylon bracket and provided with a first socket crevis at a lower end thereof; A tension control unit coupled to the first socket crevis and having an outer surface finished with a polymer synthetic rubber; And And a transmission line clamp coupled to both sides of the tension control unit and capable of fixing a connection of the transmission line. Each of the tension control units may include first and second extension bars which are inclined downwardly so that one end is hinged to the first socket crevis and is opposed to each other; Third and fourth extension bars of which one end is hinged to the other end of the first and second extension bars, and the other end is hinged to the second socket crevis so as to be rotatable with each other; First and second buffer parts respectively supported by the first and second socket crews and configured to elastically bias the first and second socket crews in a direction away from each other; A turnbuckle installed between the first and second shock absorbing parts to adjust a separation distance between the first and second socket crews; The turnbuckle is a body having a fastening hole having a thread formed at the top and a bottom thereof, respectively, and screwed to penetrate the fastening hole at the upper and lower ends of the body, respectively, wherein the first and second screw members are opposite to each other. Has, The first and second shock absorbing portions extend from the first and second socket crews in opposite directions toward the turnbuckle, a cylindrical member installed at an end of the rod and having a predetermined internal space; A disc portion which is provided to be movable up and down inside the cylindrical member and has an outer diameter corresponding to the inner diameter of the cylindrical member, and protrudes from the disc portion to the outside of the cylindrical member to be connected to the first and second screw members, respectively. Suspension insulator of the transmission and distribution steel tower, characterized in that it comprises a spring which is provided inside the portion and the cylindrical member to elastically bias the disc portion toward the turnbuckle respectively. The method of claim 1, The transmission line clamp has a semicircular arc shape and an upper base for crimping the upper portion of the transmission line, a pair of ratchet parts formed at both edges of one side of the upper base and having a plurality of teeth continuously, and the other side of the upper base. An upper binding unit portion formed at both edges and having a pair of first and second flanges each having a pinhole, A semi-circular arc shape corresponding to the upper base and connected to the coupling portion of the first and third connection bars of the tension control unit and the coupling brackets coupled to the coupling portion of the second and fourth connection bars and the lower portion of the transmission line A pair of ratchet fixing parts each formed on both edges of one side of the lower base along a semicircular trajectory of the lower base and having passages through which the ratchet part can be drawn out, and the ratcheting A lower binding unit having a locking / release means for locking or releasing the ratchet portion introduced into a passage of the government, and a third flange formed on the other side of the lower base and having a pinhole; The upper binding unit part and the lower binding unit part is a suspension insulator of a transmission and distribution steel tower, characterized in that coupled by the rotation pin penetrating through the pin hole of the first flange, the third flange and the second flange.

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