KR101903601B1 - Distribution line connect structure for steel tower - Google Patents

Abstract

The present invention relates to a power distribution type joint structure for a distributed overhead power distribution line of an iron tower, which provides good line supporting and insulation and minimizes sagging of the power transmission line due to a change in tension. Moreover, even if the power transmission line is twisted, the power transmission line is restored to an original state, convenience and safety in maintenance are improved. When a situation that a function of a rotational member having a restoration function is not normally worked occurs in twisting of the power transmission line, the situation is instantaneously indicated to the outside and is quickly informed to a remote integrated control center to be managed. Moreover, when the power transmission line is vertically moved, the shock thereof is mitigated such that durability is reinforced and stability of an electric connection state is enhanced. According to the present invention, the power distribution type joint structure for a distributed overhead power distribution line of an iron tower, which includes an iron tower fitting, a suspension insulator, the rotational member, and an extension member, comprises a spring tension detection means, a wireless communication module, and a vertical shock absorption means.

Description

{Distribution line connect structure for steel tower}

The present invention provides good wire support and insulation among distribution technology fields, minimizes sagging of transmission line due to tension change, restores to its original state even when twisted on transmission line, In addition, when a situation in which the function of the rotating member having the restoration function at the time of twisting of the transmission line is not normally exhibited, the fact is immediately displayed on the outside, and it is quickly known to the remote control center And to improve the durability and the stability of the electrical connection state by mitigating the shock when the power line is moved up and down.

Generally, the shape of a steel tower used as a support for a transmission line varies depending on the transmission power, voltage, and topography of the line, and may be as high as 60 meters.

The pylon of the transmission line usually supports three phases, two lines, ie six wires.

The distance between the pylons is 20 to 30 meters, and the minimum height from the surface of the wires installed on the pylons is defined by the electrical equipment technology, for example, 6 m for a 150,000 V line.

Generally, a strong structure is required when a railway crosses a wide river or a deep valley, because the span is long and therefore the tension of the wire increases.

Even the transmission line is small or there is a pillar built on a single foundation as a support for power lines or telephone lines.

The steel towers for transmission lines connect a plurality of transmission lines to each other. These transmission lines are installed under conditions where vibrations or amplitudes are likely to occur as they are subjected to climatic influences such as wind, snow, .

Therefore, when a certain period of time has elapsed, the transmission line is sagged. In case of strong winds, the transmission lines are shaken up and down severely to cause friction between each other, and also cause large safety accidents such as short-

Korean Unexamined Patent Publication No. 10-0904199 (Jun. 16, 2009) discloses a fixing structure of a suspending insulator for a transmission tower with a transmission line.

However, in the case of the above-described " fixing structure of suspending insulator for steel tower with transmission line ", when the elastic spring of the rotating member is abnormal, the rotating member can not exhibit the function of preventing the transmission line from being twisted. However, There was no other way but to open it and confirm it.

In addition, as the force of the power transmission line is transmitted to the elongated member, the rotating member, the insulator, and the steel tower metal as the power transmission line is vertically moved by the wind or the like, the connection portion between the corresponding structures rapidly relaxes or the electrical connection state of the transmission line becomes poor. .

Korean Registered Patent No. 10-1801158 (published on November 28, 2017), "Fixed structure in a steel tower of a power transmission line for transmission and distribution" Korean Registered Patent No. 10-0904199 (June 22, 2009), "Fixed Structure of Suspension Insulator for Steel Tower by Transmission Line"

The embodiment of the present invention provides good wire support and insulation, minimizes the sagging of the transmission line due to the change in tension, restores the original state even when the transmission line is twisted, In addition, when a situation where the function of the rotating member having the restoration function at the time of twisting of the transmission line is not normally exhibited, the fact is immediately displayed on the outside, and can be promptly informed to the remote control center And provides a power distribution type power distribution line connection structure of a steel tower that can improve the durability and the stability of the electrical connection state by relieving the impact when the power transmission line is moved up and down.

A power distribution type power distribution line connection structure of a steel tower according to an embodiment of the present invention includes a steel tower metal fitting 2 fixed to a steel tower 1 of a transmission line and a suspending insulator 3 connected to a lower portion of the steel tower metal fitting 2 A fixing protrusion 111 having a hole 111a to be fixed to the socket crevice 4 of the suspending insulator 3 and a plurality of rings 112 having a hole 112a at its rim And a pair of guides 121a are formed on the bottom 121 so as to be opposed to each other. The bottom of the guide 121a is provided with a fixing collar A stepped portion 123 having a through hole 123a is formed at the center of the bottom and an insulating cover 11 is formed at the rim of the stepped portion 123. [ An insulating pedestal 12 formed with a plurality of rings 124 to be fastened by the bolts 112 and the bolts a and n, A support portion 132 is formed which is rotatably mounted on the step portion 123 in a state where a rotation shaft 131 inserted into the through hole 123a and penetrating to the lower portion is formed at the lower portion and an O- And a rotation bar 133 having a fastening ring 133a on the end of which the fastening ring 122a formed at the other end of the elastic spring 122 is inserted is integrally formed with the head 134 And a fixing bolt 211 is fastened to the inner circumferential surface of the inner circumferential surface of the inner circumferential surface of the inner circumferential groove 131a formed at the lower end of the rotary shaft 131 And the elastic spring 23 is inserted into the insertion hole 221 of the elastic high stage 22 in the inside of the hollow box-shaped insulation box 21 having the inside and the front and rear sides forming the opening 212 The retaining ring 231 of the elastic spring 23 protrudes from both ends of the elastic high stage 22 while the protruding retaining ring 231 protrudes from both ends of the elastic high stage 22, A pair of fastening holes 251 are formed on the upper and lower sides of the insulated power transmission line clamp 25, and a pair of fastening holes 241 are formed on the upper and lower sides of the insulated power transmission line clamp 25, (24) of the insulating cap (24) on both sides of the stretching member (20) and an insulating cap (24) having two pairs of insulating caps (24) And a jumper wire (5) for electrically connecting power transmission lines (100) connected to each other via a transmission line clamp (25), characterized in that in the power transmission type power distribution line connection structure of a steel tower, Is provided on one surface of one end of the rotary bar 133, on which the fastening ring 133a of the rotary bar 133 is formed, so as to rotate in conjunction with rotation of the guide shaft 133, The first pressure sensor (121a) is installed so that one end of the one guide (121a) 31; And the other end of the rotation bar 133 is disposed on the other side of the rotation bar 133 so as to face the first pressure sensor 31 about one end of the rotation bar 133, 121a are provided so as to overlap one another in the longitudinal direction of the other one of the guides 121a so that when a rotational force in a direction parallel to the stretching member 20 is not applied to the rotating bar 133, A second pressure sensor (32) held in contact with one longitudinal end of the guide (121a) overlapping the point; A wind speed sensor 33 installed on the outer surface of the insulating cover 11 to detect the wind speed of the surroundings; A wind direction sensor 34 installed on the outer surface of the insulation cover 11 to sense the wind direction around the wind direction sensor 34; The time when the rotation bar 133 is rotated in a direction parallel to the stretching member 20 and the time when the second pressure sensor 32 is in contact with the first direction of the guide, Time information indicating a time difference between a time when the first pressure sensor 31 is contacted with one end in the longitudinal direction of another guide positioned in the rotational direction of the rotary bar in accordance with the rotation of the rotary bar, A threshold time for determining whether the elastic force of the elastic spring 122 in the insulation pedestal 12 is abnormal or not is set based on the wind velocity information and the wind direction information sensed by the wind direction detection sensor 34, 34 is a direction in which the wind direction detected by the wind speed sensor 33 is rotated in the direction in which the rotation bar 133 is aligned with the stretching member 20, A tensile force abnormality determination unit (35) for determining an abnormality of the elastic spring (122) in the insulation pedestal (12) and outputting an abnormal signal when the time information is shorter than the predetermined threshold time ); A control unit 36 for outputting a control signal to the connected abnormality display unit 37 when an abnormality signal for the tensile force of the elastic spring 122 in the insulating pedestal 12 is inputted from the tensile force abnormality determination unit 35; The spring tension detecting means 30 including the abnormality display portion 37 which operates according to the control signal of the controller 36 to notify the outside that an abnormality has occurred in the tensile force of the elastic spring 122 in the insulating pedestal 12, And a wireless communication module (40) installed on the outer surface of the insulating cover (11) for wirelessly transmitting the abnormal signal outputted through the tensile force abnormality determination unit (35) so as to be received by a remote control center , Wherein the fixing protrusions (111) formed in the insulating cover (11) are formed in a long shape along the vertical direction, the holes (111a) are in the form of elongated holes along the vertical direction, The socket crevice 4 of the socket 3 is formed in a long shape along the vertical direction and a bolt coupling hole 4a corresponding to the hole 111a of the fixing protrusion 111 is formed at the lower end, ) Are provided for each corner area, and the length A plurality of fixing pipes 51, one end of which is coupled to a lower surface of the steel pillar 2, the other end of the pillar extends downward in the vertical direction, and the lower end is opened; A plurality of elastic members (52) installed inside the corresponding fixing pipe (51) for each of the fixing pipes (51) to exert elasticity along the vertical direction; One end in the longitudinal direction is inserted through the lower end of the fixed pipe 51 for each fixing pipe 51 and the other end in the longitudinal direction is coupled to the upper surface of the insulating cover 11, (50) including a vertically movable bar (53) to which a restoring force in a downward direction is applied by the elasticity of the vertically movable bar (52).

According to the embodiments of the present invention, it is possible to minimize the sagging of the transmission line due to a change in tension, to provide good wire support and insulation, and to restore the original state even when twist occurs in the transmission line, Safety and the like can be improved. On the other hand, when the function of the rotary member having the restoration function when the transmission line is twisted can not be normally exhibited, the fact is immediately displayed on the outside and the remote control center is promptly informed Thereby relieving the shock when the power line is vertically moved, thereby enhancing the durability and the stability of the electrical connection state.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view illustrating a power distribution type power distribution line connection structure of a steel tower according to an embodiment of the present invention;
FIG. 2 is a perspective view illustrating a power distribution type processing distribution line connection structure of a steel tower according to an embodiment of the present invention in a disassembled state; FIG.
3 is a side view illustrating a power distribution type processing power distribution line coupling structure of a steel tower according to an embodiment of the present invention;
4 is a side cross-sectional view illustrating a power distribution type processing distribution line connection structure of a steel tower according to an embodiment of the present invention;
5 is a diagram illustrating an operating state of a power distribution type processing power distribution line coupling structure of a steel tower according to an embodiment of the present invention;
FIG. 6 is a plan view illustrating the installation state of the rotary member before the operation of the power distribution type power distribution line connection structure of the steel tower according to the embodiment of the present invention. FIG.
7 is a cross-sectional view illustrating a mounting state of the rotary member after operation of a power distribution type processing power distribution line connection structure of a steel tower according to an embodiment of the present invention;
8 is a view illustrating a state in which spring tensile force sensing means is installed on a rotating member in a power distribution type processing power distribution joint structure of a steel tower according to an embodiment of the present invention
Fig. 9 is a block diagram of the spring tension detecting means according to the embodiment of Fig. 8
10 is a perspective view illustrating a state in which a vertical buffering means is installed in a power distribution type processing power distribution line connection structure of a steel tower according to an embodiment of the present invention;
11 is a side view illustrating a state in which a vertical buffering means is installed in a power distribution type processing power distribution line connection structure of a steel tower according to an embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It is also to be understood that the position or arrangement of the individual components in each described embodiment may be varied without departing from the spirit and scope of the present invention.

The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which the claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Also, in certain cases, there may be a term selected arbitrarily by the applicant, in which case the meaning thereof will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term, not on the name of a simple term, but on the entire contents of the present invention.

Whenever an element is referred to as " including " an element throughout the description, it is to be understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise. In addition, the term " "... Module " or the like means a unit for processing at least one function or operation, which may be implemented in hardware or software, or a combination of hardware and software.

1 to 11, a description will be given of a distribution type processing power distribution line coupling structure of a steel tower according to an embodiment of the present invention.

1 to 7, a description will be given of a power distribution type processing power distribution line coupling structure of a steel tower according to an embodiment of the present invention.

FIG. 1 is a perspective view illustrating a power distribution type power distribution line connection structure of a steel tower according to an embodiment of the present invention. FIG. 2 is a perspective view illustrating a power distribution type power distribution line connection structure of a steel tower according to an embodiment of the present invention, FIG. 3 is a side view illustrating a power distribution type power distribution line connection structure of a steel tower according to an embodiment of the present invention, and FIG. 4 is a perspective view illustrating a power distribution type power distribution line connection structure of a steel tower according to an embodiment of the present invention. And FIG. 5 is a view illustrating an operating state of a power distribution type power distribution line joint structure of a steel tower according to an embodiment of the present invention, and FIG. 6 is a view illustrating an operation state of a power grid type power distribution line of a steel tower according to an embodiment of the present invention, FIG. 7 is a cross-sectional view illustrating an installation state of the rotary member before the operation of the rotary member in the joint structure. It is a flat cross section.

As shown in the drawings, a power distribution type power distribution line connection structure of a steel tower according to an embodiment of the present invention includes a steel tower metal fitting 2 which can be fastened and fixed to a steel tower 1 of a transmission line, The present invention relates to a distribution type processing power distribution line connection structure of a steel tower installed in a transmission tower in such a manner that a suspending insulator 3 is connected to a lower portion of a power transmission line 2 and a jumper wire 5 is connected to a spaced transmission line 100.

The present invention mainly comprises a rotating member 10 and an extending member 20 including an insulating cover 11, an insulating pedestal 12 and an insulating rotating body 13, The elongate member 20 is finished with polymeric synthetic rubber for insulation.

The insulating cover 11 is formed with a fixing protrusion 111 having a hole 111a to be fixed to the socket crevice 4 of the suspending insulator 3 and has a hole 112a at its rim and a semicircular A plurality of rings 112 are formed. The bolts a are passed through the holes 111a of the fixing protrusions 111 and the holes formed in the socket crevices 4 and fixed with nuts b.

The insulating pedestal 12 is hollow and has a pair of guides 121a facing the bottom 121. A fixing ring 121b is formed at one side of the bottom of the guide 121a, And a hole 123a is formed at the center of the bottom of the hole 122a and a hole 123a formed in the hole 112 of the insulating cover 11 A plurality of rings 124 having holes 124a to be fastened with bolts (a) and nuts (b) are formed on the upper and lower plates 112a and 112a.

The insulating rotation body 13 has a rotary shaft 131 inserted into the through hole 123a of the insulating pedestal 12 and penetrating to the lower portion thereof and a lower jaw portion 123 with an O- A locking ring 133a for locking the locking ring 122a formed at the other end of the elastic spring 122 is provided on the upper portion of the receiving ring 132. The locking ring 133a, And a head 134 formed integrally with the rotation bar 133.

6 and 7, a locking ring 133a is formed on one side of the end portion of the rotating bar 133 so that the locking ring 122a formed at the other end of the elastic spring 122 is fitted, On the other side of the end of the bar 133, a locking ring 133a is formed on the rear surface, and a locking ring 122a formed at the other end of the elastic spring 122 is fitted.

In this case, when the transmission line is shaken or twisted by the wind, the shaking is transmitted to the insulated transmission line clamp 25 and the insulation box 21, which are fastened to the transmission line 100, When the rotating body 13 rotates in the clockwise direction, that is, in the direction of the solid line as shown in FIG. 7, the resilient force of the elastic spring 122 prevents the twist of the transmission line due to the restoring force in the dotted line direction It is effective.

6, when the insulated rotation body 13 rotates counterclockwise, the end of the insulated rotation body 13 is caught by the guide 121a to prevent the rotation thereof, thereby preventing the rotation of the insulated rotation body 13 due to twisting or rotation of the transmission line 100 It is possible to prevent accidents such as disconnection.

The extension member 20 is formed with a fixing bolt 211 at an upper portion thereof so as to be fastened to a thread provided on the inner circumferential surface of the inner groove 131a formed at the lower end of the rotary shaft 131 formed in the insulating rotation body 13, And the elastic spring 23 is inserted into the inserting hole 221 of the elastic high stage 22 in the inside of the hollow box-shaped insulated box 21 inside.

Here, the retaining ring 231 of the elastic spring 23 protrudes from both ends of the elastic high stage 22, while a pair of retaining rings 241, to which the protruding retaining ring 231 is engaged, And a fastener 251 having a pair of holes 251a formed at upper and lower portions of the insulated power line clamp 25 is formed on the outer side of the insulated power line clamp 25 and a fastener 242 having holes 242a at upper and lower portions thereof. And an insulating cap 24 which is fastened with bolts (a) and nuts (b).

As described above, the present invention provides good wire support and insulation, minimizes the sagging of the transmission line due to a change in tension, restores the original state even when twisting occurs in the transmission line, do.

Hereinafter, some additional configurations and their operation in a power distribution type power distribution joint structure of a steel tower according to an embodiment of the present invention will be described with reference to FIGS. 8 to 11. FIG.

8 is a view illustrating a state in which a spring tension sensing means is installed on a rotary member in a power distribution type power distribution connection structure of a steel tower according to an embodiment of the present invention. FIG. 9 is a diagram illustrating a spring tension force Fig.

As shown in the drawings, in the power distribution type power distribution joint structure of the steel tower according to the embodiment of the present invention, the spring tension sensing means 30 is installed on the rotary member 10.

The spring tension detecting means 30 includes a first pressure sensor 31, a second pressure sensor 32, a wind speed sensor 33, a wind direction sensor 34 and a tension abnormality determination unit 35, a control unit 36 And an abnormality display unit 37. [0034]

The first pressure sensor 31 is provided at one end of one end surface of the rotation support member 13 where the fastening ring 133a of the rotation bar 133 is formed so as to be rotated in conjunction with rotation of the rotation bar 133 in the insulating base 12 of the rotation member 10. [ Respectively. At this time, the first pressure sensor is installed such that one end of the guide 121a of the pair of guides 121a of the insulating pedestal 12 is overlapped with one end of the rotation locus.

The second pressure sensor 32 is installed on the other surface of the rotation bar 133 so as to face the first pressure sensor 31 about one end of the rotation bar 133. [ At this time, the second pressure sensor 32 is installed such that one end of the guide 121a of the other one of the pair of guides 121a of the insulating pedestal 12 is overlapped with one end of the rotation locus of the second pressure sensor 32, When the rotational force in the direction of being parallel to the stretching member 20 is not applied to the shaft 133, it is held in contact with one end in the lengthwise direction of the guide 121a which overlaps with any one point of the rotational locus.

The wind speed sensor 33 is installed on the outer surface of the insulating cover 11 of the rotary member 10 to sense the wind speed around the wind turbine.

The wind direction sensor 34 is installed on the outer surface of the insulating cover 11 of the rotary member 10 to sense the surrounding wind direction.

The tensile force abnormality determination unit 35 determines that the second pressure sensor 32 is rotating while the rotation bar 133 included in the insulating rotation body 13 of the rotary member 10 is rotated in the direction to be parallel to the stretching member 20 The first pressure sensor 31 is moved in the direction of rotation of the rotation bar 133 in accordance with the time when the guide 121a is in contact with the guide 121a and the rotation of the rotation bar 133 Based on the time information indicating the time difference between the time of contact with one end in the longitudinal direction, the wind velocity information sensed through the wind speed sensor 33 and the wind direction information sensed through the wind direction sensor 34, A critical time for determining whether the elastic force of the elastic spring 122 in the insulating pedestal 12 is abnormal or not is set.

Accordingly, the tension abnormality determination unit 35 determines that the wind direction detected by the wind direction sensor 34 is the wind direction that rotates the rotation bar 133 in the direction to be parallel to the stretching member 20, And outputs an abnormal signal when it is determined that the time information is shorter than a predetermined threshold time and is greater than a tensile force of the resilient spring 122 in the insulating pedestal 12.

The control unit 36 outputs a control signal to the connected abnormality display unit 37 when an abnormality signal for the tensile force of the elastic spring 122 in the insulating pedestal 12 is inputted from the tensile force abnormality determination unit 35. [

The abnormality display unit 37 operates in accordance with the control signal of the control unit 36 to inform the outside that an abnormality has occurred in the tensile force of the elastic spring 122 in the insulating pedestal 12. [ Although the present invention is not limited to this, the abnormality display unit 37 may be configured such that the tension of the elastic spring 122 in the insulating pedestal 12 is abnormal Various configurations may be used within a range that satisfies the condition of informing the outside that the occurrence of the failure has occurred.

Further, an abnormal signal of the tensile force of the elastic spring 122 in the insulating pedestal 12 outputted through the tensile force abnormality determination unit is transmitted to the remote control center through the wireless communication module 40.

That is, the wireless communication module 40 wirelessly transmits the abnormal signal outputted through the tensile force abnormality determination unit 35 so that the abnormal signal can be received by the remote control center at a remote location. Is provided on the outer surface of the insulating cover (11) of the member (10).

The elastic tension of the elastic spring 122 provided in the insulating pedestal 12 of the rotary member 10 is abnormally generated due to various reasons such as the elapse of the use period by the spring tension detecting means 30 described above, When a situation occurs in which the function of the member 10 can not be normally exhibited, the fact is displayed on the outside of the rotary member 10 and is quickly known to the remote control center at a remote location, And follow-up measures such as the facts and replacement thereof can be carried out rapidly.

And FIG. 10 is a perspective view illustrating a state in which a vertical buffering means is installed in a power distribution type processing power distribution line connection structure of a steel tower according to an embodiment of the present invention. FIG. 11 is a perspective view Fig. 8 is a side view illustrating a state in which a vertical buffering means is installed in a distribution line connection structure. Fig.

As shown in the drawings, a power distribution type power distribution line connection structure of a steel tower according to an embodiment of the present invention further includes a vertical direction buffering means 50.

Before the vertical buffering means 50 is described, the fixing protrusions 111 formed on the insulating cover 11 of the rotary member 10 are formed in a long shape along the vertical direction, The socket crevices 4 of the suspending insulator 3 are formed in a long shape along the vertical direction and the fixing projections 111 of the insulating cover 11 And a bolt coupling hole 4a corresponding to the hole 111a of the bolt hole 111a is formed.

The vertical direction buffering means 50 includes a fixing pipe 51, an elastic member 52, and a vertical movable bar 53.

The fixing pipes 51 are provided in the corner areas of the lower surface of the steel tower metal fitting 2 and one end of each of the fixing tubes 51 in the longitudinal direction is provided on the lower surface of the steel metal fitting 2 And the other end in the longitudinal direction extends downward in the vertical direction and is formed into a hollow shape with the lower end thereof opened.

The elastic member 52 is installed to exert elasticity along the vertical direction inside the corresponding fixing pipe 51 for each fixing pipe 51.

Each of the upper and lower movable bars 53 is inserted into one end in the longitudinal direction through the lower end of the corresponding fixed tube 51 and the other end in the longitudinal direction is inserted into the upper and lower movable bars 53 Is coupled to the upper surface of the insulating cover (11). The upper and lower movable bars 53 are installed in a state in which a restoring force in a downward direction is exerted by the elasticity of the elastic member 52 in the fixing pipe 51. [

When the power transmission lines connected to both sides of the stretching member 20 are vertically moved by the wind and the rotating member 10 is formed on the fixing projections 111 of the insulating cover 11 The rotary member 10, the suspending insulator 3, and the elastic member 60 can be moved in the vertical direction by the length of the hole-like hole 111a, The impact due to the up-and-down flow of the transmission line transmitted to the steel tower metal fitting 2 can be greatly reduced, which results in enhancing the durability of the structures and improving the stability of the electrical connection state.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments or constructions. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all the equivalents or equivalents of the claims, as well as the claims set forth below, fall within the scope of the present invention.

1: Pylon 2: Pylon
3: Suspension Insulator 4: Socket Crevice
10: rotating member 11: insulating cover
12: Insulation pedestal 13: Insulated rotating body
14: o-ring 20: elongated member
21: Insulation box 22: Elastic high stage
23,122: Elastic spring 24: Insulation cap
25: Insulated transmission line clamp 30: Spring tension sensing means
31: first pressure sensor 32: second pressure sensor
33: wind speed sensor 34: wind direction sensor
35: tensile force abnormality determination unit 36:
37: abnormality display unit 40: wireless communication module
50 vertical buffer means 51 fixed pipe
52: elastic member 53: vertical movable bar
121a: Guide 121b, 241: Fixing ring
122a, 231: a hook ring 123:
123a: Through hole 131:
131a: inner groove 132:
133: rotation bar 133a: fastening ring
134: Head 211: Fixing bolt
212: opening 221: insertion hole
242,251: fastener a: bolt

Claims (1)

A steel tower fixture (2) fixedly installed on a steel tower (1) of a transmission line:
A suspension insulator 3 connected to a lower portion of the steel tower metal fitting 2;
A fixing protrusion 111 having a hole 111a is formed to be fixed to the socket crevice 4 of the suspending insulator 3 and a plurality of rings 112 having a hole 112a are formed at the rim, An insulating cover (11) finished with a polymeric synthetic rubber; A pair of guides 121a are formed on the bottom 121 so as to be opposed to each other and a fixing ring 121b is formed on one side of the guide 121a so that the hooks 122a of the elastic spring 122 A step portion 123 having a through hole 123a is formed at the center of the bottom and a ring 112 of the insulating cover 11 and a bolt a and a nut b An insulating pedestal 12 formed with a plurality of rings 124 to be fastened; A rotation shaft 131 inserted into the through hole 123a of the insulation pedestal 12 and penetrating to the lower portion is formed at the lower portion of the insulation pedestal 12 and a pedestal 123 rotatably mounted on the step portion 123 with an O- And a rotation bar 133 is provided on the upper end of the receiving part 132 and has a fastening ring 133a to which the fastening ring 122a formed at the other end of the elastic spring 122 is inserted, (10) comprising an insulating rotation body (13) composed of a head (134) formed integrally with the rotating body
A fixing bolt 211 is formed on an upper portion of the inner circumferential surface of the inner circumferential surface of the rotary shaft 131 to be fastened to a thread of the inner circumferential surface of the inner circumferential surface of the rotary shaft 131, An elastic spring 23 is inserted into the insertion hole 221 of the elastic high stage 22 in the box-shaped insulation box 21 and the elastic hook 231 of the elastic spring 23 is inserted into the elastic high stage 22 A pair of fixing hooks 241 are formed on the inner side while the protruded hooking hooks 231 are engaged with each other and fastening holes 242 are formed on the upper and lower sides of the fixing hooks 241, (20) composed of two insulating jars (24) each of which is fastened with a bolt (a) to a fastener (251)
The jumper wires 5 for electrically connecting the transmission lines 100 connected to each other through the fastening holes 242 of the insulation cap 24 and the insulated transmission line clamp 25 are provided on both sides of the stretching member 20 In a distribution-type processing distribution line connection structure of a steel tower,
Is provided on one surface of one end of the insulating bar 12 where the fastening ring 133a of the rotating bar 133 is formed to be rotated in conjunction with the rotation of the rotating bar 133, A first pressure sensor (31) installed such that one end of the guide (121a) in the longitudinal direction of the pair of the guides (121a) overlaps; And the other end of the rotation bar 133 is disposed on the other side of the rotation bar 133 so as to face the first pressure sensor 31 about one end of the rotation bar 133, 121a are provided so as to overlap one another in the longitudinal direction of the other one of the guides 121a so that when a rotational force in a direction parallel to the stretching member 20 is not applied to the rotating bar 133, A second pressure sensor (32) held in contact with one longitudinal end of the guide (121a) overlapping the point; A wind speed sensor 33 installed on the outer surface of the insulating cover 11 to detect the wind speed of the surroundings; A wind direction sensor 34 installed on the outer surface of the insulation cover 11 to sense the wind direction around the wind direction sensor 34; The time when the rotation bar 133 is rotated in a direction parallel to the stretching member 20 and the time when the second pressure sensor 32 is in contact with the first direction of the guide, Time information indicating a time difference between a time when the first pressure sensor 31 is contacted with one end in the longitudinal direction of another guide positioned in the rotational direction of the rotary bar in accordance with the rotation of the rotary bar, A threshold time for determining whether the elastic force of the elastic spring 122 in the insulation pedestal 12 is abnormal or not is set based on the wind velocity information and the wind direction information sensed by the wind direction detection sensor 34, 34 is a direction in which the wind direction detected by the wind speed sensor 33 is rotated in the direction in which the rotation bar 133 is aligned with the stretching member 20, A tensile force abnormality determination unit (35) for determining an abnormality of the elastic spring (122) in the insulation pedestal (12) and outputting an abnormal signal when the time information is shorter than the predetermined threshold time ); A control unit 36 for outputting a control signal to the connected abnormality display unit 37 when an abnormality signal for the tensile force of the elastic spring 122 in the insulating pedestal 12 is inputted from the tensile force abnormality determination unit 35; The spring tension detecting means 30 including the abnormality display portion 37 which operates according to the control signal of the controller 36 to notify the outside that an abnormality has occurred in the tensile force of the elastic spring 122 in the insulating pedestal 12, : And
A wireless communication module 40 installed on the outer surface of the insulating cover 11 and wirelessly transmitting the abnormal signal outputted through the tensile force abnormality determination unit 35 so that the abnormal signal can be received by the remote control center at a remote location Further included,
Wherein the fixing protrusion 111 formed in the insulating cover 11 is formed in a long shape along the vertical direction so that the hole 111a is in the shape of a long hole along the vertical direction, A bolt coupling hole 4a corresponding to the hole 111a of the fixing protrusion 111 is formed at the lower end of the bolt 4,
One end in the longitudinal direction is coupled to the lower surface of the steel pillar (2), and the other end in the longitudinal direction is formed in a hollow shape extending downward in the vertical direction and opening at the lower end A plurality of fixing pipes (51); A plurality of elastic members (52) installed inside the corresponding fixing pipe (51) for each of the fixing pipes (51) to exert elasticity along the vertical direction; One end in the longitudinal direction is inserted through the lower end of the fixed pipe 51 for each fixing pipe 51 and the other end in the longitudinal direction is coupled to the upper surface of the insulating cover 11, (50) including a vertically movable bar (53) to which a restoring force in a downward direction is applied by the elasticity of the vertical bar (52)
When the power transmission line connected to both sides of the stretching member 20 flows in the vertical direction by the wind, the rotary member 10 is inserted into the long hole 111a formed in the fixing protrusion 111 of the insulating cover 11 And the vertical buffering means 50 functions as a cushioning function when the rotary member 10 moves up and down. As a result, the extension member 20, the rotary member 10, (3) and the steel pillar (2) is reduced due to the upward and downward flow of the power transmission line.

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