KR102045932B1 - Bypass cable impression device and bypass cable installation method using the device - Google Patents

Abstract

The present invention relates to a bypass cable lifting device for indirect live wire work and an installation method for a bypass cable using the same. More specifically, the bypass cable lifting device for indirect live wire work includes: a clamp unit including a clamp body and an accommodation groove formed on the front surface of the clamp body to accommodate a power line, wherein the clamp unit is installed in the power line; a drum unit including a drum cover, a drum body, and an insulation lift belt formed of an insulator and wound on the drum body, wherein the drum cover is connected to the lower part of the clamp body to rotate and the drum body is connected to the inside of the drum cover to rotate; and a control unit including a rotation shaft and a gear, wherein the rotation shaft is connected to the drum body and the gear is formed to rotate the rotation shaft by being connected to the rotation shaft on a side of the drum unit. A bypass cable work member is connected to an end of the insulation lift belt. The insulation lift belt is wound on the drum body or is unwound from the drum body in accordance with control of the control unit.

Description

BYPASS CABLE IMPRESSION DEVICE AND BYPASS CABLE INSTALLATION METHOD USING THE DEVICE}

The present invention relates to a bypass cable pulling apparatus for indirect live work and a bypass cable installation method using the same.

More specifically, by operating the control unit so that the insulated lifting belt is wound around the drum body or unwound from the drum body, it is connected to the end of the insulated lifting belt and can be uninterrupted for replacement of the distribution line and relocation and change of transition. Bypass cable pulling device for indirect live work to facilitate the installation of the bypass cable working member and a bypass cable installation method using the same.

In modern society, power demand is increasing rapidly, and the demand for power quality is gradually increasing.

Accordingly, the uninterruptible power distribution method is mainly adopted so that the construction can be performed without interrupting the power during the work to reduce the power failure during construction and construction of the distribution line. .

The conventional high voltage distribution line uninterruptible power distribution method uses the uninterrupted temporary transmission method using live bypass jumper cable, construction switchgear, uninterruptible transformer train, bypass cable, etc. As a result, KEPCO, the client, decided to abolish the direct live ship method from 2017 and introduce uninterruptible power distribution method using indirect live ship method. Due to the confusion caused by the combination of the public method and the direct live method, the situation is reported to the media such as the newspapers in the field of electric power daily due to the danger of safety accidents of live boat majors and the deterioration of work efficiency due to the limitation of labor intensity and physical strength. to be.

At this time, the conventional direct bowing method is different from the work performed by the electrician who wears protective equipment and directly touches the special high pressure of the live wire. The indirect bowing method is about 1.5m to 2m long to secure the safety distance. It is a live ship method that works by using an insulated stick without directly contacting the live high voltage distribution line using an insulated stick.

On the other hand, in order to implement the uninterruptible power distribution method, a live bypass jumper cable, a construction switchgear, an uninterruptible transformer train, and a bypass cable are used. This method requires a bypass cable clamp to be used for a special high voltage power cable. And the jumper wire separation compression is accompanied.

That is, with reference to FIGS. 1A and 1B, the conventional uninterruptible power distribution method always involves a cable clamp 3 installation process. First, the temporary cable 2 is connected to the extra-high voltage line 6, and the stick 5 for the work line 5 is used. After installation, temporarily fix the bypass cable (7) temporarily mounted on the branched concrete (4) to the cable temporary hanger (2) by using the stick work stick (5). After removing the cover of the extra high voltage line 6, the extra high voltage line 6 with the strip of the cable clamp 3 temporarily fixed to the cable temporary hanger 2 using the live stick 5 again. ), The cable rotator is inserted into the cable clamp (3), and then connected using an indirect live rotation function stick.

However, the indirect live uninterruptible power distribution method as described above uses a live work stick of about 1.5 m to 2 m in length to perform a very complicated and cumbersome work, and includes a wire separating cutter, a live compressor (about 4.5 kg) and a cable. Since the weight of clamps (about 5 ~ 20kg) is placed on the end of the live work stick, it is impossible to support the live work stick due to the physical strength of the worker. In addition, the risk of musculoskeletal disorders as well as the limitation of physical strength may cause safety accidents and track failures by omitting protection.For this reason, the indirect live uninterruptible power distribution method of the prior art is implemented in the field of live major and applied technology field. Worried

Patent Registration No. 10-1873712 (2018.06.26.) Patent Registration No. 10-0926445 (2009.11.05.) Patent Registration No. 10-1777080 (2017.09.04.)

The present invention has been made in order to solve the above problems, the problem to be solved in the present invention, by connecting the end of the insulation pulling belt by operating the control unit so that the insulating lifting belt is wound on the drum body or unwinded from the drum body. It provides a bypass cable pulling device for indirect live work, and a bypass cable installation method using the same, which makes it easy to install a bypass cable work member that can be carried out uninterrupted for replacement and relocation of power distribution lines and change of location. There is.

Bypass cable pulling apparatus for indirect live work according to the present invention for solving the above problems, the clamp body including a clamp body and the receiving groove which is formed to accommodate the power line on the front surface of the clamp body and mounted on the power line; A drum part including an drum, which is rotatably coupled to a lower portion of the clamp main body, a drum main body rotatably coupled to the inside of the drum cover, and an insulator, the insulating lifting belt being wound around the drum main body; And a control unit including a rotating shaft connected to the drum body and a gear connected to the rotating shaft at the side of the drum unit, the gear configured to rotate the rotating shaft, and a bypass cable working member connected to an end of the insulating lifting belt. And the insulation lifting belt is wound around the drum body or unwound from the drum body according to an operation of the controller.

In addition, the clamp portion includes a fixing member for holding and holding the power line accommodated in the receiving groove, the fixing member is hinged to the upper side opposite the receiving groove of the clamp main body in the upper and lower parts of the receiving groove A pressure port configured to rotate in a direction; A knob housing which is hinged to a lower side opposite the receiving groove of the clamp main body so as to rotate in an upper and lower direction, and configured to face the pressing hole; A knob shaft provided to allow free rotation in the knob housing; A control knob coupled to one end of the knob shaft; And one end screwed in the other end direction of the knob shaft, and the other end is hinged to the pressurizing tool, which is configured to be pulled into or pulled out of the knob shaft according to the operation of the adjusting knob. Characterized in that it comprises a.

The clamp unit may include a rotating member rotatably connected to a lower portion of the clamp main body in a direction orthogonal to the power line, and the drum cover may be rotatably coupled to a lower portion of the rotating member.

The drum unit may include: a rotating plate connected to the rotating shaft on the opposite side of the drum unit to be rotated together with the rotating shaft, and having a plurality of rotating grooves formed along an inner circumference of the inner surface; A plurality of insertion holes provided in the drum body to rotate together with the drum body and formed to correspond to the rotating grooves of the rotating plate; An elastic member for elastically supporting the plurality of insertion holes in the rotating plate direction; And a dropping plate provided between the rotating plate and the plurality of insertion holes, the dropping plate having a number of through grooves corresponding to the rotating groove, wherein the drum body is rotated by the rotating shaft to rotate the rotating plate. The groove is characterized in that it is configured to rotate by the control of the control unit as a plurality of insertion holes are inserted.

In addition, the rotary groove is formed in a shape that gradually widens toward the drum portion, the through groove is formed to correspond to a shape that gradually widens as the rotary groove toward the drum portion, and is set in advance in the insulating lifting belt When the rotating shaft is rotated in a state where more than a weight is applied, the plurality of insertion holes are moved along the bottom surfaces of the rotating grooves and the through grooves and dropped from the rotating grooves and the through grooves, so that the drum body rotates by the controller. Characterized in that not configured.

In addition, the drum is formed with a plurality of rotary grooves connected to the rotary shaft on the opposite side of the control unit of the drum and rotated together with the rotary shaft, and formed in a polygonal shape along the outer circumference of the inner surface. Rotating plate is formed in a shape that gradually widens toward the drum portion; An insertion plate provided inside the drum body to rotate together with the drum body and having a plurality of insertion holes corresponding to the rotating grooves of the rotating plate; An elastic member for elastically supporting the insertion plate in the rotation plate direction; And a through plate provided between the rotating plate and the insertion plate and having a number of through grooves corresponding to the rotating groove, wherein the through groove has a dropping plate formed to correspond to a shape in which the rotating groove gradually widens toward the drum part. Characterized in that it is included.

In addition, the gear member, a case; A worm wheel provided inside the case and coupled to the rotation shaft to rotate together with the rotation shaft; And a worm corresponding to the worm wheel is formed at a portion located inside the case, and a worm shaft having an impression adjusting knob formed at one end of the worm wheel.

In addition, the drum cover is characterized in that one or a plurality of fixing grooves are formed along the circumferential direction of the rotating shaft so that the case is fixed, and the gear member is provided with an index plunger corresponding to the fixing groove.

Bypass cable installation method using the indirect live work bypass cable pulling device according to the present invention for solving the above problems, the bypass cable pulling device and bypass cable working member on the power side and load side of the live power line A job preparation process for preparing each phase; A pulling device installation step of installing the clamp portion of the bypass cable pulling device for live work on a power line on a power supply side and a load side for each phase; A bypass cable preparation step of connecting the bypass cable work members by lowering the insulation lifting belts of the installed bypass cable pulling devices for each live work and raising the insulated lifting belt of the bypass cable pulling device for live work again; Bypass for connecting the power line and the bypass cable work member by bypass by installing the elevated bypass cable work member on the insulated power line on the power supply side and the load side by phase. Cable installation process; A jumper wire separation process of separating the jumper wires on both sides of the work section after bypassing the power line and the bypass cable work member; A distribution facility process for performing diagonal work in a work section after the jumper wire is separated; A jumper wire connecting step of connecting jumper wires on both sides of the work section after the power distribution work; A bypass cable separation step of separating a bypass cable work piece installed on a phased power line on a power supply side and a load side, and separating the bypass cable work piece from an insulation pulling belt; It is characterized in that it comprises a finishing step of separating the clamp portion of the bypass cable pulling device for live work for each phase installed on the power line on the power supply side and the load side, and the site.

According to the bypass cable pulling apparatus for indirect live work and the bypass cable installation method using the same according to the present invention, the insulating pulling belt is wound around the drum body or unwound from the drum body by operating the control unit, thereby connecting to the end of the insulating pulling belt. It also has the effect of making it easy to install bypass cable working members that can be used to replace and relocate distribution lines, and to perform uninterrupted construction.

In addition, according to the present invention, when the rotating shaft is rotated in a state in which the weight is more than the predetermined weight is applied to the insulating lifting belt so that a plurality of insertion holes are removed from the rotating groove and the through groove so that the insulating lifting belt does not move even if the rotating shaft is rotated, When the rotating shaft is rotated in the state in which the insulation lifting belt is in the wrong position, there is an effect to prevent the overload of the insulation lifting belt or the control unit.

1A and 1B show a conventional temporary cable connection clamp.
Figure 2a to 2c is a view showing a bypass cable pulling device for indirect live work according to the present invention.
Figure 3 is a view showing the clamp portion of the bypass cable pulling device for indirect live work according to the present invention.
4a and 4b is a view showing the operating state of the clamp portion of the bypass cable pulling device for indirect live work according to the invention.
5a to 5c is a view showing a drum according to an embodiment of the bypass cable pulling apparatus for indirect live work according to the present invention.
Figures 6a and 6b is a view showing the drum operating state of the bypass cable pulling device for indirect live work according to Figures 5a to 5c.
7a to 7c is a view showing a drum according to another embodiment of the bypass cable pulling apparatus for indirect live work according to the present invention.
8A and 8B are views showing an operation state of the drum of the bypass cable pulling apparatus for indirect live work according to FIGS. 7A to 7C.
9a to 9c is a view showing a control unit of the bypass cable pulling apparatus for indirect live work according to the present invention.
10 is a flowchart showing a bypass cable installation method using a bypass cable pulling apparatus for indirect live work according to the present invention.

As the inventive concept allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention.

When a component is said to be "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but it may be understood that another component may be present in the middle. Should be.

On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that there is no other component in between.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "having" are intended to indicate that there is a feature, number, process, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present disclosure does not exclude the possibility of the presence or the addition of numbers, processes, operations, components, components, or a combination thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

Hereinafter, with reference to the accompanying drawings will be described in more detail the present invention. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the ordinary or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own inventions. Based on the principle that it can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. In addition, unless there is another definition in the technical terms and scientific terms used, it has the meaning commonly understood by those of ordinary skill in the art to which this invention belongs, and the gist of the present invention in the following description and the accompanying drawings. Descriptions of well-known functions and configurations that may be unnecessarily blurred are omitted. The drawings introduced below are provided by way of example so that the spirit of the invention to those skilled in the art can fully convey. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. Also, like reference numerals denote like elements throughout the specification. It should be noted that the same elements in the figures are represented by the same numerals wherever possible.

The present invention is operated by the control unit so that the insulated lifting belt is wound on the drum body or unrolled from the drum body, connected to the end of the insulated lifting belt, and can be performed uninterrupted to perform the replacement and relocation of the distribution line and the change of transition. The present invention relates to a bypass cable pulling device for indirect live work, and a bypass cable installation method using the same.

Hereinafter, a bypass cable pulling apparatus for indirect live work according to the present invention and a bypass cable installation method using the same will be described in detail with reference to the accompanying drawings.

2a to 2c is a view showing the bypass cable pulling apparatus for indirect live work according to the present invention.

According to the accompanying Figures 2a to 2c, the live cable bypass device of the present invention, the clamp main body 110 and the receiving groove which is formed to accommodate the power line 500 on the front surface of the clamp main body 110 ( And a clamp unit 100 mounted on the power line 500, a drum cover 210 rotatably coupled to a lower portion of the clamp main body 110, and rotatably inside the drum cover 210. A drum unit 200 including a drum main body 220 and an insulator coupled to the drum main body 220 including an insulated impression belt 230 wound around the drum main body 220, and a rotating shaft 310 connected to the drum main body 220; The controller 300 includes a gear member 320 connected to the rotary shaft 310 at the side of the drum unit 200 and configured to rotate the rotary shaft 310.

At this time, the bypass cable working member 400 is connected to the end of the insulation lifting belt 230, the insulation lifting belt 230 is wound around the drum body 220 in accordance with the operation of the control unit 300 The drum body 220 is configured to be unwound.

In the live cable bypass device of the present invention, an unshielded portion of the power line 500 is accommodated in the receiving groove 120 of the clamp unit 100 so that the live cable bypass device is the power line 500. By operating the control unit 300 in the state mounted on the bypass cable working member 400 connected to the insulating lifting belt 230 of the drum 200 by lowering and pulling the bypass cable working member ( It is to be able to easily install 400 in the shielded portion of the power line 500.

In the live cable bypass device, the insulation pulling belt 230 connected to the bypass cable work member 400 is formed of an insulator, and the bypass cable work member 400 is prevented from falling and falling. By being configured to, it is configured to prevent a safety accident that may be caused by the progress of the live work or the fall of the bypass cable work member 400.

In this case, the bypass cable work member 400 connected to the insulation pulling belt 230 may include a bypass clamp part 410, a bypass connection part 420, and a bypass cable 430.

The bypass clamp unit 410 may be configured to have the same or similar configuration as the clamp unit 100 of the present invention, and is to allow a portion of the power line 500 to be installed and energized.

The bypass clamp unit 410 may be deformed as much as the thickness and shape of the power line 500 since the bypass clamp unit 410 is mounted on the portion of the power line 500, and the clamp unit 100 of the present invention. Unlike the power line 500 may be made of a conductive material so as to be energized.

In addition, the bypass clamp unit 410 may include a fixing member 130 of the same shape as the fixing member 130 provided in the clamp unit 100 of the present invention, which will be described later, As described above, the power line 500 may be deformed as much as the thickness and shape of the power line 500.

The bypass connection unit 420 conducts electricity between the bypass clamp unit 410 and the bypass cable 430 while the bypass clamp unit 410 is mounted on the insulated portion of the power line 500. In order to improve the workability, the bypass cable 430 may be configured to be freely rotatable.

The bypass cable 430 is configured to be freely rotatable, wherein the bypass connection part 420 is configured by being divided into an upper connection part 421 and a lower connection part 422, and the upper connection part 421 is connected to the bypass clamp. The lower connection portion 422 may be coupled to the portion 410 by being rotatably coupled to the lower portion of the upper connection portion 421 with the same central axis as the upper connection portion 421.

The bypass cable 430, one end is inserted and connected through the end of the bypass connection 420, the other end is inserted and connected through the end of the other bypass connection 420, two bypass cables It is configured to be energized by connecting the working member 400.

Figure 3 is a view showing the clamp portion of the bypass cable pulling apparatus for indirect live work according to the present invention, Figures 4a and 4b is a view showing the operating state of the clamp portion of the bypass cable pulling device for indirect live work according to the present invention.

According to the accompanying Figures 3 to 4b, the clamp unit 100 of the present invention is to install the bypass cable pulling device for live work of the present invention to the power line 500, as described above the clamp body 110 and It is configured to include a receiving groove 120 formed in the clamp body 110.

The clamp unit 100 may include a rotating member 140 which is rotatably connected in a direction orthogonal to the power line 500 at the lower portion of the clamp body 110, the drum cover 210 is It may be rotatably coupled to the lower portion of the rotating member 140.

The rotating member 140 is coupled to the lower portion of the clamp unit 100 to maintain a vertical state with the drum unit 200 to be described later.

Since the clamp body 110 is configured such that the insulation lifting belt 230 connecting the clamp body 110 and the bypass cable work member 400 is made of an insulator and is not energized with each other, the clamp body 110 ) May be made of any one of a conductor or an insulator.

In addition, the accommodating groove 120 may be formed with an upper gripping groove 121 having a 'V' shape to hold the power line 500, and the upper gripping groove 121 is the power line 500. Depending on the thickness of the) may be formed in a variety of sizes.

In addition, the clamp unit 100 may include a fixing member 130 for holding and holding the power line 500 accommodated in the receiving groove 120.

The fixing member 130 is hinged to the upper side opposite the receiving groove 120 of the clamp main body 110 is configured to rotate in the vertical direction in the interior of the receiving groove 120, the pressure port 131, the The hinge housing is coupled to the lower side opposite the receiving groove 120 of the clamp body 110 is configured to rotate in the upper and lower direction, the knob housing 132 is configured to face the pressure port 131, the interior of the knob housing 132 The knob shaft 133 is provided so as to be freely rotated, the coupling control knob 134 is coupled to one end of the knob shaft 133 and one end is screwed in the other end direction of the knob shaft 133 and the other end is Is hinged to the pressure port 131 is configured to be drawn into the knob shaft 133 or withdrawn from the knob shaft 133 according to the operation of the coupling control knob 134 to rotate the pressure port 131 Coaxial 135 may be included.

The pressure port 131 is rotated in the vertical direction by the rotating shaft 135 drawn into or out of the knob shaft 133 according to the operation of the coupling control knob 134 the power line And to hold 500.

In this case, the pressing hole 131 may be configured to grip the power line 500 while rotating from the bottom to the upper direction, is formed in the upper portion of the receiving groove 120 so as to firmly grip the power line 500. A lower gripping groove 131a having a shape corresponding to the upper gripping groove 121 may be formed.

The knob housing 132 forms a space in which the knob shaft 133 to be rotated according to the manipulation of the coupling adjusting knob 134 is accommodated. The knob housing 132 is disposed below the receiving groove 120 of the clamp body 110. The hinge may be coupled to easily correspond to the positional change according to the pulling in and out of the pivot shaft 135.

The knob shaft 133 is configured to be rotated according to the operation of the coupling adjusting knob 134, and a screw thread is formed therein so that the knob shaft 133 is rotated by the coupling adjusting knob 134. The rotating shaft 135 which is screwed in is configured to be drawn into the inside of the knob shaft 133 or to be drawn out from the inside of the knob shaft 133.

The knob shaft 133 may be configured to only freely rotate without shaking in the knob housing 132, that is, even when the coupling adjusting knob 134 is operated, the coupling adjusting knob 134 and the knob shaft are operated. The position of 133 is configured to remain unchanged.

The rotating shaft 135 is hinged to the pressure port 131 in the state in which one end is screwed in the other end direction of the knob shaft 133, even if the knob shaft 133 is rotated without the rotation It is configured to be drawn into the inside of the knob shaft 133 or to be drawn out from the inside of the knob shaft 133, so as to have a certain level of torsional strength to be drawn in and drawn out without being rotated by the rotation of the knob shaft 133. Can be configured.

That is, the clamp unit 100 of the present invention is configured to fix the unsealed portion of the power line 500 while the fixing member 130 is mounted on the unsealed portion of the power line 500.

5A to 5C are views illustrating a drum unit according to an embodiment of the indirect live work bypass cable pulling apparatus according to the present invention, and FIGS. 6A and 6B show the bypass cable pull for indirect live work according to FIGS. 5A to 5C. It is a figure which shows the drum part operation state of an apparatus.

5A to 6B, the drum unit 200 according to an embodiment of the present invention is connected to the rotary shaft 310 on the side opposite to the control unit 300 of the drum unit 200. Rotating together with the 310, the rotating plate 240 is formed in a plurality of rotating grooves 241 formed in a circular shape along the inner circumference of the inner surface, the drum body 220 is provided in the drum body 220 And a plurality of insertion holes 250 formed to correspond to the rotating grooves 241 of the rotating plate 240 and the elastic members elastically supporting the plurality of insertion holes 250 in the direction of the rotating plate 240. 260 and between the rotating plate 240 and the plurality of insertion holes 250, the dropping plate 270, the number of through grooves 271 corresponding to the rotating groove 241 is formed may be included, The drum body 220 is the rotating plate 240 is rotated by the rotating shaft 310 and the rotating plate 240 Rotation grooves 241 may be configured to be rotated by the control of the controller 300 as the plurality of the insertion port 250 is inserted.

The rotating plate 240 transmits the rotational force transmitted from the control unit 300 to the drum body 220 through the plurality of insertion holes 250 so that the drum body 220 is rotated, thereby the drum body 220. Insulated lifting belt 230 is to be wound, or the insulating lifting belt 230 wound on the drum body 220 is to be unwound.

At this time, the rotational force transmitted from the rotating plate 240 to the plurality of insertion holes 250 is transmitted to the rotary groove 241 formed in the rotating plate 240 by being inserted into the plurality of insertion holes 250 to rotate together. The shape of the rotating groove 241 formed on the rotating plate 240 may be variously modified according to a work environment.

The plurality of insertion holes 250 are inserted into the rotary groove 241 with elasticity by the elastic member 260 to transfer the rotational force transmitted from the rotating plate 240 to the drum body 220.

The plurality of insertion holes 250 may be configured to be elastically supported by the elastic member 260 in a state of being inserted into the partition 221 inside the drum body 220, which is the plurality of insertion holes 250. ) Is to be prevented from being lost when the rotary groove 241 is dropped.

The dropping plate 270 is provided between the rotating plate 240 and the plurality of insertion holes 250 to provide a clutch function to be described later.

On the other hand, the rotary groove 241 may be formed in a shape that gradually increases toward the drum portion 200 direction, the through groove 271 is the rotary groove 241 toward the drum portion 200 direction The drum body 220 may be formed to correspond to a gradually wider shape. When the rotating shaft 310 is rotated in a state where a weight more than a predetermined weight is applied to the insulation lifting belt 230, the plurality of the plurality of drum bodies 220 may be rotated. The insertion hole 250 is moved along the bottom surface of the rotary groove 241 and the through groove 271 to be removed from the rotary groove 241 and the through groove 271, the drum body 220 is the control unit 300 It can be configured not to rotate by).

That is, as a clutch function is provided in the drum body 220, and when the rotation shaft 310 is rotated in a state where a weight equal to or greater than a predetermined weight is applied to the drum body 220, the plurality of insertion holes ( 250 is moved in the direction in which the elastic member 260 is provided in accordance with the gradually widening shape of the rotary groove 241 and the through groove 271, so that the plurality of insertion holes 250 is the rotary groove 241 And falling from the through groove 271.

At this time, since the rotational force of the rotating plate 240 is transmitted in a state where the plurality of insertion holes 250 are inserted into the rotating groove 241 of the rotating plate 240, the plurality of insertion holes 250 are the rotating grooves ( As it is removed from the 241, the rotational force of the rotating plate 240 is not transmitted to the plurality of insertion holes 250, so that the drum body 220 is not rotated even when the control unit 300 is operated.

The predetermined weight of the drum body 220 depends on the elastic force of the elastic member 260 and the angle of the shape gradually widening toward the drum portion 200 of the rotary groove 241 and the through groove 271. The elastic force of the elastic member 260 or the angle of the shape gradually widening toward the drum 200 of the rotary groove 241 and the through groove 271 may be differently applied according to the working environment. .

Accordingly, even when the rotating shaft 310 is rotated in the state in which the insulating lifting belt 230 is in the wrong position, the insulating lifting belt 230 or the control unit 300 may be configured to prevent overload.

7A to 7C are views illustrating a drum unit according to another embodiment of the indirect live work bypass cable pulling apparatus according to the present invention, and FIGS. 8A and 8B illustrate a bypass cable pull for indirect live work according to FIGS. 7A to 7C. It is a figure which shows the drum part operation state of an apparatus.

7A to 8B, in the drum 200 according to another embodiment of the present invention, the drum 200 may include the rotating shaft on the opposite side of the controller 300 of the drum 200. Is connected to the 310 is rotated with the rotary shaft 310, a plurality of rotary grooves 241 formed in a polygonal shape is formed along the outer periphery of the inner surface, the rotary groove 241 is the drum portion 200 Rotating plate 240 is formed in a shape that gradually increases toward the direction, is provided inside the drum body 220 is rotated with the drum body 220, in the rotating groove 241 of the rotating plate 240 Insertion plate 280 in which a plurality of insertion holes 250 are formed, an elastic member 260 for elastically supporting the insertion plate 280 in the direction of the rotating plate 240 and the rotating plate 240 and the insertion plate 280 ) Is provided between the through grooves 271 of the number corresponding to the rotary groove 241 is formed, the through grooves 271 may include a dropping plate 270 formed to correspond to a shape in which the rotary groove 241 gradually widens toward the drum 200.

That is, a clutch function is provided inside the drum body 220 while the drum body 220 is rotated by the rotational force transmitted to the insertion plate 280 through the rotating plate 240 according to the operation of the control unit 300. It is to be provided.

When the rotating shaft 310 is rotated in a state where a weight greater than or equal to a predetermined weight is applied to the insulation lifting belt 230, the insertion plate 280 having the plurality of insertion holes 250 is formed through the rotation groove 241 and through. In accordance with the gradually widening shape of the groove 271 is moved in the direction in which the elastic member 260 is provided so that the plurality of insertion holes 250 of the insertion plate 280 is the rotary groove 241 and the through groove 271 Will be eliminated.

At this time, since the rotational force of the rotating plate 240 is transmitted in a state where the plurality of insertion holes 250 of the insertion plate 280 is inserted into the rotating groove 241 of the rotating plate 240, the insertion plate 280 As the plurality of insertion holes 250 are removed from the rotation groove 241, the rotational force of the rotation plate 240 is not transmitted to the insertion plate 280, so that the drum body 220 is operated even when the control unit 300 is operated. ) Is configured not to rotate.

The predetermined weight of the drum body 220 depends on the elastic force of the elastic member 260 and the angle of the shape gradually widening toward the drum portion 200 of the rotary groove 241 and the through groove 271. The elastic force of the elastic member 260 or the angle of the shape gradually widening toward the drum 200 of the rotary groove 241 and the through groove 271 may be differently applied according to the working environment. .

9A to 9C are views illustrating a control unit of the bypass cable pulling apparatus for indirect live work according to the present invention.

9A to 9C, the gear member 320 is provided inside the case 321 and the case 321 and is coupled to the rotation shaft 310 to rotate together with the rotation shaft 310. A worm 323a corresponding to the worm wheel 322 is formed at a portion located inside the worm wheel 322 and the case 321, and an impression adjusting knob is formed at one end of the worm wheel 322 and positioned outside the case 321. A worm shaft 323 in which 323b is formed may be included.

That is, when rotating the impression adjusting knob 323b of the gear member 320, the worm wheel 322 is rotated while the worm 323a located inside the case 321 is rotated, and the worm wheel ( As the 322 is rotated, the rotating shaft 310 which is rotated together with the worm wheel 322 is rotated to rotate the rotating plate 240 of the drum 200 so that the drum body 220 is rotated.

At this time, in the present invention, although the impression adjusting knob 323b is shown to be provided only at the bottom of the case 321, it may be configured to be provided at the same time on the top of the case 321 according to the embodiment, most preferably The impression adjusting knob 323b is often formed only at the bottom because it is often adjusted at the bottom.

On the other hand, the present invention discloses a worm wheel 322 and a worm shaft 323 as a configuration for rotating the rotary shaft 310, in accordance with an embodiment the impression adjusting knob 323b from the outside of the case 321 Any configuration that can rotate the rotary shaft 310 by only rotating can be changed.

In addition, one or a plurality of fixing grooves 210a may be formed in the drum cover 210 along the circumferential direction of the rotation shaft 310 so that the case 321 may be fixed. An index plunger 324 corresponding to the fixing groove 210a may be provided.

The index plunger 324 may be applied as long as the index plunger 324 is formed in the form of a conventional index plunger so that the index plunger can be drawn in and fixed in the fixing groove 210a or drawn out and fixed in the fixing groove 210a.

That is, the index plunger 324 prevents the case 321 from rotating on the surface of the drum cover 210. When the index plunger 324 is separated from the fixing groove 210a, the case 321 is rotated. 321 may rotate itself to drive the drum 200, and when the index plunger 324 is inserted into the fixing groove 210a, the drum is operated by operating the impression adjusting knob 323b. It is possible to drive the unit 200.

In this case, when the plurality of fixing grooves 210a are configured in plural, the index plunger 324 may also be configured in plural. For the sake of safety, the plurality of index plungers 324 may be removed when the index plunger 324 is drawn out. It can be configured to be rotatable only when all the 324 are withdrawn.

In addition, the index plunger 324 is inserted into a plurality of fixing grooves (210a) formed on the surface of the drum cover 210 while the gear member 320 is rotated on the surface of the drum cover 210 to the gear The member 320 is configured to be fixed.

Therefore, when the index plunger 324 is separated from the fixing groove 210a to rotate the gear member 320 and the index plunger 324 is inserted into the fixing groove 210a, the index plunger 324 ) Can be configured to adjust the position of the impression adjustment knob (323b) by having a fixed angle of the gear member 320 is determined according to which fixing groove (210a) to be inserted.

10 is a flowchart illustrating a bypass cable installation method using a bypass cable pulling apparatus for indirect live work according to the present invention.

According to the accompanying FIG. 10, the bypass cable installation method using the bypass cable pulling apparatus for indirect live work according to the present invention may be composed of seven steps, which is a work preparation step (S10) and a pulling device installation step (S20). , Bypass cable preparation process (S30), bypass cable installation process (S40), jumper wire separation process (S50), power distribution equipment process (S60), jumper wire connection process (S70), bypass cable separation process (S80) And finishing step (S90).

In the bypass cable installation method using the indirect live cable bypass device according to the present invention, the jumper wire replacement, relocation, switchgear installation, replacement, relocation, etc. in the live pole, perform indirect live uninterrupted power distribution work, or After installing the construction switchgear in live Jeonju, divide the sections and perform uninterrupted power distribution work by moving the electric poles indirectly by relocating and replacing the electric poles, or by replacing wires, or by installing construction switchgear in live Jeonju. Uninterrupted power distribution works with indirect lines such as relocation and replacement of electric poles, wire replacement, etc., or by uninterrupted power distribution works for uninterrupted transformer installation, replacement or relocation from live poles using uninterruptible transformer devices. Or install an uninterruptible bypass cable to pole the extra-high voltage distribution line. Although it may be configured to perform an uninterruptible power distribution work by moving indirectly, such as relocation, replacement, change of the transition place, etc., in the present invention, indirect liveline uninterruptible power distribution work is performed by replacing jumper wire, relocation, switchgear, replacement, relocation, etc. in live poles. Only performing is described as an example.

The work preparation step (S10) is a process of preparing a bypass cable pulling device and a bypass cable work member 400 on a power supply side and a load side of a live power line 500 by phase.

In this case, the bypass cable lifting member 230 of the bypass cable pulling device may be provided in a state where the bypass cable work member 400 is not coupled, and the insulation pulling belt 230 is initially in safety. It is preferable to prepare in the state raised along.

The pulling device installation step (S20) is a step of installing the clamp unit 100 of the bypass cable pulling device for live work on the power line 500 on the power supply side and the load side for each phase.

This is to receive the power line 500 of the power supply side and the load side in the receiving groove 120 of the clamp unit 100 so that the clamp unit 100 is caught and installed, the fixing member 130 according to the implementation environment By adjusting the back, the clamp unit 100 and the power line 500 may be configured to be firmly coupled.

The process of installing the live cable bypass cable pulling device for the power line 500 on the power supply side and the load side may be made through a separate live insulation stick, and the live insulation stick is commonly used for live ships. It may be composed of an insulating stick.

The bypass cable preparation step (S30) is to cut the insulation pulling belt 230 of the installed bypass cable pulling device for each live work to connect the bypass cable work member 400 and again of the live cable bypass device It is a process of pulling up the insulation pulling belt 230.

This is to operate the control unit 300 by using the live insulation stick to rotate the drum body 220 to lower or raise the insulation lifting belt 230, according to an embodiment, the live insulation stick Is configured to lower or raise the insulation pulling belt 230 by simply rotating the impression adjusting knob 323b of the control unit 300 can be used easily.

In the bypass cable installation process (S40), the bypass cable working member 400 which is raised is installed on the power line and the load side of the shielded power line 500 'by phase, thereby bypassing the shielded power line 500'. By connecting and energizing the cable work member 400 is a process of bypass connection of the cabled power line 500 'and the bypass cable work member 400.

This is installed by walking the bypass clamp portion 410 of the bypass cable working member 400 to the power line side and the load side of the power line (500 '), and installed on the power line side of the power line (500'). By-pass cable working member 400 and the bypass cable working member 400 installed on the load-impeded power line 500 'by the bypass cable 430 are connected to the power-side stripped power line 500'. ) And the load-side shielded power line 500 'are electrically energized.

The jumper wire separation process (S50) is a process of preparing a power distribution construction by separating the jumper wires on both sides of the work section after bypassing the cabled power line 500 'and the bypass cable work member 400.

The power distribution facility process (S60) is a process of performing power distribution work in a work section in a diagonal state after the jumper wire separation process (S50).

At this time, the jumper wire can be replaced, relocated, new switch, replacement, relocation, etc. in a state in which the jumper wire is separated.

The jumper wire connection process (S70) is a process of supplying power in the work section by connecting jumper wires on both sides of the work section after the power distribution facility process (S60).

The bypass cable separation process (S80) separates the bypass cable work member 400 installed in phases on the power line 500 ′ on the power supply side and the load side, and insulates the bypass cable work member 400. The process is separated from the impression belt (230).

This is configured to separate the bypass cable work member 400 by adjusting the impression adjusting knob 323b of the controller 300 using the live insulation stick.

The finishing step (S90) is a step of separating the clamp unit 100 of the bypass cable pulling device for live work installed on the power line 500 on the power supply side and the load side for each phase, and clean up the site.

This is to release the pressing force of the clamp unit 100 and the power line 500 of the power supply side and the load side by operating the fixing member 130 by using the live insulating stick for the clamp unit 100 to the power line When disconnected from 500, the live cable bypass device of the present invention is removed.

Meanwhile, the removal of the bypass cable pulling apparatus for live work according to the present invention is preferably performed sequentially for each phase of the power supply side and the load side, and the bypass cable pulling device for live work during uninterruptible power distribution works through such a series of processes. Indirect live uninterrupted power distribution is completed.

According to the present invention, by operating the control unit so that the insulation lifting belt is wound on the drum body or unrolled from the drum body, it is connected to the end of the insulation lifting belt, so that the replacement of the distribution line and relocation and change of transition site can be carried out uninterrupted. There is an effect to facilitate the installation of the bypass cable working member.

In the above description, various embodiments of the present invention have been described and described, but the present invention is not necessarily limited thereto, and a person having ordinary skill in the art to which the present invention pertains can make various changes without departing from the technical spirit of the present invention. It will be appreciated that branch substitutions, modifications and variations are possible.

100: clamp part
110: clamp body
120: receiving groove 121: upper gripping groove
130: fixing member
131: pressure port 131a: lower gripping groove
132: knob housing 133: knob shaft
134: coupling control knob 135: rotating shaft
140: rotating member
200: drum
210: drum cover 210a: fixing groove
220: drum body 221: partition
230: Insulated impression belt
240: rotating plate 241: rotating groove
250: insertion hole 260: elastic member
270: dropping plate 271: through groove
280: insert plate
300: control unit 310: rotation axis
320: gear member 321: case
322: worm wheel 323: worm shaft
323a: Worm 323b: Impression Adjustment Knob
324: Index Plunger
400: bypass cable working member 410: bypass clamp
420: bypass connection 421: upper connection
422: lower connection 430: bypass cable
500: power line 500 ': stripped power line

Claims (9)

delete A clamp unit (100) including a clamp main body (110) and a receiving groove (120) formed on the front surface of the clamp main body (110) to accommodate the power line (500);
The drum body 220 includes a drum cover 210 rotatably coupled to a lower portion of the clamp body 110, a drum body 220 rotatably coupled to the inside of the drum cover 210, and an insulator. A drum unit 200 including an insulation lifting belt 230 wound around the drum 200; And
Rotating shaft 310 connected to the drum body 220 and the gear member 320 is connected to the rotating shaft 310 on the side of the drum unit 200 is configured to rotate the rotating shaft 310 Control unit 300;
Including;
The bypass cable working member 400 is connected to the end of the insulation lifting belt 230,
The insulation lifting belt 230 is wound around the drum body 220 or unwound from the drum body 220 according to an operation of the controller 300.
In the clamp unit 100,
It includes a fixing member 130 for holding and holding the power line 500 accommodated in the receiving groove 120,
In the fixing member 130,
A pressure port 131 which is hinged to an upper side of the clamp main body 110 opposite to the receiving groove 120 and configured to rotate upward and downward in the receiving groove 120;
A knob housing 132 which is hinged to a lower side opposite the receiving groove 120 of the clamp main body 110 to be rotated in an up and down direction and is configured to face the pressure port 131;
A knob shaft 133 provided in the knob housing 132 to allow free rotation;
A coupling control knob 134 coupled to one end of the knob shaft 133; And
One end is screwed in the other end direction of the knob shaft 133 and the other end is hinged to the pressing hole 131 is introduced into the knob shaft 133 or the knob shaft in accordance with the operation of the coupling adjustment knob 134 A rotating shaft 135 configured to be drawn out from the 133 to rotate the pressing hole 131;
Bypass cable pulling device for indirect live work, characterized in that it is included.
A clamp unit (100) including a clamp main body (110) and a receiving groove (120) formed on the front surface of the clamp main body (110) to accommodate the power line (500);
The drum body 220 includes a drum cover 210 rotatably coupled to a lower portion of the clamp body 110, a drum body 220 rotatably coupled to the inside of the drum cover 210, and an insulator. A drum unit 200 including an insulation lifting belt 230 wound around the drum 200; And
Rotating shaft 310 connected to the drum body 220 and the gear member 320 is connected to the rotating shaft 310 on the side of the drum unit 200 is configured to rotate the rotating shaft 310 Control unit 300;
Including;
The bypass cable working member 400 is connected to the end of the insulation lifting belt 230,
The insulation lifting belt 230 is wound around the drum body 220 or unwound from the drum body 220 according to an operation of the controller 300.
In the clamp unit 100,
Rotating member 140 is rotatably connected to the lower portion of the clamp body 110 in a direction orthogonal to the power line 500,
The drum cover 210,
Bypass cable pulling apparatus for indirect live work, characterized in that rotatably coupled to the lower portion of the rotation member (140).
A clamp unit (100) including a clamp main body (110) and a receiving groove (120) formed on the front surface of the clamp main body (110) to accommodate the power line (500);
The drum body 220 includes a drum cover 210 rotatably coupled to a lower portion of the clamp body 110, a drum body 220 rotatably coupled to the inside of the drum cover 210, and an insulator. A drum unit 200 including an insulation lifting belt 230 wound around the drum 200; And
Rotating shaft 310 connected to the drum body 220 and the gear member 320 is connected to the rotating shaft 310 on the side of the drum unit 200 is configured to rotate the rotating shaft 310 Control unit 300;
Including;
The bypass cable working member 400 is connected to the end of the insulation lifting belt 230,
The insulation lifting belt 230 is wound around the drum body 220 or unwound from the drum body 220 according to an operation of the controller 300.
The drum unit 200,
A plurality of rotary grooves 241 connected to the rotary shaft 310 on the opposite side of the control unit 300 of the drum unit 200 and rotated together with the rotary shaft 310 and formed in a circular shape along the inner circumference of the inner surface. Rotating plate 240 is formed;
A plurality of insertion holes 250 provided in the drum body 220 to be rotated together with the drum body 220 and formed to correspond to the rotating grooves 241 of the rotating plate 240;
An elastic member 260 that elastically supports the plurality of insertion holes 250 in the direction of the rotating plate 240; And
A dropping plate 270 provided between the rotating plate 240 and the plurality of insertion holes 250 and having a number of through grooves 271 corresponding to the rotating grooves 241;
This includes,
The drum body 220, the rotating plate 240 is rotated by the rotating shaft 310, a plurality of insertion holes 250 are inserted into the rotating groove 241 of the rotating plate 240 the control unit 300 Bypass cable pulling apparatus for indirect live work, characterized in that configured to rotate by the control of).
The method of claim 4, wherein
The rotary groove 241,
It is formed in a shape that gradually widens toward the drum 200,
The through groove 271 is,
The rotary groove 241 is formed to correspond to the shape gradually widening toward the drum 200,
When the rotating shaft 310 is rotated in a state where a weight greater than or equal to a predetermined weight is applied to the insulation lifting belt 230, the plurality of insertion holes 250 may form a bottom surface of the rotary groove 241 and the through groove 271. By moving along and dropped from the rotary groove 241 and the through groove 271, the bypass cable pulling device for indirect live work, characterized in that the drum body 220 is configured not to rotate by the control unit 300. .
A clamp unit (100) including a clamp main body (110) and a receiving groove (120) formed on the front surface of the clamp main body (110) to accommodate the power line (500);
The drum body 220 includes a drum cover 210 rotatably coupled to the lower portion of the clamp body 110, a drum body 220 rotatably coupled to the inside of the drum cover 210, and an insulator. A drum unit 200 including an insulation lifting belt 230 wound around the drum 200; And
Rotating shaft 310 connected to the drum body 220 and the gear member 320 is connected to the rotating shaft 310 on the side of the drum unit 200 is configured to rotate the rotating shaft 310 Control unit 300;
Including;
The bypass cable working member 400 is connected to the end of the insulation lifting belt 230,
The insulation lifting belt 230 is wound around the drum body 220 or unwound from the drum body 220 according to an operation of the controller 300.
The drum unit 200,
A plurality of rotary grooves 241 are connected to the rotary shaft 310 on the opposite side of the control unit 300 of the drum 200 and rotated together with the rotary shaft 310, and are formed in a polygonal shape along the outer circumference of the inner surface. ) Is formed, the rotating groove 241 is a rotating plate 240 is formed in a shape that gradually widens toward the drum 200;
The insertion plate 280 is provided in the drum body 220 is rotated together with the drum body 220, a plurality of insertion holes 250 corresponding to the rotating groove 241 of the rotating plate 240 is formed ;
An elastic member 260 elastically supporting the insertion plate 280 in the direction of the rotating plate 240; And
It is provided between the rotating plate 240 and the insertion plate 280, the number of through grooves 271 corresponding to the rotating groove 241 is formed, the through groove 271 is the rotating groove 241 A dropping plate 270 that is formed to correspond to a shape that gradually widens toward the drum 200;
Bypass cable pulling device for indirect live work, characterized in that it is included.
A clamp unit (100) including a clamp main body (110) and a receiving groove (120) formed on the front surface of the clamp main body (110) to accommodate the power line (500);
The drum body 220 includes a drum cover 210 rotatably coupled to a lower portion of the clamp body 110, a drum body 220 rotatably coupled to the inside of the drum cover 210, and an insulator. A drum unit 200 including an insulation lifting belt 230 wound around the drum 200; And
Rotating shaft 310 connected to the drum body 220 and the gear member 320 is connected to the rotating shaft 310 on the side of the drum unit 200 is configured to rotate the rotating shaft 310 Control unit 300;
Including;
The bypass cable working member 400 is connected to the end of the insulation lifting belt 230,
The insulation lifting belt 230 is wound around the drum body 220 or unwound from the drum body 220 according to an operation of the controller 300.
The gear member 320,
Case 321;
A worm wheel 322 provided inside the case 321 and coupled to the rotation shaft 310 to rotate together with the rotation shaft 310; And
A worm 323a corresponding to the worm wheel 322 is formed at a portion located inside the case 321, and an impression adjusting knob 323b is formed at one end of the case 321 located outside. A worm shaft 323;
Bypass cable pulling device for indirect live work, characterized in that it is included.
The method of claim 7, wherein
The drum cover 210,
One or a plurality of fixing grooves 210a are formed along the circumferential direction of the rotation shaft 310 so that the case 321 is fixed.
The gear member 320,
Bypass cable pulling apparatus for indirect live work, characterized in that the index plunger 324 corresponding to the fixing groove (210a) is provided.
In the bypass cable installation method using the bypass cable pulling apparatus for indirect live work according to any one of claims 2 to 8,
A work preparation step (S10) of preparing a bypass cable pulling device and a bypass cable work member 400 on a power supply side and a load side of the power line 500 in a live state;
A pulling device installation process of installing the clamp unit 100 of the bypass cable pulling apparatus for live work on a power line 500 at a power supply side and a load side for each phase (S20);
By-passing the insulation lifting belt 230 of each installed bypass cable pulling device for live work, connects the bypass cable work member 400, and again raises the insulation lifting belt 230 of the bypass cable pulling device for live work. Pass cable preparation process (S30);
The elevated bypass cable work member 400 is installed on the power line and the load-side encapsulated power line 500 'by phase to connect and energize the power line 500 and the bypass cable work member 400 to the power line. Bypass cable installation process for connecting the bypass cable 500 and the bypass cable working member 400 (S40);
A jumper wire separation process (S50) of separating the jumper wires on both sides of the work section after bypass connecting the power line 500 and the bypass cable work member 400;
After the jumper wire is separated, a distribution facility process (S60) for performing a diagonal work in a working section in a diagonal state;
A jumper wire connecting step of connecting the jumper wires on both sides of the work section after the power distribution work (S70);
Bypass separating the bypass cable work member 400 installed in each phase on the enclosed power line 500 'on the power supply side and the load side, and separating the bypass cable work member 400 from the insulation lifting belt 230. Cable separation process (S80);
A finishing step (S90) of separating the clamp unit 100 of the bypass cable pulling apparatus for live work installed on each of the power lines 500 at the power supply side and the load side, and arranging the site;
Bypass cable installation method using a bypass cable pulling device for indirect live work comprising a.

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