KR101955155B1 - Uninterruptible power method and Indirect live lifting device for Electronic pole for power line - Google Patents

Abstract

The present invention relates to an indirect live wire lifting device. More specifically, in order to cope with the policy change of the uninterrupted work and to perform the uninterrupted work through the safe indirect live wire work, an elevating bar is moved up and down by an elevating actuation unit which is installed on an electric pole to electrically operate and a horizontal bar having an electric wire cable roller is horizontally moved to the left and right by a horizontal actuation unit which is electrically operated. It is possible to freely adjust the up and down position and the left and right horizontal position of the live wire installed on the electric wire cable roller. In addition, it is possible to perform the lifting operation in a state in which the live wire is securely latched to the electric wire cable roller so that a sufficient space may be ensured in the wire replacement process. An accident caused by the live wire can be prevented, a long post cross-arm or a strain pole cross-arm can be used as necessary and it is possible to perform the construction by changing a pin pole into a double pole. Since a sufficient space can be ensured in the process of replacing a cross-arm, the efficiency of use can be increased. In addition, the live wire lifting operation is convenient because live wires are lifted at a time.

Description

Technical Field [0001] The present invention relates to an indirect live lifting device for an electric power line and an indirect live lifting device for an electric pole for power line,

The present invention relates to an indirect live wire lifting device, and more particularly, to an indirect live wire lifting device for performing an indirect live wire operation in the course of performing an uninterruptible power supply without power interruption, To an indirect live-wire lifting device for a distribution line and an indirect live-line uninterruptible power supply method using the same.

The conventional uninterruptible power distribution system consists of a mobile transformer car method, a by-pass cable method, and a construction switch-off method. However, the bypass cable method includes a cable car, a cable necessary for a work section, It is equipped with a mobile transformer car, a live wire basket truck and a luminaire working air port. Bypass cable is installed by direct live operation to bypass power supply, It is necessary to dismantle the bypass cable in the job live job to complete the distribution work.

In addition, in the case of distribution lines with electric capacity exceeding 5,000 KW, since the existing capacity of cable for existing method is less than 5,000 KW when using existing bypass cable method, in order to reduce the capacity of distribution line to less than 5,000 KW In addition, there is a serious problem in the operation of the system of an effective distribution line, and in particular, in the case of a distribution line having two or more lines in one pole, the operation of the upper distribution line is in actual operation There is a problem that construction is not possible with the uninterrupted method.

In order to solve the above problems, the applicant of the present invention has found that, as in the Utility Model Application Registration No. 20-0252786, in the case of using the electric wire twisting device and wire twisting device in Jeonju, And the uninterrupted operation was carried out directly on the live line.

However, in the uninterrupted operation as described above, the electric wire can be separated and connected only within a certain range in which the arm body pivots by the direct live wire operation, and the limit of the lifting range of the live wire is limited. And it is impossible and ineffective as an indirect live-wire operation in the process of replacing the electric pole.

In addition, it is changing to a policy of gradual elimination of uninterrupted work through the direct live operation in the near future, and the implementation of uninterrupted work using indirect live work, and it is urgent to improve the non-correction work using such indirect live work .

Korean Utility Model Registration No. 20-0252786.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and it is an object of the present invention to provide a method and apparatus for preventing unintended operation of an unmanned operation by means of a lifting operation unit mounted on a pole, The horizontal movement of the horizontal bar having the twisted rollers is enabled through the lower lifting and lowering operation and the horizontally operating portion that is electrically operated to freely adjust the upper and lower positions and the left and right horizontal positions of the live wire installed on the twisted roller The present invention provides an indirect live wire lifting device for a distribution line and an indirect live wire uninterruptible power supply method using the indirect live wire lifting device.

In addition, by enabling lifting operation in a state where the live wire is securely latched to the twist roller, it is possible to secure a sufficient work space in the course of replacement of the wire and electric pole, thereby preventing a safety accident caused by direct live operation The present invention also provides an indirect live wire lifting device for a distribution line and an indirect live wire uninterrupted method using the same.

In addition, it is possible to change the construction of the reinforcement in the pin shaft as well as the use of the semi-permanent shaft or the inner shaft in accordance with the necessity, Another object of the present invention is to provide an indirect live wire lifting device for a distribution line and an indirect live wire uninterruptible power supply method using the indirect live wire lifting device.

In addition, for the indirect live line work for each phase, the indirect live line lifting device for the distribution line and the indirect live line uninterrupted method using the same for making the live wire lifting work more convenient by raising the three phases at a time by the indirect live wire work And it is a further object of the present invention.

As a concrete means for achieving the above object, there is provided a clamping device comprising a clamp base having a semicylindrical groove for holding one side of a pole, at least one step formed with a clamping base corresponding to the clamp base and corresponding to the pole- A mounting portion formed by the above-mentioned binding portion and attached to the periphery of the electric pole;

An elevating operation portion formed on the mounting portion for controlling the upper and lower elevating and lowering rivers of the elevating bar; And

And a horizontal operating part configured to connect upper ends of the two side elevating bars and to ascend and descend together with the elevating bar and to control the horizontal bar horizontal operation,

The lift bar,

The upper and lower raising and lowering operation is performed by the operation of the raising and lowering operation unit, and each of the raising and lowering racks is formed, and the lower end of the raising and lowering operation unit is connected to the raising and lowering bar connection And,

The horizontal bar,

A pair of left and right horizontal operation units connected to the horizontal operation unit and operated horizontally in the left and right directions,

In the horizontal bar,

Further comprising at least one insulated twist roller capable of guiding the live wire,

The insulation twist roller,

And a live wire guide portion in which a live wire is passed through the upper portion and the live wire is guided by a horizontal roller and a vertical roller.

INDUSTRIAL APPLICABILITY As described above, the indirect live-wire lifting apparatus for a distribution line according to the present invention and the indirect live-wire uninterrupted method using the same are capable of freely adjusting the upper and lower heights and the left and right clearances through the lifting operation unit and the horizontal operation unit , It is possible to freely adjust the upper and lower positions of the live wire installed on the twisted roller and adjust the horizontal position to the left and right, and the position of the live wire can be controlled very easily by the indirect live wire operation.

In addition, it is ensured that a sufficient indirect live working space is ensured in a state in which the live wire is safely accommodated in the twist roller. In the indirect live wire lifting process, the flow of the live wire, It is possible to obtain an effect of securing safety such as prevention of electric shock accident caused by contact with a live wire due to direct live operation.

In addition, it is possible to select a plurality of horizontal moving bands. In addition, it is possible to use a moving bell main body or a built-in bell, as well as to change the bell main body in the bell main body, It is possible to obtain an effect of further improving the safety.

In addition, each of the live wires is inserted and connected to an insulated twisted roller formed on the horizontal bar. As a result, the operation of lifting the live wires of each phase or a plurality of live wire wires at a time is possible. Effect can be obtained.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exploded perspective view of an indirect live line lifting device for a distribution line according to the present invention. FIG.
Fig. 2 is a perspective view of the indirect live-wire lifting device for the distribution line of the present invention; Fig.
3 is a view of a mounting portion of an indirect live line lifting device for a distribution line of the present invention.
4 is a perspective view of a mounting portion of an indirect live-line lifting device for a distribution line according to the present invention.
5 is a main part view of a lifting operation part of an indirect live line lifting device for a distribution line according to the present invention.
6 is a main part view of an elevating operation part of an indirect live line lifting device for a distribution line according to the present invention.
7 is a longitudinal sectional view of a horizontal operation part of an indirect live line lifting device for a distribution line according to the present invention.
8 is a schematic view of a horizontal operation portion of an indirect live line lifting device for a distribution line according to the present invention.
Fig. 9 is an explanatory view of an insulated twist roller of an indirect live wire lifting device for a distribution line according to the present invention. Fig.
10 is another embodiment of an indirect live-line lifting device for a distribution line of the present invention.
Fig. 11 is a mounting state of an indirect live-line lifting device for a distribution line according to the present invention. Fig.
Fig. 12 is an elevational view of a lifting operation of an indirect live line lifting device for a distribution line according to the present invention.
13 is a horizontal operation state view of an indirect live line lifting device for a distribution line according to the present invention.
Fig. 14 is a state view of the indirect-live-line lifting device for a distribution line according to the present invention.
15 is a view showing a state of use of a two-stage line of an indirect live-line lifting device for a distribution line of the present invention.
16 to 20 are schematic views of a first embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
21 to 25 are schematic views of a second embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
26 to 30 are schematic views of a third embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
31 to 35 are schematic views of a fourth embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
36 to 40 are schematic views of a fifth embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
41 to 45 are schematic views of a sixth embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
46 to 50 are schematic views of a seventh embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
51 to 55 are schematic views of an eighth embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
56 to 60 are schematic views of a ninth embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
61 to 65 are schematic views of a tenth embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
66 to 70 are schematic views of an eleventh embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
71 to 75 are schematic views of a twelfth embodiment showing an indirect live line uninterrupted method using an indirect live line lifting device for a distribution line of the present invention.
76 shows a first embodiment of the electric pole replacement state of the indirect live line uninterruptible power supply method using the indirect live line lifting apparatus for distribution lines of the present invention.
FIG. 77 is a second electric pole replacement state of the indirect live line uninterruptible power supply method using the indirect live wire lifting apparatus for distribution lines of the present invention. FIG.
78 shows the first embodiment of the state in which the indirect live line uninterrupted method using the indirect live line lifting device for distribution lines of the present invention is installed.
79 is a second embodiment of the state in which the second embodiment of the second embodiment of the indirect live line uninterrupted method using the indirect live line lifting device for the distribution line of the present invention is installed.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

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

First, according to the indirect live-line lifting device for a distribution line of the present invention,

FIG. 1 is an exploded perspective view of an indirect live-wire lifting device for a distribution line according to the present invention, and FIG. 2 is an assembled perspective view of an indirect live-line lifting device for a distribution line of the present invention.

As shown in FIGS. 1 and 2, the indirect live-wire lifting device for a distribution line of the present invention includes a mounting portion 100, an elevating operation portion 200, and a horizontal operation portion 300.

First, the mounting portion 100 is configured to be able to mount the indirect-live-line pulling-up device 1 for distribution lines of the present invention on the electric pole and to be attached thereto.

At this time, the mounting portion 100 is composed of the clamp base 110 and the binding portion 120 with reference to FIG. 3 and FIG.

First, the clamp base 110 is formed as a base of the mounting portion 100, and has a vertical length. The clamp base 110 is formed in a planar semicircular tube shape to constitute a preform placement groove 111 so as to surround one side of the preform.

The binding unit 120 is configured to be coupled to the clamp base 110 and to surround the other side of the circumference of the electric pole. The binding unit 120 has an electric pole binding groove 121, which corresponds to the pole placing groove 111 of the clamp base 110, And formed in a planar semicircular tube shape.

In this case, the coupling between the clamp base 110 and the binding portion 120 is not limited. For example, one end of the clamp base 110 may be connected to a hinge (not shown in the figure) A flange portion (not shown in the figure) that can be coupled to both ends of the base 110 and the binding portion 120 can be formed.

The clamp base 110 and the binding unit 120 are configured to be lockable with respect to each other. The clamp base 110 and the binding unit 120 are not limited to the locking structure applied thereto, but may be a bolt fastening or a pressure fastening And the like.

In this case, at least the upper and lower ends of the clamping unit 120 may be constituted by the clamping base 110. In the embodiment of the present invention, the clamping base 110 has two stages at the upper and lower ends of the clamping base 110 .

That is, the mounting portion 100 can be mounted on the pole by locking the pole in a state where the pole is wrapped around the pole base through the pole base 111 and the pole fixing groove 121 of the clamp base 110 and the binding portion 120 .

The mounting portion 100 may further include a first pressing portion 130 and a second pressing portion 140 to provide a more rigid fixing force in the course of binding the pole as described above.

The first pressing part 130 is formed in the clamp base 110 and is capable of pressing and fixing the pole together with the clamp base 110. The first pressing part 130 and the first pressing part 132, And a first adjustment bolt 133.

At this time, the first guider 131 is formed in the clamp base 110, and has a block shape having a first guide groove 131a opened to one side of the pole guide groove 111 at one side.

The first pressing member 132 is slidable into and out of the first guide groove 131a of the first guider 131 and opened to the side of the pole guide groove 111. The tip 132a is formed at the tip of the first pressing member 132, So that the electric pole can be pressed.

The first adjusting bolt 133 is inserted into the rear end of the first guider 131 and enters the inside of the first guide groove 131a. The first pressing member 132 is inserted into the leading end of the first adjusting bolt 133, So as to have a free rotational force.

Thus, the first pressing part 130 is advanced by the first pressing bolt 133 by the first adjusting bolt 133, so that the electric pole can be pressed and fixed through the tip part 132a.

At least one of the first pressing portions 130 may be formed in the clamp base 110. In the embodiment of the present invention, two clamping bases 110 are formed at the upper and lower ends of the clamp base 110, respectively.

The second pressing unit 140 is configured to be capable of being pressed and fixed together with the binding unit 120. The second pressing unit 140 includes a second pressing unit 142 and a second pressing unit 142, And a second adjustment bolt 143.

At this time, the second guider 141 is formed in the binding part 120 and has a block shape in which a second guide groove 141a opened to one side of the binding groove 121 is formed.

The second urging member 142 is slidably fitted in the second guide groove 141a of the second guider 141 and is slidable toward and away from the pole engaging groove 121. The tip of the second urging member 142 is in close contact with the pole, And a V-groove 142a is formed so as to be able to press-contact the pole.

The second adjusting bolt 143 is inserted into the rear end of the second guider 141 and enters the inside of the second guide groove 141a and the second pressing member 142 is inserted into the leading end of the second adjusting bolt 143, So as to have a free rotational force.

The second pressing member 140 is inserted into the second pressing member 142 by the second adjusting bolt 143 so that the electric pole can be tightly fixed around the V groove 142a.

The second pressing portion 140 is formed at the center of the binding portion 120 at each of the upper and lower ends of the binding portion 120. The second pressing portion 140 includes two first pressing portions 130 and the second pressing part 140 are arranged at intervals of 120 degrees so that the same pressing force is applied to the circumference of the rotor.

That is, the mounting portion 100 is provided with a fixing portion for fixing the connection portion 100 between the clamp base 110 and the binding portion 120 when the indirect live-wire lifting device for the distribution line of the present invention is mounted on the electric pole and the first pressing portion 130, The first pressing portion 130 and the second pressing portion 140 can be pressed and fixed by the first pressing member 132 and the second pressing member 142 So that it can be applied variously according to the diameter of the electric pole.

The elevating operation unit 200 is configured to intermittently ascend and descend the elevating bars 210 and 210 'in constructing the indirect live-line lifting device 1 for a distribution line according to the present invention. FIGS. 5 and 6 A lifting / lowering case 220, a lifting / lowering box 230, a lifting / lowering driven shaft 240, and a lifting / lowering driving shaft 250 with reference to FIG.

First, the lifting unit case 220 is formed on the outer side of the clamping base 110 and has a hollow shape.

At this time, the elevating part case 220 is formed with a pair of elevating bar guide holes 221 on both sides through which the two side elevating bars 210 and 210 'penetrate and slide, And guide rollers 222 of multiple means for imparting a rolling force to the lift bars 210 and 210 'are formed on the inner sides of the guide rollers 222 on the opposite sides of the base 110.

The lift worm box 230 is configured to convert the horizontal turning force of the lift driving shaft 250 described below into a vertical turning force and has a box shape that is mounted on the clamp base 110 inside the lift case 220 And includes a lifting and lowering rotary shaft 231 and a lifting worm shaft 235.

In this case, the lifting / lowering shaft 231 has a horizontal length and a vertical rotation force. Both sides of the lifting and lowering case 220 are formed in the lifting unit case 220 to have a rotational force.

The upper and lower pinions 232 and 232 are provided on both sides of the lifting and lowering shaft 231 so as to engage with the lifting and lowering racks 211 and 210 of the lifting bars 210 and 210 ' The upper sprocket 233 is constituted.

The elevating worm shaft 235 has a vertical direction length and has a horizontal rotational force. The horizontal worm gear 235 has a horizontal interlocking spur gear 237 at its lower portion.

The worm box 230 is configured to convert the horizontal rotation force of the lift worm shaft 235 to the vertical rotation force of the lift rotation shaft 231. For this purpose, 231, the elevating worm gear is formed at the center thereof, and the elevating worm 235 can be constituted by an elevating worm that engages with the elevating worm gear.

The lifting and lowering coupling shaft 240 is constituted by a pair of both sides so as to correspond to both the upper pinions 232 and the upper sprocket 233 of the lifting and lowering shaft 231, And is configured to be interlocked with the lifting and lowering shaft 231.

At this time, the lower pinion 242, which is engaged with the elevating rack 211 together with the upper pinion 232, is formed in each of the elevating /

The lower sprocket 243 is connected to the upper sprocket 233 of the lifting and lowering shaft 231 through the chain 244. The lower sprocket 243 is connected to the upper sprocket 233, So as to have a connecting force with each other.

The lifting and lowering driving shaft 250 is vertically extended from one side of the lifting warm box 230. Upper and lower lifting and lowering driving coupling parts 250a and 250b And the elevation adjustment tool engaging portion 250a is configured to protrude from the upper portion and the lower portion of the elevation portion case 220. [

Further, a horizontal driving spur gear 252 is formed at the lower portion of the elevation driving shaft 250 to engage with the interlocking spur gear 237 of the elevating worm shaft 235.

The elevating bars 210 and 210 'are formed in the form of a "square bar" having upper and lower lengths. The elevating bars 210' are formed as a pair of two sides, And a lifting rack 211 is constructed.

At this time, the elevating bars 210 and 210 'pass through the elevating bar guide holes 221 formed at both sides of the elevating case 220 of the elevating operation part 200, while the elevating racks 211' Upper and lower pinions 232 and 242, respectively.

The elevating bars 210 and 210 'on both sides are connected to each other. The lower ends of the elevating bars 210 and 210' are connected to the elevating bar connecting rod 212. At this time, the elevating bar connecting rod 212 passes horizontally A fresh water insertion hole 213 is formed so that the fastener can penetrate and slide.

The horizontal operation part 300 is configured to intermittently move the horizontal bars 310 and 310 'to the left and right in configuring the indirect line lifting device 1 for the distribution line of the present invention. A first horizontal operation unit 330, and a second horizontal operation unit 340, as shown in FIG.

The horizontal part base 320 is configured to connect the upper ends of the lift bars 210 and 210 'on both sides and includes a lift bar fixing pipe 321' and a horizontal bar guide pipe 322 ' And a shaft portion 325,

At this time, the elevating bar fixing pipes 321 and 321 'are configured to be paired on both sides, and the upper ends of the elevating bars 210 and 210' are fixed to be penetrated and fixed.

The horizontal bar guide pipes 322 and 322 'are configured to connect the elevator bar fixing pipes 321 and 321' on both sides of the elevator bar fixing pipes 321 and 321 ' It is configured to connect both sides.

Each of the horizontal bar guide pipes 322 and 322 'is formed with a horizontal bar guide hole 323 through which horizontally extending bars 310 and 310' penetrate and slide in the center thereof .

Each of the horizontal bar guide pipes 322 and 322 'has a through hole 324 communicating with the horizontal bar guide hole 323 at a lower portion thereof. The through hole 324 is connected to the horizontal bar guide pipe 322, (322 ').

The axially tilted portion 325 is formed between the two side elevating bar fixing pipes 321 and 321 'and includes a first horizontal warm box 339 and a second horizontal warm box 349 And is configured to protrude downward from the horizontal part base 320.

The first horizontal actuating part 330 is configured on one side of the axle tilting part 325 and interrupts the horizontal operation of any one of the horizontal bars 310. The first horizontal actuating part 330 includes a first horizontal driving shaft 331, And a horizontal warm box 339.

At this time, the first horizontal driving shaft 331 is configured to vertically penetrate the shaft portion 325 to impart a horizontal rotational force, and a first tool engaging portion 331a is formed at the upper and lower ends thereof, The first driving spur gear 332 is configured to apply a rotational force to the first horizontal worm box 339.

The first horizontal worm box 339 is constituted by a first horizontal worm axis 333 and a first horizontal rotation axis 336.

The first horizontal worm axis 333 is configured to be vertically extended to the axis 325 to impart a horizontal rotational force. The first horizontal worm axis 333 is engaged with the first driving spur gear 332 A first interlocked spur gear 334 is constituted.

The first horizontal rotary shaft 336 is horizontally extended from the lower portion of the axial tilting portion 325 to impart a vertical rotational force to the first horizontal rotary shaft 336. The first horizontal rotary shaft 336 is coupled to a horizontal rack 311 of one of the horizontal bars 310, A first pinion 338 is formed.

At this time, the first pinion 338 is positioned below the horizontal bar guide pipe 322 on one side, while the first pinion 338 is inserted through the through hole 324 into the inner horizontal bar guide hole 323 of the horizontal bar guide pipe 322, As shown in FIG.

The first horizontal worm box 339 is configured to convert the horizontal rotation force of the first horizontal worm axis 333 into the vertical rotation force of the first horizontal rotation axis 336. For this purpose, A horizontal worm may be formed at the center of the first horizontal worm axis 333 and a horizontal worm gear may be formed at the first horizontal rotation axis 336 to mate with the horizontal worm.

The second horizontal operation unit 340 is configured to be separated from the first horizontal warm box 339 so as to be spaced apart from the first horizontal warm box 339 so as to control the horizontal operation of the other horizontal bar 310 ' A second horizontal drive shaft 341, and a second horizontal warm box 349.

At this time, the second horizontal drive shaft 341 is configured to vertically penetrate the shaft portion 325 to impart a horizontal rotational force, and a second tool engagement portion 341a is formed at the upper and lower ends thereof, The second driving spur gear 342 is configured to apply a rotational force to the second horizontal warm box 349 to be formed.

The second horizontal worm box 349 is composed of a second horizontal worm shaft 343 and a second horizontal rotation shaft 346.

The second horizontal worm shaft 343 is configured to be horizontally rotatable by being vertically extended to the spindle 325. The second horizontal worm shaft 343 is engaged with the second driving spur gear 342, A second interlocking spur gear 344 is formed.

The second horizontal rotary shaft 346 is horizontally extended from the lower portion of the axial tilting portion 325 to impart a vertical rotational force and has a horizontal rack 311 of another horizontal bar 310 ' And a second pinion 338 to be engaged is formed.

At this time, the second pinion 338 is positioned below the horizontal bar guide pipe 322 'on the other side, while the second pinion 338 is inserted through the through hole 324 into the inner horizontal bar guide hole 322' 323, respectively.

The second horizontal worm box 349 is configured to convert the horizontal rotation force of the second horizontal worm shaft 343 into the vertical rotation force of the second horizontal rotation shaft 346. For this purpose, A horizontal worm may be formed at the center of the second horizontal worm axis 343 and a horizontal worm gear may be formed at the second horizontal rotation axis 346 to engage with the horizontal worm.

The horizontal bars 310 and 310 'are formed in the form of a "square bar " having left and right lengths. Each of the horizontal bars 310 and 310' has a pair of left and right sides. A rack 311 is constructed.

At this time, the horizontal bars 310 and 310 'pass through the horizontal bar guide holes 323 formed in the horizontal bar guide pipes 322 and 322' of the horizontal operation unit 300, And the first pinion 331 and the second pinion 338 are engaged with each other.

That is, the horizontal bars 310 and 310 'are moved to the left and right by the operation of the horizontal operation unit 300 so that the horizontal bars 310 and 310' can extend in the left and right directions.

9, at least one or more insulation twist rollers 400 capable of guiding a live wire are further provided on the horizontal bars 310 and 310 'in the construction of the indirect live wire lifting device 1 for a distribution line of the present invention . ≪ / RTI >

At this time, the insulation twist roller 400 is not limited, but a conventional fastening clamp 410 is formed at the lower portion so that it can be selectively mounted on the horizontal bars 310 and 310 ' And the upper portion may be constituted by a live wire guide portion 420 through which the live wire is inserted and guided by the opening and closing operation.

That is, the insulated twist roller 400 is configured to be mounted on the horizontal bars 310 and 310 'and to receive the live wire in the live wire guide part 420. For example, the live wire guide part 420 may be formed by the applicant of the present invention A vertical roller 423 vertically formed on both sides of the lower body 421a and a vertical roller 423 vertically formed on both sides of the lower body 421a, as shown in the registered Utility Model Registration No. 20-0381079, And an upper body 421b having a horizontal roller 422 which is connected to a hinge (not shown in the drawing) and is rotatable so as to open and close between the two vertical rollers 423 and to be locked to the other vertical roller 423 It will be possible.

The wire 430 is received in the horizontal bar 310 and 310 'according to the amount of the live wire by the clamp 410. The wire 430 is received in the horizontal bar 310, Lt; RTI ID = 0.0 > 310 '. ≪ / RTI >

As described above, the directionality of the live wire guide part 420 of the insulated twisted roller 400 mounted on the horizontal bars 310 and 310 'can be adjusted by selecting the upper and lower sides of the horizontal bars 310 and 310' It will be possible.

On the other hand, when the indirect live-wire lifting device 1 according to the present invention is installed on the electric pole, two indirect live-wire lifting devices 1 can be installed symmetrically on the electric pole with reference to FIG. 10,

At this time, the two clamp bases 110 corresponding to the respective mounting portions 100 may be wrapped around the pole, and the clamp bases 110 on both sides thereof may be fixedly coupled to each other.

Both ends of the horizontal bar 310 opposed to the symmetrical horizontal actuating part 300 can be connected to the horizontal bar connecting part 350. The horizontal bar connecting part 350 May be configured to be coupled to the horizontal bar 310 through conventional bolting or the like.

Hereinafter, the operation of the indirect live-line lifting device for a distribution line according to the present invention will be described in detail with reference to the accompanying drawings.

In order to secure a safe and sufficient working space by raising the extra high voltage power line (live wire) by the indirect live wire work in the process of changing or replacing the electric wire in the process of uninterrupted operation of the electric wire of the present invention, , And the impression of such a live line is made possible by the lifting and the left and right movement of the live line.

In order to replace the wire and the electric pole in the embodiment, the indirect live wire lifting device 1 for a distribution line of the present invention may be installed in a pole provided with a wire to be replaced.

11, the indirect live-line lifting device 1 for a distribution line according to the present invention is installed at the upper end of the electric pole 10 through the mounting portion 100, The circumferential side of the electric pole 10 is wrapped around the electric pole groove 111 of the clamp base 110 in a state where the binding part 120 is opened from the clamp base 110 and the electric pole fixing groove 121 of the binding part 120 The other side of the electric pole 10 can be mounted and locked by locking it.

At this time, it is possible to mount the mounting portion 100 more firmly when the mounting portion 100 is mounted on the electric pole, which is possible by the first and second pressing portions 130 and 140.

The second pressing member 140 is used to support one side of the electric pole 10 so that the second pressing member 142 is fixed by tightening the second adjusting bolt 143 of the second pressing member 140, And the V-grooves 142a support one side of the electric pole 10.

The first pressing portion 130 is then used to advance the first pressing member 132 by fastening the first adjusting bolt 133 and to advance the tip 132a formed at the tip It is sufficient to press the periphery of the electric pole 10.

That is, in the embodiment of the present invention, a plurality of first pressing portions 130 and a single second pressing portion 140 are formed at intervals of 120 degrees, and by uniformly pressing and fixing the circular perimeter of the electric pole 10, 100 can be mounted more firmly.

In order to pull up the live wire, the extra-high voltage power line 12 opens the live wire guide portion 420 of the insulation twist roller 400 and receives the extra-high voltage power wire 12 to prevent the live wire from flowing.

Thereafter, the lifting of the live wire is performed. Such lifting of the live wire is made possible by the upward, downward lift and leftward and rightward extension movements.

First, the up-and-down lifting and lowering is enabled by the lifting and lowering operation part 200.

Referring to FIGS. 5 and 6, in the elevating operation unit 200, as shown in FIG. 12, an elevating / lowering adjusting tool engaging portion 250a protruding to the upper portion and the lower portion of the elevating portion case 220, The elevating drive shaft 250 is rotated and its rotational force is transmitted to the interlocking spur gear 237 through the driving spur gear 252 to rotate the elevating worm shaft 235. The rotational force The rotation direction of the lift worm box 230 is changed and the elevation / descent rotation shaft 240 connected to the chain 244 is rotated.

The elevating bars 210 and 210 'engaged with the upper and lower pinions 232 and 242 and the elevating and lowering racks 211 are operated to move upward and downward. At this time, the elevating bars 210 and 210 'May be changed according to the direction of rotation of the lifting drive shaft 250.

That is, when the elevating bars 210 and 210 'are lifted up, the extra high voltage power line 12 connected to the insulation twisting roller 400 is lifted upward together with the elevating bars 210 and 210' The power line 12 becomes detachable from the base 20.

In addition, the extra high voltage power line 12 pulled up as described above can be moved in the left and right direction as needed, which is enabled by the horizontal operation unit 300.

Referring to FIGS. 7 and 8, a pair of horizontal bars 310 and 310 'on both sides of the first horizontal operation part 330 and the second horizontal operation part 340, as shown in FIG. 13, Each of which can be extended and moved by operation.

In this case, when the first horizontal actuating part 330 attaches a separate tool to the first tool engaging part 331a protruding to the upper and lower parts of the first horizontal driving shaft 331 and applies rotational force thereto, The first horizontal spiral gear 331 is rotated and its rotational force is transmitted to the first associated spur gear 334 through the first driving spur gear 332 to rotate the first horizontal worm axis 333, The rotation direction of the worm box 339 is changed to rotate the first horizontal rotary shaft 336 in the vertical direction.

Thus, any one of the horizontal bars 310 engaged with the first pinion 338 and the horizontal rack 311 horizontally moves left and right.

In addition, the second horizontal operation portion 340 is provided with the second horizontal driving shaft 341 and the second horizontal driving shaft 341 when the second tool engagement portion 341a, which protrudes to the upper and lower portions of the second horizontal driving shaft 341, 341 is rotated and its rotational force is transmitted to the second cooperating spur gear 344 through the second driving spur gear 342 to rotate the second horizontal worm shaft 343, The rotation direction of the worm box 349 is switched to rotate the second horizontal rotary shaft 346.

Thus, the other horizontal bar 310 ', which is engaged with the second pinion 338 and the horizontal rack 311, is horizontally moved left and right.

In other words, the horizontal operation part 300 is configured such that the first horizontal warm box 339 and the second horizontal warm box 349 are operated respectively. Through these respective operations, the horizontal bars 310 and 310 ' So that the extra-high voltage power line 12 can be extended to the outside of the wire net.

As described above, the indirect live-wire lifting device (1) for the distribution line according to the present invention requires the operator to carry out dangerous work by using a tool such as a hand or a separate stick as a live wire work, , The safety work space is ensured by raising the three-phase live wire at once and expanding to the left and right without having to individually raise by using the indirect live wire method to be described later by using the indirect live wire tensioning device (1) for distribution line, Safe operation becomes possible.

Meanwhile, the indirect live-wire lifting device for lifting the live wire as described above according to the present invention is applicable to the shape of the longitudinal groove in the application of the electric wire to the left and right moving operations of the horizontal bars 310 and 310 ' .

11 to 13, when the pin 20 is positioned at the center of the electric pole 10, the horizontal bars 310 and 310 ' The same ratio may be applied to the two sides of the second side 10,

14, when the wire 20 is eccentrically positioned on one side of the electric pole 10, the horizontal bars 310 and 310 'may be positioned in the same direction as the wire 20, It may be adjusted by projecting and eccentric to one side of the base 10.

On the other hand, when the indirect live-wire lifting device 1 for a distribution line according to the present invention is applied to a traveling state as described above, the elevating and lowering of the extra-high voltage power line 12 can be adjusted only by lifting and lowering.

In addition, the indirect live-line lifting device 1 for a distribution line according to the present invention uses a wax 20 'that is to be replaced while lifting the wax 20 in the process of replacing the wax 20, It can be inserted and stored in the filler insert hole 213 of the lift bar connecting rod 212 connecting the lower ends of the lift bars 210 and 210 '. Thus, it is possible to easily handle the filler without any additional device.

The indirect live-wire lifting device 1 for a distribution line according to the present invention is a device for lifting up the wire 20 'to be replaced in the process of replacing the wire 20 in the two-wire two- The lifting action of the bottom live wire of the wax to be replaced at this time is performed by the lifting bar connecting rod 212 connecting the lower ends of the lifting bars 210 and 210 ' It is possible to insert another horizontal bar (not shown in the figure) into the bill insertion hole 213 and to pull up the bill insertion hole 213 so that the two-step line work can be easily performed without changing the apparatus, It is possible to perform the indirect live-line operation.

As described above, according to the present invention, the indirect live-line lifting device for an electric distribution line of the present invention is capable of lifting and lowering the electric wire in the uninterrupted power supply process, replacing the electric wire and replacing the electric wire, , It is possible to extend the rightward movement and secure sufficient working space necessary for the construction, and it is possible to perform a safe and convenient indirect lifting operation of the live wire.

Hereinafter, an indirect live wire uninterruptible power supply method using the indirect live wire lifting device for a distribution line according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 14, the indirect live line uninterrupted method using an indirect live line lifting device for a distribution line according to the present invention is characterized in that, in the process of changing the electric pole, replacing the electric pole, and changing the electric pole of the electric pole, And the change of the electric pole, the electric pole pole and the change of the electric pole pole can be changed in various embodiments according to the change of the kind or the progress point of the pole pole, built-in pole, .

Accordingly, referring to the embodiment,

* Example 1

Referring to FIGS. 16 to 20, uninterrupted work can be performed by using the indirect line lifting device 1 for the distribution line in order to equally replace the insulator and insulator of the pin rail during the construction work with the uninterrupted power distribution line.

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 on the electric pole 10 by covering the electric pole 10 from the lower portion of the existing pin shaft 11 by using the mounting portion 100.

Thereafter, a position adjustment process is performed,

This is possible by actuating the lifting operation part 200 and the horizontal operation part 300 by using a stick for normal live work (not shown in the figure).

The lifting and lowering operation of the lifting and lowering operation part 200 is controlled so that the horizontal bars 310 and 310 'are lowered under the extra high voltage power line Position.

Then, the horizontal operation unit 300 is operated so that the insulation twist roller 400 is positioned close to the extra-high voltage power line 21 through the left and right control of the horizontal bars 310 and 310 ' It will be appreciated that the rollers 400 are installed at regular intervals in consideration of the spacing of the extra-high voltage power lines 21 installed.

Thereafter, the power line separation and separation process is performed,

The operator opens the live wire guide portion 420 of the insulation twist roller 400 using a normal live wire stick (not shown in the figure) and uses the stick for live wire work to connect the extra high voltage power wire 21 to the live wire guide portion 420 and the live wire guide part 420 may be closed.

Then, the worker removes the binding of the elbow insulator by using a stick for normal live work (not shown in the figure) and activates the lifting operation part 200 to lift the lifting bars 210 and 210 ' The horizontal bar 310 and the horizontal bar 310 are separated from the elbow insulator so that the horizontal bar 310 and the horizontal bars 310 and 310 ' It is necessary to raise the separation distance without a safe distance.

Thereafter, a long-period replacement process is performed,

This is because the operator removes the existing pin shaft 11 and the elbow insulator from which the extra-high voltage power line 21 has been removed, installs a new pin shaft 11 'to be replaced at a position where the existing pin shaft 11 is removed, The installation process of the new pin shaft 11 'is not newly implemented, but a new shaft replacement method using an ordinary band (not shown) may be applied.

Thereafter, the power line installation process is performed,

This is possible by the operation of the lifting operation part 200 and the horizontal operation part 300 in the reverse order of the separation of the extra-high voltage power line 21.

The horizontal bar 310 and 310 'may be pulled by operating the horizontal operation unit 300 so that the extra high voltage power line 21 is positioned above the elbow insulator of the new pin long bar 11'.

Then, the elevating operation unit 200 is operated again to lower the elevating bars 210 and 210 'and to place the extraordinary high voltage power line 21 on the elbow insulator, thereby binding and fixing the elevating bar 210 and 210'.

Thereafter, the lifting device demolition process is performed,

This is achieved by first moving the lifting bars 210 and 210 'down and moving the horizontal bars 310 and 310' by operating the lifting operation part 200 in a state where the live wire guide part 420 of the insulation twisting roller 400 is opened. The horizontal bar 310 and the horizontal bar 310 'are automatically separated from the extra high voltage power line 21 when the horizontal bars 310 and 310' are lowered. ) To the safety clearance.

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Therefore, it is possible to replace the pin rail during the uninterrupted operation by using the indirect line lifting device for the distribution line through a series of processes.

* Example 2

21 to 25, uninterrupted work can be carried out by using an indirect live wire lifting device (1) for distribution lines in order to change the pin feeder into a single built-in type lightening iron core in the course of construction with uninterrupted power distribution lines.

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 on the electric pole 10 by covering the electric pole 10 from the lower portion of the existing pin shaft 11 by using the mounting portion 100.

This is achieved by installing the indirect live-wire lifting device 1 on the electric pole 10 by covering the electric pole 10 with the use of the mounting portion 100.

Thereafter, a position adjustment process is performed,

This is possible by actuating the lifting operation part 200 and the horizontal operation part 300 by using a stick for normal live work (not shown in the figure).

The lifting and lowering operation of the lifting and lowering operation part 200 is controlled so that the horizontal bars 310 and 310 'are lowered under the extra high voltage power line Position.

Then, the horizontal operation unit 300 is operated so that the insulation twist roller 400 is positioned close to the extra-high voltage power line 21 through the left and right control of the horizontal bars 310 and 310 ' It will be appreciated that the rollers 400 are installed at regular intervals in consideration of the spacing of the extra-high voltage power lines 21 installed.

Thereafter, the power line separation and separation process is performed,

The operator opens the live wire guide portion 420 of the insulation twist roller 400 using a normal live wire stick (not shown in the figure) and uses the stick for live wire work to connect the extra high voltage power wire 21 to the live wire guide portion 420 and the live wire guide part 420 may be closed.

Then, the worker removes the binding of the elbow insulator by using a stick for normal live work (not shown in the figure) and activates the lifting operation part 200 to lift the lifting bars 210 and 210 ' The horizontal bar 310 and the horizontal bars 310 and 310 'are extended to both sides of the bar so that the extra high voltage power line 21 is separated from the elbow insulator, Raise to safe distance without live wire interference.

Thereafter, a long-period replacement process is performed,

This is because the operator removes the existing pin shaft 11 from which the extra-high voltage power line 21 is separated and installs a single built-in light guide iron at the position where the existing pin shaft 11 is removed, The installation process of the new built-in main lid 12 'is not newly implemented, but can be applied to a replacement process using a conventional band.

Thereafter, the power line fixing process is performed,

This is accomplished by first providing the joists 30 on both sides of the new built-in main body 12 '.

When the extra-high voltage power line 21 is moved to the lower position of the installed girder 30 through the operation of the elevating operation unit 200 and the horizontal operation unit 300 in the reverse order of separation of the extra high voltage power line 21 do.

The elevating operation unit 200 may be operated to lower the elevating bars 210 and 210 'and to bring the extraordinary high voltage power line 21 close to the double girder 30.

Then, the horizontally operating part 300 is operated to pivot the horizontal bars 310 and 310 'so that the extra-high voltage power line 21 is brought close to the main line 30.

Both sides of the extra high voltage power line 21 are held and fixed by using the double side girder 30 around the electric pole 10 and the extra high voltage power lines 21 on both sides are fixed to the new jumper line 42 And short the existing short extra high voltage power line to complete the jumper of the new built-in main body 12 '.

At this time, it is a matter of course that the special high-voltage power line 21 to be fixedly connected is provided with a dead-end clamp at its end and a suspending insulator formed in the built-in lead 12 '.

Thereafter, the lifting device demolition process is performed,

This separates the joiner 30 from the extra-high voltage power line 21 first.

The lifting and lowering operation unit 200 is operated to lower the lifting bars 210 and 210 'and lower the horizontal bars 310 and 310' while the live wire guide unit 420 of the insulation twisting roller 400 is opened. Voltage power line 21 to the lower side.

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Therefore, it is possible to change the built-in built-in light-weight iron built-in mains by using the indirect lifting line lifting device for distribution lines through a series of processes.

* Example 3

26 to 30, uninterrupted work can be carried out by using an indirect live wire lifting device (1) for distribution lines in order to change the pin main shaft to the double built-in main shaft in the process of uninterrupted distribution line construction.

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 on the electric pole 10 by covering the electric pole 10 from the lower portion of the existing pin shaft 11 by using the mounting portion 100.

Thereafter, a position adjustment process is performed,

This is possible by actuating the lifting operation part 200 and the horizontal operation part 300 by using a stick for normal live work (not shown in the figure).

The lifting and lowering operation of the lifting and lowering operation part 200 is controlled so that the horizontal bars 310 and 310 'are lowered under the extra high voltage power line Position.

The worker removes the binders of the elbows using normal sticks for live work (not shown) and operates the horizontal operation part 300 to adjust the left and right adjustments of the horizontal bars 310 and 310 ' The insulation twist roller 400 may be disposed at a predetermined interval in consideration of the spacing of the extra high voltage power lines 21 installed in the insulation twist roller 400. In this case, something to do.

Thereafter, the power line separation and separation process is performed,

The operator opens the live wire guide portion 420 of the insulation twist roller 400 using a normal live wire stick (not shown in the figure) and uses the stick for live wire work to connect the extra high voltage power wire 21 to the live wire guide portion 420 and the live wire guide part 420 may be closed.

Then, the elevating operation unit 200 is operated again to lift the elevating bars 210 and 210 'upward and separate upward the extra-high voltage power line 21 from the elbow insulator, and successively operate the horizontal operating unit 300 to horizontally The bars 310 and 310 'may be opened on both sides so that the extra-high voltage power line 21 is separated from the worker's safe distance without the interference of the live wire during the replacement of the mains.

Thereafter, a long-period replacement process is performed,

This is because the operator removes the existing pin shaft 11 from which the extra-high voltage power line 21 is separated and installs a double wire to the pole 10 at the position where the existing pin shaft 11 is removed, It is only necessary to install the built-in main body 12 ', and the installation process of the built-in main body 12' is not newly implemented, but it is possible to apply the main body replacement method using a conventional band.

Thereafter, the power line fixing process is performed,

This is accomplished by first providing the joists 30 on both sides of the new built-in main body 12 '.

When the extra-high voltage power line 21 is moved to the lower position of the installed girder 30 through the operation of the elevating operation unit 200 and the horizontal operation unit 300 in the reverse order of separation of the extra high voltage power line 21 do.

The elevating operation unit 200 may be operated to lower the elevating bars 210 and 210 'and to bring the extraordinary high voltage power line 21 close to the double girder 30.

Then, the horizontally operating part 300 is operated to pivot the horizontal bars 310 and 310 'so that the extra-high voltage power line 21 is brought close to the main line 30.

The two extra-high voltage power lines 21 are connected to the new jumper wires 42 by being fixed on both sides of the extra high voltage power line 21 by using the double side girder 30, And the existing short high voltage power line is cut to complete the jumper of the new built-in main body 12 '.

At this time, it is a matter of course that the special high-voltage power line 21 to be fixedly connected is provided with a dead-end clamp at its end and a suspending insulator formed in the built-in lead 12 '.

Thereafter, the lifting device demolition process is performed,

This is achieved by first separating the joiner 30 from the extra-high voltage power line 21.

The lifting and lowering operation unit 200 is operated to lower the lifting bars 210 and 210 'and lower the horizontal bars 310 and 310' while the live wire guide unit 420 of the insulation twisting roller 400 is opened. Voltage power line 21 to the lower side.

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Therefore, it is possible to change the built-in core of double-tinned wire by using an indirect wire-lifting device for distribution lines through a series of processes.

* Example 4

31 to 35, uninterrupted work can be carried out by using an indirect live wire lifting device (1) for distribution lines in order to replace the built-in wrist and insulator composed of a single built-in type lightening arm in the process of uninterrupted distribution line construction .

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 on the electric pole 10 by covering the electric pole 10 from the lower part of the existing built-in main body 12 by using the mounting part 100.

At this time, a plurality of indirect live-wire lifting devices 1 to be installed may be provided symmetrically on both sides of the electric pole 10.

On the other hand, when a plurality of indirect live-wire lifting apparatuses 1 are installed as described above, it is possible to apply only one horizontal bar 310 to each of the two horizontal bars 310 and 310 ' will be.

Thereafter, a position adjustment process is performed,

This can be achieved by operating each lifting operation part 200 corresponding to the indirect live lifting device 1 on both sides by using a stick for normal live work (not shown in the drawing).

The height of the horizontal bar 310 is adjusted by vertically moving the elevating bars 210 and 210 'by operating the elevating operation unit 200, The high voltage power line 21 can be brought close to the upper portion or the lower portion of the power line.

Thereafter, the first power line retention process is performed,

This is accomplished by first providing a bracket 30 on a horizontal bar 310 corresponding to each indirect live wire lifting device 1 and by using the bracket 30 to connect the extra high voltage power line 21 ).

In this case, since the extra-high voltage power lines 21 are separated from each other with respect to the longitudinal axis in the case of the general built-in type, in the present invention, It is only necessary to install the joists 30.

The extra high voltage power line 21 is separated from the existing built-in lug 12 by using the sticky wire 30 while adjusting the tension of the extra high voltage power line 21, And is naturally transferred to the horizontal bar 310 provided with the joiner 30.

Thereafter, the power line separation and separation process is performed,

This is because the lifting and lowering operation parts 200 corresponding to the respective indirect live lifting devices 1 are operated to move the lifting bars 210 and 210 'upwards or downwards, The power line 21 can be separated and lifted up to a safety clearance without operator intervention when the long power line is replaced.

Thereafter, a long-period replacement process is performed,

This is because the operator can dismantle the existing built-in mains 12 from which the extra-high voltage power line 21 has been separated and remove the existing built-in mains 12 from the newly installed built-in mains 12 The installation procedure of the new built-in main body 12 'is not newly implemented, but can be applied to a long-period replacement method using an ordinary band or the like.

Thereafter, the second power line retention process is performed,

This is because the elevating operation unit 200 is operated in the reverse order of the separation of the extra high voltage power line 21 to lower or raise the elevating bars 210 and 210 ' ).

The extra high voltage power line 21 is connected to the new built-in main power line 12 'by using the joining line 30 holding the extra-high voltage power line 21 while adjusting the diversion of the extra high voltage power line 21, ), You can fix it.

Thereafter, the lifting device demolition process is performed,

This is achieved by first separating the joiner 30 from the extra-high voltage power line 21.

The elevating operation part 200 may be operated to lower the elevating bars 210 and 210 'and to separate the horizontal bar 310 from the extraordinary high voltage power line 21 downward.

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Therefore, it is possible to change the built-in state of built-in light-gauge steel wire during the uninterrupted operation by using the indirect live wire lifting device for the distribution line through a series of processes.

* Example 5

36 to 40, uninterrupted work can be carried out by using an indirect live wire lifting device (1) for distribution lines in order to replace the built-in wrist and insulator composed of double wires in the process of uninterrupted distribution line construction.

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 on the electric pole 10 by covering the electric pole 10 from the lower part of the existing built-in main body 12 by using the mounting part 100.

At this time, a plurality of indirect live-wire lifting devices 1 to be installed may be provided symmetrically on both sides of the electric pole 10.

On the other hand, when a plurality of indirect live-line lifting devices 1 are installed as described above, it is possible to apply only one horizontal bar 310 to each of the two horizontal bars 310 and 310 ' will be.

Thereafter, a position adjustment process is performed,

This can be achieved by operating each lifting operation part 200 corresponding to the indirect live lifting device 1 on both sides by using a stick for normal live work (not shown in the drawing).

First, the elevating operation part 200 is operated to adjust the height of the horizontal bar 310 by adjusting the elevating bars 210 and 210 'up and down, 12 near the extra-high voltage power line 21 at the upper portion or the lower portion.

Thereafter, the first power line retention process is performed,

This is accomplished by first providing a bracket 30 on a horizontal bar 310 corresponding to each indirect live wire lifting device 1 and by using the bracket 30 to connect the extra high voltage power line 21 ).

In this case, since the extra-high voltage power lines 21 are separated from each other with respect to the longitudinal axis in the case of the general built-in type, in the present invention, It is only necessary to install the joists 30.

The extra high voltage power line 21 is separated from the existing built-in lug 12 by using the sticky wire 30 while adjusting the tension of the extra high voltage power line 21, And is naturally transferred to the horizontal bar 310 provided with the joiner 30.

Thereafter, the power line separation and separation process is performed,

This is because the lifting and lowering operation parts 200 corresponding to the respective indirect live lifting devices 1 are operated to move the lifting bars 210 and 210 'upwards or downwards, The power line 21 can be separated and lifted up to a safety clearance without operator intervention when the long power line is replaced.

Thereafter, a long-period replacement process is performed,

This is because the operator can dismantle the existing built-in mains 12 from which the extra-high voltage power line 21 has been separated and install the new built-in mains 12 'having the double- The installation process of the new built-in main body 12 'is not newly implemented, but can be applied to a long-period replacement method using a conventional band.

Thereafter, the second power line retention process is performed,

This is because the elevating operation portion 200 is operated in the reverse order of the separation of the extra high voltage power line 21 to lower or raise the elevating bars 210 and 210 ' ).

The extra high voltage power line 21 is connected to the new built-in main power line 12 'by using the joining line 30 holding the extra-high voltage power line 21 while adjusting the diversion of the extra high voltage power line 21, ), You can fix it.

Thereafter, the lifting device demolition process is performed,

This is achieved by first separating the joiner 30 from the extra-high voltage power line 21.

The elevating operation part 200 may be operated to lower the elevating bars 210 and 210 'and to separate the horizontal bar 310 from the extraordinary high voltage power line 21 downward.

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Therefore, it is possible to change the built-in state of the double-walled building during the uninterrupted construction by using the indirect lifting line lifting device for the distribution line through a series of processes.

* Example 6

41 to 45, uninterrupted work can be carried out by using the indirect line lifting device (1) for the distribution line to replace the billet and insulator of the billet pin during the construction work with the uninterruptible power distribution line.

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 in the electric pole 10 by covering the electric pole 10 from the lower part of the existing slanting pin 13 using the mounting part 100. [

Thereafter, a position adjustment process is performed,

This is possible by actuating the lifting operation part 200 by using a normal hot working stick (not shown in the figure). By operating the lifting operation part 200, the lifting bars 210 and 210 ' So that the horizontal bars 310 and 310 'are positioned below the extra-high voltage power line of the existing slit strip 13.

Then, the horizontal operation unit 300 is operated so that the insulation twist roller 400 is positioned close to the extra-high voltage power line 21 through the left and right control of the horizontal bars 310 and 310 ' It will be appreciated that the rollers 400 are installed at regular intervals in consideration of the spacing of the extra-high voltage power lines 21 installed.

On the other hand, in the case of a normal slide fastener, it is eccentric from one side of the electric pole 10 to one side. In applying the indirect live hot line lifting device 1 according to the present invention, the horizontal bars 310 and 310 ' Can be selected and applied.

Thereafter, the power line separation and separation process is performed,

The operator opens the live wire guide portion 420 of the insulation twist roller 400 using a normal live wire stick (not shown in the figure) and uses the stick for live wire work to connect the extra high voltage power wire 21 to the live wire guide portion 420 and the live wire guide part 420 may be closed.

Then, the worker removes the binding of the elbow insulator by using a stick for normal live work (not shown in the figure) and activates the lifting operation part 200 to lift the lifting bars 210 and 210 ' The power line 21 can be separated from the power line 21 by a safety distance without operator interference.

Thereafter, a long-period replacement process is performed,

This is because the operator removes the existing slip-on slip 13 from which the extra-high voltage power line 21 has been removed and installs the new slip-on slip 13 'at the position where the slip- The installation process of the new part-to-be-loaded main shaft 13 'is not newly implemented, but it is possible to apply the main shaft replacing method using a normal band or the like.

Thereafter, the power line installation process is performed,

This is possible by the operation of the lifting operation part 200.

That is, the elevating operation unit 200 may be operated so that the elevating bars 210 and 210 'descend and the extra-high voltage power line 21 is seated and fixed on the elbow of the new-equipment joining shaft 13'.

Thereafter, the lifting device demolition process is performed,

This is achieved by first moving the lifting bars 210 and 210 'down and moving the horizontal bars 310 and 310' by operating the lifting operation part 200 in a state where the live wire guide part 420 of the insulation twisting roller 400 is opened. The horizontal bar 310 and the horizontal bar 310 'are automatically separated from the extra high voltage power line 21 when the horizontal bars 310 and 310' are lowered. ).

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Therefore, it is possible to change the construction schedule for uninterrupted construction using indirect lifeline lifting device for distribution lines through a series of processes.

* Example 7

46 to 50, uninterrupted work can be performed using an indirect live wire lifting device (1) for a distribution line in order to change a single-piece built-in type light-emitting leaded-wire built-in lead wire in the course of construction with an uninterruptible power distribution line.

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 in the electric pole 10 by covering the electric pole 10 from the lower part of the existing slanting pin 13 using the mounting part 100. [

Thereafter, a position adjustment process is performed,

This is possible by actuating the lifting operation part 200 and the horizontal operation part 300 by using a stick for normal live work (not shown in the figure).

First, the elevating operation part 200 is operated to adjust the elevating bars 210 and 210 'up and down so that the horizontal bars 310 and 310' As shown in FIG.

Then, the horizontal operation unit 300 is operated so that the insulation twist roller 400 is positioned close to the extra-high voltage power line 21 through the left and right control of the horizontal bars 310 and 310 ' It will be appreciated that the rollers 400 are installed at regular intervals in consideration of the spacing of the extra-high voltage power lines 21 installed.

On the other hand, in the case of a normal slide fastener, it is eccentric from one side of the electric pole 10 to one side. In applying the indirect live hot line lifting device 1 according to the present invention, the horizontal bars 310 and 310 ' Can be selected and applied.

Thereafter, the power line separation and separation process is performed,

The operator opens the live wire guide portion 420 of the insulation twist roller 400 using a normal live wire stick (not shown in the figure) and uses the stick for live wire work to connect the extra high voltage power wire 21 to the live wire guide portion 420 and the live wire guide part 420 may be closed.

Then, the worker removes the binding of the elbow insulator by using a stick for normal live work (not shown in the figure) and activates the lifting operation part 200 to lift the lifting bars 210 and 210 ' The power line 21 can be lifted up to a safe distance without operator intervention.

Thereafter, a long-period replacement process is performed,

This means that the operator should dismantle the existing slip shank (13) from which the extra-high voltage power line (21) has been removed, and install a single type of flexible shank at the location where the existing slip shank (13) The installation process of the new built-in built-in main lid 14 'is not newly realized but it is possible to apply the old ladder replacement method using a conventional band.

Thereafter, the power line fixing process is performed,

That is, first, the joists 30 are provided on both sides of the newly-built internal lead 14 '.

When the extra-high voltage power line 21 is moved to the upper position of the installed girder 30 through the operation of the elevating operation unit 200 and the horizontal operation unit 300 in the reverse order of the separation of the extra high voltage power line 21 do.

That is, the elevating operation part 200 may be operated to lower the elevating bars 210 and 210 'and to bring the extraordinary high voltage power line 21 close to the both side girder 30.

The two extra-high voltage power lines 21 are connected to the new jumper wires 42 by being fixed on both sides of the extra high voltage power line 21 by using the double side girder 30, And cut off the existing short high voltage power line to complete the built-in jumper.

At this time, it is a matter of course that the extra high-voltage power line 21 to be fixedly connected is provided with a dead-end clamp on its end and a suspending insulator formed on the new built-in lead 14 '.

Thereafter, the lifting device demolition process is performed,

This separates the joiner 30 from the extra-high voltage power line 21 first.

The lifting and lowering operation unit 200 is operated to lower the lifting bars 210 and 210 'and lower the horizontal bars 310 and 310' while the live wire guide unit 420 of the insulation twisting roller 400 is opened. Voltage power line 21 to the lower side.

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Thus, by using a series of processes, it is possible to change the built-in prong of the single built-in light-gauge iron by using the indirect live-wire lifting device for distribution lines.

* Example 8

51 to 55, uninterrupted work can be carried out by using an indirect live-wire lifting device (1) for distribution lines to change the built-in end of double-ended wires to the built-in double-walled wire in the process of uninterrupted distribution line construction.

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 in the electric pole 10 by covering the electric pole 10 from the lower part of the existing slanting pin 13 using the mounting part 100. [

Thereafter, a position adjustment process is performed,

This is possible by actuating the lifting operation part 200 and the horizontal operation part 300 by using a stick for normal live work (not shown in the figure).

First, the elevating operation part 200 is operated to adjust the elevating bars 210 and 210 'up and down so that the horizontal bars 310 and 310' As shown in FIG.

Then, the horizontal operation unit 300 is operated so that the insulation twist roller 400 is positioned close to the extra-high voltage power line 21 through the left and right control of the horizontal bars 310 and 310 ' It will be appreciated that the rollers 400 are installed at regular intervals in consideration of the spacing of the extra-high voltage power lines 21 installed.

On the other hand, in the case of a normal slide fastener, it is eccentric from one side of the electric pole 10 to one side. In applying the indirect live hot line lifting device 1 according to the present invention, the horizontal bars 310 and 310 ' Can be selected and applied.

Thereafter, the power line separation and separation process is performed,

The operator opens the live wire guide portion 420 of the insulation twist roller 400 using a normal live wire stick (not shown in the figure) and uses the stick for live wire work to connect the extra high voltage power wire 21 to the live wire guide portion 420 and the live wire guide part 420 may be closed.

Then, the worker removes the binding of the elbow insulator by using a stick for normal live work (not shown in the figure) and activates the lifting operation part 200 to lift the lifting bars 210 and 210 ' The horizontal bar 310 and the horizontal bars 310 and 310 'are extended to both sides of the bar so that the extra high voltage power line 21 is separated from the elbow insulator, You can increase the length of separation by long distance without safety intervention.

Thereafter, a long-period replacement process is performed,

This is because the operator can dismantle the existing slip shafts 13 from which the extra-high voltage power line 21 has been separated and remove the existing slip shafts 13 at the positions where the existing slip shafts 13 are removed, The installation process of the new built-in built-in main lid 14 'is not newly realized but the installation of the new built-in built-in lid 14' Lt; / RTI >

Thereafter, the power line fixing process is performed,

That is, first, the joists 30 are provided on both sides of the newly-built internal lead 14 '.

When the extra-high voltage power line 21 is moved to the upper position of the installed girder 30 through the operation of the elevating operation unit 200 and the horizontal operation unit 300 in the reverse order of the separation of the extra high voltage power line 21 do.

That is, the elevating operation part 200 may be operated to lower the elevating bars 210 and 210 'and to bring the extraordinary high voltage power line 21 close to the both side girder 30.

The two extra-high voltage power lines 21 are connected to the new jumper wires 42 by being fixed on both sides of the extra high voltage power line 21 by using the double side girder 30, And cut off the existing short high voltage power line to complete the built-in jumper.

At this time, it is a matter of course that a conventional dead-and-clamp is installed at the end of the extra-high voltage power line 21 to be connected and is installed in a suspending insulator formed in the built-in built-in lead 14 '.

Thereafter, the lifting device demolition process is performed,

This is achieved by first separating the joiner 30 from the extra-high voltage power line 21.

The lifting and lowering operation unit 200 is operated to lower the lifting bars 210 and 210 'and lower the horizontal bars 310 and 310' while the live wire guide unit 420 of the insulation twisting roller 400 is opened. When the horizontal bars 310 and 310 'are lowered, they are automatically separated from the new jumper wire 42. In this case, the horizontal bar 310 and 310' .

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Therefore, it is possible to change the built-in prefabricated main building with double-wired construction at the time of uninterrupted construction by using the indirect live-wire lifting device for distribution lines through a series of processes.

* Example 9

56 to 60, uninterrupted construction work can be carried out by using an indirect live wire lifting device (1) for distribution lines in order to equally replace the built-in built-in lightwave built- have.

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 on the electric pole 10 by covering the electric pole 10 from the lower part of the existing built-in embedded stalks 14 by using the mounting part 100.

At this time, a plurality of indirect live-wire lifting devices 1 to be installed may be provided symmetrically on both sides of the electric pole 10.

On the other hand, when a plurality of indirect live-line lifting devices 1 are installed as described above, it is possible to apply only one horizontal bar 310 to each of the two horizontal bars 310 and 310 ' will be.

Thereafter, a position adjustment process is performed,

This can be achieved by operating each lifting operation part 200 corresponding to the indirect live lifting device 1 on both sides by using a stick for normal live work (not shown in the drawing).

That is, the height of the horizontal bar 310 is adjusted by operating the lifting and lowering operation part 200 to adjust the lifting and lowering of the lifting and lowering bars 210 and 210 ' Voltage power line 21 in the upper portion or the lower portion of the high-voltage power line 14.

Thereafter, the first power line retention process is performed,

This is accomplished by first providing a stringer 30 on the horizontal bar 310 corresponding to each of the indirect live wire lifting devices 1 and by using the stringer 30 to connect the extra high voltage power line 21).

In this case, since the extra-high voltage power lines 21 are separated from each other with respect to the longitudinal axis in the case of the general built-in type, in the present invention, It is only necessary to install the joists 30.

The extra high voltage power line 21 is separated from the existing embedded built-in lug 14 by using the sticking machine 30 while adjusting the tension of the extra high voltage power line 21, Is naturally transferred to the horizontal bar 310 provided with the joiner 30.

Thereafter, the power line separation and separation process is performed,

This is because the lifting and lowering operation parts 200 corresponding to the respective indirect live lifting devices 1 are operated to move the lifting bars 210 and 210 'upwards or downwards, The extra high voltage power line 21 can be separated and pulled up to the safe distance without operator intervention of the live wire at the time of replacing the long power line.

Thereafter, a long-period replacement process is performed,

This is because the operator removes the existing lead-in embedded lead 14 from which the extra-high voltage power line 21 has been removed, and installs a single built-in lead-in lead at the position where the lead-in lead- It is only necessary to install the new built-in built-in lid 14 '. The installation process of the new built-in built-in lid 14' is not newly realized but can be applied to the replacement of the old built-

Thereafter, the second power line retention process is performed,

This is because the elevating operation unit 200 is operated in the reverse order of the separation of the extra high voltage power line 21 to lower or raise the elevating bars 210 and 210 ' ').

The extra high voltage power line 21 is connected to the new built-in built-in main line 14 (14) by using the joining line 30 holding the extra-high voltage power line 21, ').

Thereafter, the lifting device demolition process is performed,

This is achieved by first separating the joiner 30 from the extra-high voltage power line 21.

The elevating operation part 200 may be operated to lower the elevating bars 210 and 210 'and to separate the horizontal bar 310 from the extraordinary high voltage power line 21 downward.

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Thus, it is possible to change the built-in built-in light-gauge railway incandescent underpass during the uninterrupted operation by using the indirect live-wire lifting device for distribution lines through a series of processes.

* Example 10

61 to 65, uninterrupted work can be carried out by using an indirect live wire lifting device (1) for distribution lines in order to replace the bare wire and the insulator with the double wire in the process of uninterrupted distribution line construction .

To this end, the pulling device installation process is performed,

This is achieved by installing the indirect live-wire lifting device 1 on the electric pole 10 by covering the electric pole 10 with the use of the mounting portion 100. [

At this time, a plurality of indirect live-wire lifting devices 1 to be installed may be provided symmetrically on both sides of the electric pole 10.

On the other hand, when a plurality of indirect live-line lifting devices 1 are installed as described above, it is possible to apply only one horizontal bar 310 to each of the two horizontal bars 310 and 310 ' will be.

Thereafter, a position adjustment process is performed,

This can be achieved by operating each lifting operation part 200 corresponding to the indirect live lifting device 1 on both sides by using a stick for normal live work (not shown in the drawing).

That is, the height of the horizontal bar 310 is adjusted by operating the lifting and lowering operation part 200 to adjust the lifting and lowering of the lifting and lowering bars 210 and 210 ' Voltage power line 21 in the upper portion or the lower portion of the high-voltage power line 14.

Thereafter, the first power line retention process is performed,

This is accomplished by first providing a stringer 30 on the horizontal bar 310 corresponding to each of the indirect live wire lifting devices 1 and by using the stringer 30 to connect the extra high voltage power line 21).

In this case, since the extra-high voltage power lines 21 are separated from each other with respect to the longitudinal axis in the case of the general built-in type, in the present invention, It is only necessary to install the joists 30.

The extra high voltage power line 21 is separated from the existing embedded built-in lug 14 by using the sticking machine 30 while adjusting the tension of the extra high voltage power line 21, Is naturally transferred to the horizontal bar 310 provided with the joiner 30.

Thereafter, the power line separation and separation process is performed,

This is because the lifting and lowering operation parts 200 corresponding to the respective indirect live lifting devices 1 are operated to move the lifting bars 210 and 210 'upwards or downwards, The extra high voltage power line 21 can be separated from the lead built-in lead 14 by the safety separation distance without the operator's live wire interference at the time of replacing the long lead wire.

Thereafter, a long-period replacement process is performed,

This is because the operator removes the existing built-in built-in mains 14 from which the extra-high voltage power line 21 has been separated and newly installed double helix at the position where the existing built-in built-in mains 14 is demolished, It is only necessary to install the built-in main body 14 '. That is, the installation process of the built-in built-in main body 14' is not newly implemented, but a general replacement method using a conventional band.

Thereafter, the second power line retention process is performed,

This is because the elevating operation portion 200 is operated in the reverse order of the separation of the extra high voltage power line 21 to lower or raise the elevating bars 210 and 210 ' ').

The extra high voltage power line 21 is connected to the new built-in built-in main line 14 (14) by using the joining line 30 holding the extra-high voltage power line 21, ').

Thereafter, the lifting device demolition process is performed,

This is achieved by first separating the joiner 30 from the extra-high voltage power line 21.

The elevating operation part 200 may be operated to lower the elevating bars 210 and 210 'and to separate the horizontal bar 310 from the extraordinary high voltage power line 21 downward.

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Therefore, it is possible to change the built-in state of the double-charged wire during the uninterrupted operation by using the indirect wire lifting device for the distribution line through a series of processes.

* Example 11

66 to 70, it is possible to perform uninterrupted work for separating the span by using the indirect live-wire lifting device 1 for the distribution line to change the history of the built-in main span during the uninterrupted distribution line construction work.

To this end, the pulling device installation process is performed,

This is because the indirect live-wire lifting device 1 is installed on the electric poles 10a and 10b where the existing built-in mains 12 are formed on both sides of the change section, It is sufficient to enclose the electric poles 10a and 10b.

At this time, the indirect live-wire lifting device 1 to be installed may be provided on one side of the electric pole 10a and the other side of the electric pole 10b.

Thereafter, a position adjustment process is performed,

This can be achieved by operating the lifting operation part 200 and the horizontal operation part 300 corresponding to the indirect live-wire lifting device 1 on both sides by using a stick for normal live-work (not shown).

The height of the horizontal bars 310 and 310 'is adjusted by adjusting the vertical movement of the vertical bars 210 and 210' by operating the vertical movement operation unit 200, 310 'may be brought close to the extra high voltage power line 22 to be removed from the upper or lower portion of the existing built-in main body 12.

Thereafter, the power line retention process is performed,

This is accomplished by first providing a joist 30 on the horizontal bars 310 and 310 'corresponding to each of the indirect live-wire lifting devices 1 and changing the existing built-in stalks 12 using the joists 30 (22) located at the inner side of the section.

The tension of the extra high voltage power line 21 is adjusted by using the supercharger 30 to separate the super high voltage power line 21 from the existing built-in lug 12 by using the stick for live work. Is naturally transferred to the horizontal bars 310 and 310 'provided with the joists 30.

Thereafter, the jumper cable connecting process is performed,

This is achieved by connecting the extra high voltage power line 21 outside the change section around the both side poles 10a and 10b and the side of the extra high voltage power line 22 to be demounted separated in the change section with the bypass jumper cable 50 It is necessary to temporarily operate in parallel.

Thereafter, the power line separation and separation process is performed,

This is accomplished by moving the lifting bars 210 and 210 'upward or downward by operating the lifting and lowering operation part 200 corresponding to each of the indirect live lifting devices 1. The horizontal bars 310 and 310 'May be separated from the existing built-in mains 12 to the upper portion so that the extra-high voltage power line 21 can be lifted up to a safe separation distance without operator interference.

Thereafter, a span separation step is performed,

This is achieved by first separating the existing jumper wire 41 connecting the existing line, that is, the extra-high voltage power line 21 and the extra high voltage power line 22 to be demolished, the extra high voltage power line 21 and the extra high voltage power line 22, The high voltage power line 21 in the span inside the joiner 30 fixed at the bypass connection position is secured to secure the safety lane work area without the live wire interference of the operator in the change period of the electric wire etc. in the change section.

Thereafter, a span installing process is performed,

This can be accomplished by a preliminary preparation work process in which the new and newly installed special high voltage power line 23 is connected to a span including a new electric pole and a long pole at a position to change the current location, .

Thereafter, the jumper wire connecting process is performed,

This can be achieved by first connecting the extra high voltage power line 21 located outside the two pole posts 10a and 10b and the new extra high voltage power line 23 by the new jumper wire 42 and performing parallel operation.

The bypass jumper cable 50 connected to the outer extra-high voltage power line 21 and the extra high voltage power line 22 to be demounted is separated and the normal high voltage power line 21 and the new extra high voltage power line 23 are used for normal operation .

Thereafter, the lifting device demolition process is performed,

This can be accomplished by first unplugging the supercharger 30 holding the extra-high voltage power line 22 to be demolished, and then removing the extra high voltage power line 22, Zhangzhou and Jeonju.

The indirect live-wire lifting device 1 is separated from the frontal electric poles 10a and 10b by detaching the mounting portion 100 from the electric poles 10a and 10b in the reverse order of the installation, It may be removed from the electric poles 10a and 10b.

Thus, it is possible to perform safe and efficient uninterrupted construction more efficiently when the span separation uninterrupted construction is performed by using an indirect live line lifting device for a distribution line through a series of processes.

* Example 12

Referring to FIGS. 71 to 75, when the uninterrupted distribution line is constructed, when the work area is at the end of the work area or at the end of the work area, the work area can be separated from the work area.

To this end, the pulling device installation process is performed,

This is because the indirect live-wire lifting device 1 is provided on the electric poles 10a and 10b on both sides of the change section in which the existing pin elbows 11 are formed and this is installed in the electric poles 10a and 10b You can install it by wrapping it.

At this time, the indirect live-wire lifting device 1 installed may be installed at a position where it is not interfered with the existing pin shaft 11 of the one electric pole 10a and the other electric pole 10b.

Thereafter, a position adjustment process is performed,

This is possible by actuating the lifting operation part 200 and the horizontal operation part 300 by using a stick for normal live work (not shown in the figure).

The lifting and lowering operation of the lifting and lowering operation part 200 is controlled so that the horizontal bars 310 and 310 'are lowered under the extra high voltage power line Position.

Then, the horizontal operation unit 300 is operated so that the insulation twist roller 400 is positioned close to the extra-high voltage power line 21 through the left and right control of the horizontal bars 310 and 310 ' It will be appreciated that the rollers 400 are installed at regular intervals in consideration of the spacing of the extra-high voltage power lines 21 installed.

Thereafter, the power line separation and separation process is performed,

This is because the operator opens the live wire guide portion 420 of the insulation twist roller 400 using a normal live wire stick (not shown in the figure) and uses the stick for live wire work to connect the extra-high voltage power wire 21 to the live wire guide The left and right line guide portions 420 may be closed by the portion 420.

Then, the worker removes the binding of the elbow insulator by using a stick for normal live work (not shown in the figure) and activates the lifting operation part 200 to lift the lifting bars 210 and 210 ' The horizontal bar 310 and the horizontal bars 310 and 310 'are extended to open both sides of the horizontal bars 310 and 310' The safety separation distance without the interference of the live wire can be increased.

After that,

This is because the operator removes the existing pin shaft 11 from which the extra-high voltage power line 21 has been separated and installs a single built-in type mandrel iron or double wire at the position where the existing pin shaft 11 is removed, It is only necessary to install the built-in main body 12 '. That is, the installation process of the built-in main body 12' is not newly implemented, but the main body replacing system using a conventional band.

Thereafter, the power line fixing process is performed,

This is achieved by first providing the joist 30 in the horizontal bar 310 corresponding to the indirect live-wire lifting device 1 on the side of the extra-high voltage power line 22 to be demolished, And the joiner 30 is installed in the newly built internal main body 12 'in order to fix the side of the extra high voltage power line 21.

The extra high voltage power line 21 may be moved to a position close to the installed girder 30 through the operation of the elevating operation unit 200 and the horizontal operation unit 300 in the reverse order of the separation of the extra high voltage power line 21 .

The elevating operation unit 200 may be operated to bring the elevating bars 210 and 210 'down and bring the extraordinary high voltage power line 21 close to the double girder 30.

The horizontal bar 310 and the horizontal bar 310 'are pulled by operating the horizontal operation unit 300 so that the extra-high voltage power line 21 can be brought close to the main line 30.

Thereafter, the extra-high voltage power line 22 to be removed is temporarily fixed to the both sides by using the long cable 30 installed in the horizontal bar of the indirect live wire lifting device 1, and the long cable Both sides of the extra-high voltage power line 21 outside the work section can be held and fixed to the new built-in mains 12 'around the working electrode 10 on the working section.

Thereafter, the jumper cable connecting process is performed,

This is achieved by connecting the extra high voltage power line 21 outside the change section around the both side poles 10a and 10b and the side of the extra high voltage power line 22 to be demounted separated in the change section with the bypass jumper cable 50 It is necessary to temporarily operate in parallel.

Thereafter, a span separation step is performed,

This is achieved by first separating the existing jumper wire 41 connecting the existing line, that is, the extra-high voltage power line 21 and the extra high voltage power line 22 to be demolished, the extra high voltage power line 21 and the extra high voltage power line 22, The high voltage power line 21 in the span inside the joiner 30 fixed at the bypass connection position is secured to secure the safety lane work area without the live wire interference of the operator in the change period of the electric wire etc. in the change section.

Thereafter, a span installing process is performed,

It is preferable that the span including the new electric pole and the long span should be connected to the newly installed and newly installed extra high voltage power line 23 at a position to change the past location, You can do this by doing a long line.

At this time, the span newly formed as described above can be formed by the new built-in main spindle 12 'located on both sides of the work section, and the angle of the new extra-high voltage power line 23 can be changed.

Thereafter, the jumper wire connecting process is performed,

This can be achieved by connecting the extra high voltage power line 21 located outside the work section around the new built-in lid 12 'and the newly installed extra high voltage power line 23 through the new jumper line 42 and operating in parallel.

Thus, when the jumper cable 50 is removed from both the pole posts 10a and 10b, the extra-high voltage power line 22 to be removed in the work section becomes oblique.

Thereafter, the lifting device demolition process is performed,

This is accomplished by first unplugging the wire harness 30 holding the extra-high voltage power line 22 to be demolished, and then removing the extra high voltage power line 22 to be demolished and the longitudinal and transverse sections in the section.

The lifting and lowering operation unit 200 is operated to lower the lifting bars 210 and 210 'and lower the horizontal bars 310 and 310' while the live wire guide unit 420 of the insulation twisting roller 400 is opened. When the horizontal bars 310 and 310 'are lowered, they are automatically separated from the new jumper wire 42. In this case, the horizontal bar 310 and 310' .

The indirect live-wire lifting device 1 is detached from the electric pole 10 by separating the mounting portion 100 from the electric pole 10 in the reverse order of the installation, The electric pole 10 can be removed.

Therefore, it is possible to change the built-in main body made of single built-in lightwave iron or double-wired iron by using the indirect live wire lifting device for distribution line through a series of processes.

Thus, it is possible to construct a distribution facility for the replacement of electric poles and the change of historical sites during the uninterrupted operation by using an indirect live line lifting device for distribution lines through a series of processes.

Meanwhile, in the indirect live-line uninterruptible power supply method using the indirect-live-wire lifting device for the distribution line according to the present invention, which is performed through the above-described first to twelfth embodiments, when the extra-high voltage power line 21 forms a plurality of phases, It would be desirable to perform the phase together.

In addition, referring to FIG. 15, the indirect live wire uninterruptible power supply method using the indirect live wire lifting apparatus for distribution lines according to the present invention, which is performed through the above-described first to twelfth embodiments, It is preferable that the plurality of stages of the lines are performed together.

Meanwhile, in performing the indirect live-line uninterruptible operation method using the indirect live-wire lifting device for a distribution line according to the present invention, although it is not described in the above description, it is possible to perform the replacement of the static electricity poles with reference to FIGS. 76 and 77.

At this time, the replacement of the electric pole 10 is performed by installing a new electric pole 10 'on one side of the electric pole 10 in a state where the extra-high voltage electric power line 21 is separated by a safe separation distance.

A new pin rail 11 'or a new built-in main rail 12' is installed in the newly installed new electric pole 10 'and a special high-voltage electric power line is connected to the new pin rail 11' or the new built- The indirect live line uninterrupted method can be performed by operating the indirect live line lifting device.

Further, in the present invention, Indirect live wire  Using a lifting device Indirect live wire  In carrying out the uninterruptible power supply method, Although it was unmounted 78 and Fig. 79, it is possible to concurrently install the induction electric pole between the normal two side electric poles 10.

At this time, in order to install the induction pole (10 "), the induction pole (10") is newly installed on one side of the conductive pole (10) with the extra high voltage power line (21) separated by the safe separation distance.

A new pin rail 11 'or a new built-in main rail 12' is installed on the new intruder electric pole 10 '' and a special high-voltage electric power line is installed on the new pin rail 11 'or the new built- The indirect live line uninterrupted method can be performed by operating the indirect live line lifting device.

As described above, the indirect live-line uninterrupted method using the indirect live-wire lifting device for the distribution line of the present invention can be easily and securely separated from the live-line high-voltage power line in the process of replacing the electric pole, It is possible to secure the movement and safety work sections and to perform the uninterrupted construction in the indirect live line state.

10, 10a, 10b: electric pole 11, 11 '
12,12 ': Built-in notes 13 and 13'
14,14 ': Built-in built-in note 21: Extra-high voltage power line
22: Extra-high voltage power line to be demolished 23: New extra-high voltage power line
30: Long wire machine 41: Conventional jumper wire
42: New jumper wire 50: Bypass jumper cable
100: mounting portion 110: clamp base
111: electric pole groove 120:
121: electric pole binding groove 130: first pressing portion
131: first guider 131a: first guide groove
132: first pressing member 132a:
133: first adjusting bolt 140: second pressing portion
141: second guider 141a: second guide groove
142: second pressing member 142a: V-groove
143: Second adjusting bolt
200: lifting operation part 210, 210 ': lifting bar
211: lifting and lowering rack 220: lifting and lowering case
221: lift bar guide hole 222: guide roller
230: lift / worm box 231: lift /
232: upper pinion 233: upper sprocket
235: ascending / descending worm shaft 237: interlocking spur gear
240: lifting and lowering shaft 242: lower pinion
243: Lower sprocket 244: Chain
250: lift driving shaft 250a: lift adjusting tool engaging portion
252: Driving spur gear
300: horizontal operation part 310, 310 ': horizontal bar
320: Horizontal part base 321, 321 ': Fixing part
322, 322 ': horizontal bar guide tube 323: horizontal bar guide ball
324: through hole 325:
330: first horizontal operating portion 331: first horizontal driving shaft
331a: first tool engagement portion 332: first drive spur gear
333: first horizontal worm shaft 334: first interlocking spur gear
336: first horizontal rotary shaft 338: first pinion
339: 1st horizontal warm box
340: second horizontal operating portion 341: first horizontal driving shaft
341a: second tool engaging portion 342: second driving spur gear
343: second horizontal worm shaft 344: second interlocking spur gear
346: second horizontal rotary shaft 348: second pinion
349: second horizontal warm box 350: horizontal bar connecting rod
400: insulated twist roller 410: clamp
420: live wire guide portion 421a: lower body
422: Horizontal roller 423: Vertical roller
421b: upper body 422: horizontal roller

Claims (22)

A clamp base 110 having a semicylindrical shape and having a preformed annular groove 111 to surround one side of the preform and an electret fastening groove 121 corresponding to the clamp base 110 and corresponding to the preformed recess 111, A mounting portion 100 formed by at least one of the plurality of binding portions 120 formed with a plurality of holes formed therein,
An elevating operation part 200 formed on the mounting part 100 to control the upper and lower elevating and lowering rivers of the elevating bars 210 and 210 '; And
A horizontal operation part 300 'for connecting the upper ends of the two side lift bars 210 and 210' and ascending and descending together with the lift bars 210 and 210 ' ),
The elevating bars 210 and 210 '
The lifting and lowering operation is performed by the operation of the lifting and lowering operation part 200. The lifting and lowering operation is carried out by the operation of the lifting and lowering operation part 200. The elevating and lowering racks 211 are formed respectively, The insertion hole 213 is connected to the lift bar connecting rod 212 through which the insertion hole 213 is inserted,
The horizontal bars 310 and 310 '
And is horizontally operated to the left and right by the operation of the horizontal operation part 300 connected to the horizontal operation part 300. Horizontal racks 311 are formed in each of them,
The mounting portion 100
In the clamp base 110,
At least one first pressing part 130 for applying a pressing force to the electric pole in the process of being mounted on the electric pole,
In the binding portion 120,
And a second pressing part (140) for applying a pressing force to the electric pole in the process of being mounted on the electric pole,
The first pressing portion 130,
A first guider 131 formed on the clamp base 110 and having a first guide groove 131a opened to one side of the pole guide groove 111;
A first urging member 132 which is inserted into the first guider 131 and slidably moves toward and away from the pole guide groove 111 side and has a tip portion 132a at its tip; And
A first adjusting bolt 133 which is inserted into the first guider 131 and protruded into the first guide groove 131a and has a rear end joined to the front end thereof,
The second pressurizing portion 140,
A second guider 141 formed in the binding portion 120 and having a second guide groove 141a opened to one side of the pole binding groove 121;
A second pressing member 142 having a V groove 142a formed at the tip end thereof to be in close contact with the periphery of the electric pole, the second pressing member 142 being inserted into the second guider 141 and sliding toward and away from the pole fixing groove 121; And
And a second adjusting bolt (143) which is inserted into the second guider (141) and is projected to the second guide groove (141a) and the rear end of the second pressing member is coupled to the front end thereof. Indirect live lifting device.
delete The method according to claim 1,
The lifting and lowering operation unit 200 includes:
A lift bar guide hole 221 through which the lift bars 210 and 210 'are passed is formed on both sides of the clamp base 110 and the sliding of the lift bars 210 and 210' A lifting portion case 220 on which a guide roller 222 for guiding is formed;
The upper pinions 232 (232) are formed inside the lifting portion case 220 and horizontally both sides of the lifting portion case 220 are extended on both sides and the lifting racks 211 of the lifting bars 210 and 210 ' And an elevating worm shaft 235 having a horizontal interlocking spur gear 237 at a lower portion thereof so that the horizontal rotation of the elevating worm shaft 235 is transmitted to the elevating rotary shaft 231 231 in the vertical direction by the lift worm box 230;
A lower pinion 242 and a lower sprocket 243 corresponding to the upper pinion 232 and the upper sprocket 233 on both sides and meshed with the elevating rack 211 are formed and axially installed in the elevating portion case 220, The upper sprocket 233 and the lower sprocket 243 are connected to the chain 244 and are connected to the lift rotation shaft 231 by a pair of lift-motion interlocking shafts 240 on both sides. And
The lifting and lowering worm box 230 is vertically installed on one side of the lifting worm box 230. Upper and lower ends of the lifting worm box 230 are provided with lifting and lowering adjusting tool engaging portions 250a projecting upward and downward from the lifting portion case 220, And an elevation drive shaft (250) having a driving spur gear (252) engaged with the elevation drive shaft (250).
The method according to claim 1,
The horizontal operation portion 300 includes:
A pair of lifting and lowering bar fixing pipes 321 and 321 'on both sides where the upper ends of the lifting bars 210 and 210' on both sides are fixed and a pair of lifting and lowering bar fixing pipes 321 and 321 'on both sides of the lifting bar fixing pipes 321 and 321' The horizontal bar guide holes 323 are formed at the center of the horizontal bars 310 and 310 to extend through the horizontal bars 310 and 310 ' A horizontal part base 320 having a pair of horizontal bar guide pipes 322 and 322 'and a shank part 325 protruding downward between the pair of vertical bar fixing pipes 321 and 321';
A first horizontal drive shaft 331 formed vertically to the shaft portion 325 and having a first tool engaging portion 331a formed at an upper end and a lower end thereof and a first drive spur gear 332 formed at an intermediate portion thereof, A first horizontal worm shaft 333 having a first cooperating spur gear 334 and a second cooperating spur gear 334 vertically formed on the first driving spur gear 332 and vertically aligned with the first driving spur gear 332, A first horizontal rotation shaft 336 having a first pinion 338 coupled with a horizontal rack 311 of one horizontal bar 310 is formed so that the horizontal rotation force of the first horizontal worm shaft 333 is transmitted to the first horizontal rotation axis A first horizontal actuating part 330 comprising a first horizontal warm box 339 for converting the rotational force of the first horizontal warm box 336 into a vertical rotational force of the first horizontal warm box 336; And
A second tool engaging portion 341a is formed at an upper end and a lower end thereof, and a second drive spur gear 342 is provided at an intermediate portion of the second tool engaging portion 341a, which is spaced apart from the first horizontal warm box 339, A second horizontal worm shaft 343 having a second horizontal driving shaft 341 formed thereon and a second cooperating spur gear 344 axially extended to the shaft portion 325 and engaged with the second driving spur gear 342, A second horizontal rotation shaft 346 having a second pinion 338 formed on the tongue 325 and having a second pinion 338 coupled to the horizontal rack 311 of the other horizontal bar 310 ' And a second horizontal operating part 340 which is a second horizontal warm box 349 for converting the horizontal rotating force of the worm shaft 343 into the vertical rotating force of the second horizontal rotating shaft 346 Indirect live wire lifting device for distribution lines.
The method according to claim 1,
In the horizontal bars 310 and 310 '
Further comprising at least one insulated twist roller (400) capable of guiding the live wire,
The insulation twist roller 400,
A clamp 410 is formed to be mounted on the horizontal bars 310 and 310 'and one side of the clamp 410 is constituted by a live wire guide part 420 through which the live wire is inserted and guided by opening / Indirect live wire lifting device for distribution lines.
The method according to claim 1,
Two indirect live lifting devices are installed symmetrically around the pole,
Each of the clamp bases 110 surrounds the pole, while being fixedly coupled with each other,
Wherein each of the opposite ends of the horizontal bar (310) opposed to the symmetrical horizontal operating parts (300) is connected to the horizontal bar connecting part (350) .
In the uninterruptible power supply method for replacing the pin shaft in the process of installing the uninterruptible power distribution line,
A lifting device mounting step of mounting the indirect live-wire lifting device 1 to the electric pole 10 for replacing the existing pin shaft 11 by using the mounting portion 100;
The insulation twisting rollers 400 operate the elevation operation unit 200 and the horizontal operation unit 300 in a state where the insulation twisting rollers 400 are installed at predetermined intervals in consideration of the spacing of the extra high voltage power lines 21 so that the elevation bars 210 and 210 ' A position adjusting step of adjusting the up and down lifting and lowering of the horizontal and vertical bars 310 and 310 'to the left and right so as to position the insulation twist roller 400 close to the extra-high voltage power line 21;
The extra high voltage power line 21 is received and constrained in the live wire guide portion 420 of the insulation twist roller 400 so that the elevated bar 210 and 210 ' Separating the horizontal bars 310 and 310 'from the elbow insulator of the main body 11 and separating the horizontal bars 310 and 310' to a safe separation distance on both sides;
A long pole replacement step of removing the existing pin shaft 11 from which the extra-high voltage power line 21 is separated and installing a new pin shaft 11 'at a position where the existing pin shaft 11 is dismantled;
The elevating operation part 200 and the horizontal operating part 300 are operated to pull the horizontal bars 310 and 310 'and lower the elevating bars 210 and 210' 11 ') on the elbow insulator; And
The insulated twisted roller 400 is opened and the elevating operation part 200 is operated to separate the horizontal bars 310 and 310 'from the extra high voltage power line 21 and detach the mounting part 100 to the electric pole 10 And the lifting device for removing the indirect lifting line lifting device (1) is demolished by using the indirect lifting line lifting device for the distribution line.
In the uninterruptible power supply method for changing the pin shaft to the built-in built-in light guide rail in the process of uninterrupted distribution line construction,
A lifting device mounting step of mounting the indirect live-wire lifting device 1 to the electric pole 10 for replacing the existing pin shaft 11 by using the mounting portion 100;
The insulation twisting rollers 400 operate the elevation operation unit 200 and the horizontal operation unit 300 in a state where the insulation twisting rollers 400 are installed at predetermined intervals in consideration of the spacing of the extra high voltage power lines 21 so that the elevation bars 210 and 210 ' A position adjusting step of adjusting the up and down lifting and lowering of the horizontal and vertical bars 310 and 310 'to the left and right so as to position the insulation twist roller 400 close to the extra-high voltage power line 21;
The extra high voltage power line 21 is received and constrained in the live wire guide portion 420 of the insulation twist roller 400 so that the elevated bar 210 and 210 ' Separating the horizontal bars 310 and 310 'from the elbow insulator of the main body 11 and separating the horizontal bars 310 and 310' to a safe separation distance on both sides;
A long-length replacement step of removing the existing pin shaft 11 from which the extra-high voltage power line 21 is separated and installing a new built-in main shaft 12 'made of a single built-in light guide iron at a position where the existing pin shaft 11 is removed;
The elevator 30 is installed on both sides of the new built-in main body 12 'and the elevating operation part 200 and the horizontal actuating part 300 are operated to move the elevating bars 210 and 210' Power supply line 21 is brought close to the conductor 30 and the both sides of the extra-high voltage power line 21 are held and fixed by using the conductor 30, A power line fixing step of connecting the high voltage power line 21 to the new jumper line 42;
Separating the joining machine 30 from the extra high voltage power line 21 and operating the elevating operation part 200 to separate the horizontal bars 310 and 310 'from the extra high voltage power line 21 and remove the mounting part 100 And the lifting device for lifting the indirect lifting line lifting device (1) mounted on the electric pole (10) is demolished. The indirect lifting line lifting method using the indirect lifting line lifting device for the distribution line.
In an uninterrupted power supply method for changing a pin shaft into a double ear wire built-in main line in an uninterruptible power distribution line,
A lifting device mounting step of mounting the indirect live-wire lifting device 1 to the electric pole 10 for replacing the existing pin shaft 11 by using the mounting portion 100;
The insulation twisting rollers 400 operate the elevation operation unit 200 and the horizontal operation unit 300 in a state where the insulation twisting rollers 400 are installed at predetermined intervals in consideration of the spacing of the extra high voltage power lines 21 so that the elevation bars 210 and 210 ' A position adjusting process for adjusting the upper and lower lifting and lowering of the horizontal bar 310 and the horizontal bar 310 to adjust the left and right of the horizontal bar 310 and 310 '
The extra high voltage power line 21 is received and constrained in the live wire guide portion 420 of the insulation twist roller 400 so that the elevated bar 210 and 210 ' A power line separating step of separating the high voltage power line from the elbow insulator of the high voltage power line 11 and opening the horizontal bars 310 and 310 '
A step of replacing the existing pin shaft 11 from which the extra-high voltage power line 21 is separated and a new step of replacing the existing pin shaft 11 with the new built-in shaft 12 ';
The elevator 30 is installed on both sides of the new built-in main body 12 'and the elevating operation part 200 and the horizontal actuating part 300 are operated to move the elevating bars 210 and 210' ) Of the extra high voltage power line 21 by pulling the left and right sides of the extra high voltage power line 21 to close the super high voltage power line 21 to the super long conductor 30, A power line fixing step of connecting the power line (21) with a new jumper wire (42);
Separating the joining machine 30 from the extra high voltage power line 21 and operating the elevating operation part 200 to separate the horizontal bars 310 and 310 'from the extra high voltage power line 21 and remove the mounting part 100 And the lifting device for lifting the indirect lifting line lifting device (1) mounted on the electric pole (10) is demolished. The indirect lifting line lifting method using the indirect lifting line lifting device for the distribution line.
In an uninterrupted power supply method for replacing a built-in built-in light-gauge interiors with an uninterruptible power distribution line,
A lifting device mounting step of mounting the indirect live-wire lifting device 1 symmetrically on both sides of the electric pole 10 for replacing the existing built-in main body 12 using the mounting portion 100;
The height of the horizontal bars 310 and 310 'is adjusted by operating the lifting operation part 200 of each indirect live lifting device 1 to adjust the height of the lifting bars 210 and 210' A position adjustment step of bringing the power line 21 close to the power line 21;
The horizontal bar 310 and the horizontal bar 310 corresponding to the respective indirect live line lifting devices 1 are installed and the extra high voltage power line of the existing built-in main line 12 21, and fixing the first power line by separating from the existing built-in main body 12 while adjusting the tension of the extra-high voltage power line 21 by using the joiner 30;
A power line longitudinal pulling-up step of moving the elevating operation part 200 corresponding to each of the indirect live-wire lifting devices 1 up or down to separate the extra-high voltage electric power line 21 into a safety separation distance;
A long length replacement step of dismounting the existing built-in mains 12 from which the extra-high voltage power line 21 is separated and installing a new built-in mains 12 'made of a single built-
The elevating operation part 200 corresponding to each indirect live lifting device 1 is moved to the upper part or the lower part to bring the extra high voltage power line 21 close to the newly built internal lid 12 ' A second power line splicing step of splicing the extra-high voltage power line 21 to the new built-in splice 12 'while adjusting the tension of the extra-high voltage power line 21; And
The joining machine 30 is separated from the extra high voltage power line 21 and the elevating operation part 200 corresponding to each of the indirect live wire pulling devices 1 is operated so that the horizontal bars 310 and 310 ' The lifting device lifting step for lifting the lifting device for pulling up the indirect live-wire lifting device 1 mounted on the electric pole 10 is carried out by separating the mounting portion 100 from the main lifting device 21 and indirectly using the indirect lifeline lifting device for a power distribution line Live uninterrupted method.
In an uninterrupted power supply method for replacing a built-in double insulated mains in an uninterruptible power distribution line,
A lifting device mounting step of mounting the indirect live-wire lifting device 1 symmetrically on both sides of the electric pole 10 for replacing the existing built-in main body 12 using the mounting portion 100;
The height of the horizontal bars 310 and 310 'is adjusted by operating the lifting operation part 200 of each indirect live lifting device 1 to adjust the height of the lifting bars 210 and 210' A position adjustment step of bringing the power line 21 close to the power line 21;
The horizontal bar 310 and the horizontal bar 310 corresponding to the respective indirect live line lifting devices 1 are installed and the extra high voltage power line of the existing built-in main line 12 21, and fixing the first power line by separating from the existing built-in main body 12 while adjusting the tension of the extra-high voltage power line 21 by using the joiner 30;
A power line longitudinal pulling-up step of moving the elevating operation part 200 corresponding to each of the indirect live-wire lifting devices 1 up or down to separate the extra-high voltage electric power line 21 into a safety separation distance;
A step of replacing the existing built-in mains 12 from which the extra-high voltage power line 21 has been separated and installing a new built-in mains 12 'made of double-layered wire at the position where the existing built-in mains 12 is removed;
The elevating operation part 200 corresponding to each indirect live lifting device 1 is moved to the upper part or the lower part to bring the extra high voltage power line 21 close to the newly built internal lid 12 ' A second power line splicing step of splicing the extra-high voltage power line 21 to the new built-in splice 12 'while adjusting the tension of the extra-high voltage power line 21; And
The joining machine 30 is separated from the extra high voltage power line 21 and the elevating operation part 200 corresponding to each of the indirect live wire pulling devices 1 is operated so that the horizontal bars 310 and 310 ' The lifting device lifting step for lifting the lifting device for pulling up the indirect live-wire lifting device 1 mounted on the electric pole 10 is carried out by separating the mounting portion 100 from the main lifting device 21 and indirectly using the indirect lifeline lifting device for a power distribution line Live uninterrupted method.
In the uninterruptible power supply method for replacing the one -
A pulling-up device mounting step of mounting the indirect live-wire pulling-up device 1 to the electric pole 10 for replacing the existing parting shaft 13 using the mounting part 100;
The insulation twisting rollers 400 operate the elevation operation unit 200 and the horizontal operation unit 300 in a state where the insulation twisting rollers 400 are installed at predetermined intervals in consideration of the spacing of the extra high voltage power lines 21 so that the elevation bars 210 and 210 ' A position adjusting step of adjusting the up and down lifting and lowering of the horizontal and vertical bars 310 and 310 'and adjusting the left and right of the horizontal bars 310 and 310' to bring the insulation twill roller 400 close to the extra high voltage power line 21;
The extra high voltage power line 21 is received and constrained in the live wire guide section 420 of the insulation twist roller 400 to elevate the elevation bar 210 and 210 ' A power line longitudinal pulling-up step of moving upwardly from the elbow insulator of the longitudinal strip 13 and separating it into a safety distance;
(13) of the existing high voltage power line (21) is removed, and the new long line replacement line (13 ') is installed at the position where the existing line pin line (13) is removed;
A power line installing step of operating the elevating operation portion 200 to lower the elevating bars 210 and 210 'and to seat the extraordinary high voltage power line 21 on the elongated insulator of the new part forming long axis 13'; And
The insulated twisted roller 400 is opened and the elevating operation part 200 is operated to separate the horizontal bars 310 and 310 'from the extra high voltage power line 21 and detach the mounting part 100 to the electric pole 10 And the lifting device for removing the indirect lifting line lifting device (1) is demolished by using the indirect lifting line lifting device for the distribution line.
In the uninterruptible power supply method for changing the single-piece built-in type light-gauge-wire built-in built-in integrated circuit in the uninterrupted distribution line construction process,
A pulling-up device mounting step of mounting the indirect live-wire pulling-up device 1 to the electric pole 10 for replacing the existing parting shaft 13 using the mounting part 100;
The insulation twisting rollers 400 operate the elevation operation unit 200 and the horizontal operation unit 300 in a state where the insulation twisting rollers 400 are installed at predetermined intervals in consideration of the spacing of the extra high voltage power lines 21 so that the elevation bars 210 and 210 ' A position adjusting step of adjusting the up and down lifting and lowering of the horizontal and vertical bars 310 and 310 'and adjusting the left and right of the horizontal bars 310 and 310' to bring the insulation twill roller 400 close to the extra high voltage power line 21;
The extra high voltage power line 21 is received and constrained in the live wire guide section 420 of the insulation twist roller 400 to elevate the elevation bar 210 and 210 ' A power line longitudinal pulling-up step of moving upwardly from the elbow insulator of the longitudinal strip 13 and separating it into a safety distance;
A method of removing the existing slab-type slab 13 from which the extra-high voltage power line 21 has been removed and replacing the existing slab-type slab 13 with a new built-in slab 14 ';
The elevator 30 is installed on both sides of the new built-in embedding main body 14 'and the elevating operation parts 200 are operated to lower the elevating bars 210 and 210' A power line fixing step of bringing both side extra-high voltage power lines 21 to a new jumper line 42 while holding both sides of the extra high voltage power line 21 by using the joiner 30; And
Separating the joining machine 30 from the extra high voltage power line 21 and operating the elevating operation part 200 to separate the horizontal bars 310 and 310 'from the extra high voltage power line 21 and remove the mounting part 100 And the lifting device for lifting the indirect lifting line lifting device (1) mounted on the electric pole (10) is demolished. The indirect lifting line lifting method using the indirect lifting line lifting device for the distribution line.
In the uninterrupted power supply method for changing the power supply line in the process of uninterrupted power distribution line to the dual built-in power supply,
A pulling-up device mounting step of mounting the indirect live-wire pulling-up device 1 to the electric pole 10 for replacing the existing parting shaft 13 using the mounting part 100;
The insulation twisting rollers 400 operate the elevation operation unit 200 and the horizontal operation unit 300 in a state where the insulation twisting rollers 400 are installed at predetermined intervals in consideration of the spacing of the extra high voltage power lines 21 so that the elevation bars 210 and 210 ' A position adjusting process of placing the insulation twist roller 400 on the extra-high voltage power line 21 by adjusting the vertical and horizontal lifts and the horizontal bars 310 and 310 '
The extra high voltage power line 21 is received and constrained in the live wire guide section 420 of the insulation twist roller 400 to elevate the elevation bar 210 and 210 ' A power line longitudinal pulling-up process for upwardly moving the extra-high voltage power line to a safe separation distance from the elbow insulator of the long axis (13);
A step of replacing the existing slanting line 13 in which the extra high voltage power line 21 is separated and a new slanting built-in slanting line 14 'in which the existing slanting line 13 is demolished;
The elevator 30 is installed on both sides of the new built-in embedding main body 14 'and the elevating operation parts 200 are operated to lower the elevating bars 210 and 210' A power line fixing step of bringing both side extra-high voltage power lines 21 to a new jumper line 42 while holding both sides of the extra high voltage power line 21 by using the joiner 30; And
Separating the joining machine 30 from the extra high voltage power line 21 and operating the elevating operation part 200 to separate the horizontal bars 310 and 310 'from the extra high voltage power line 21 and remove the mounting part 100 And the lifting device for lifting the indirect lifting line lifting device (1) mounted on the electric pole (10) is demolished. The indirect lifting line lifting method using the indirect lifting line lifting device for the distribution line.
In an uninterrupted power supply method for replacing a built-in built-in incandescent insulated integrated circuit in an uninterruptible power distribution line,
A lifting device mounting step of mounting the indirect live-wire lifting device 1 symmetrically on both sides of the electric pole 10 for replacing the existing built-in built-in electric main by using the mounting part 100;
The height of the horizontal bars 310 and 310 'is adjusted by operating the lifting operation part 200 of each indirect live lifting device 1 to adjust the height of the lifting bars 210 and 210' A position adjustment step of bringing the power line 21 close to the power line 21;
The horizontal bars 310 and 310 'corresponding to the respective indirect live-wire lifting devices 1 are provided with the girder 30 and the extra-high voltage power line A first power line lead fixing step of holding and fixing the lead wire 21 and separating from the existing lead embedded lead wire 14 while adjusting the tension of the extra high voltage power line 21 by using the lead wire 30;
The elevating bars 210 and 210 'are moved upward or downward by the operation of the elevating operation unit 200 and the horizontal actuating unit 300 corresponding to the respective indirect live line lifting devices 1, A power line separation and separation process for separating the power line into a safe separation distance;
A long replacement process of removing the existing built-in built-in lid 14 from which the extra-high voltage power line 21 has been separated and installing a new built-in built-in lid 14 'made of a single built-
The elevating bars 210 and 210 'are lowered or raised by the operation of the elevating operation part 200 corresponding to each indirect live lifting device 1 so that the extra high voltage power line 21 is inserted into the new built- A second power line lead fixing step of bringing the extra-high voltage power line 21 to the new built-in built-in lead 14 'while adjusting the lead of the extra-high voltage power line 21 by using the joiner 30; And
The joining machine 30 is separated from the extra high voltage power line 21 and the elevating operation part 200 corresponding to each of the indirect live wire pulling devices 1 is operated so that the horizontal bars 310 and 310 ' The lifting device lifting step for lifting the lifting device for pulling up the indirect live-wire lifting device 1 mounted on the electric pole 10 is carried out by separating the mounting portion 100 from the main lifting device 21 and indirectly using the indirect lifeline lifting device for a power distribution line Live uninterrupted method.
In an uninterrupted power supply method for replacing a built-in double-insulated built-in mains in an uninterrupted distribution line,
A lifting device mounting step of mounting the indirect live-wire lifting device 1 symmetrically on both sides of the electric pole 10 for replacing the existing built-in built-in electric main by using the mounting part 100;
The height of the horizontal bars 310 and 310 'is adjusted by operating the lifting operation part 200 of each indirect live lifting device 1 to adjust the height of the lifting bars 210 and 210' A position adjustment step of bringing the power line 21 close to the power line 21;
The horizontal bar 310 and the horizontal bar 310 corresponding to the respective indirect live line lifting devices 1 are installed and the extra high voltage power line of the existing built-in main line 12 A first power line lead fixing step of holding and fixing the power lines 21 to the horizontal bars 310 and 310 'while adjusting the tension of the extra-high voltage power line 21 by using the joists 30;
The elevating bars 210 and 210 'are moved upward or downward by the operation of the elevating operation unit 200 and the horizontal actuating unit 300 corresponding to the respective indirect live line lifting devices 1, A power line separation and separation process for separating the power line into a safe separation distance;
A long length replacement step of removing the existing built-in built-in lug main body 14 from which the extra-high voltage power line 21 is separated and installing a new built-in built-in lug main body 14 '
The elevating bars 210 and 210 'are lowered or raised by the operation of the elevating operation part 200 corresponding to each indirect live lifting device 1 so that the extra high voltage power line 21 is inserted into the new built- A second power line lead fixing step of separating from the existing lead built-in lead 14 while adjusting the lead of the extra-high voltage power line 21 by using the lead wire 30;
The joining machine 30 is separated from the extra high voltage power line 21 and the elevating operation part 200 corresponding to each of the indirect live wire pulling devices 1 is operated so that the horizontal bars 310 and 310 ' The lifting device lifting step for lifting the lifting device for pulling up the indirect live-wire lifting device 1 mounted on the electric pole 10 is carried out by separating the mounting portion 100 from the main lifting device 21 and indirectly using the indirect lifeline lifting device for a power distribution line Live uninterrupted method.
In the uninterruptible power supply method for changing the history of the built-in main section during the uninterrupted distribution line construction,
A pulling-up device installing step of mounting the indirect live-wire pulling-up device 1 by using the mounting part 100 to the one electric pole 10a and the other electric pole 10b of the glade changing area where the existing built-in pouch 12 is formed;
The lifting and lowering operation of the lifting bars 210 and 210 'is controlled by operating the lifting and lowering operation part 200 of the indirect live lifting device 1 mounted on each of the electric poles 10a and 10b, (310 ') is brought close to the extra-high voltage power line (22) to be removed in the change section;
It is possible to install the joists 30 on the horizontal bars 310 and 310 'corresponding to the indirect live-wire lifting device 1 of each of the two side poles 10a and 10b of the change section, A special high voltage power line 22 located inside the built-in main body 12 is held and fixed and the tension of the extra high voltage power line 22 to be demolded is adjusted by using the super high voltage power line 30, Fixing the power line to the horizontal bars 310 and 310 'by separating the power lines 22 from the existing built-in lugs 12;
It is possible to connect the extra high voltage power line 21 outside the change section around the electric poles 10a and 10b with the bypass jumper cable 50 at both sides of the separated extra high voltage power line 22 to be temporarily operated Jumper cable connection process;
The lift bars 210 and 210 'are moved upward or downward by the operation of the lift actuating part 200 and the horizontal actuating part 300 corresponding to the respective indirect live wire lifting devices 1, 22) to a safe separation distance;
A span separation process for securing a safe working space in the change section by separating the span between the change section and the existing jumper line (41) of the existing line;
A new span installation process in which a new high voltage power line 23 such as a new electric pole, a new span, and a new span is connected to the location where the old span is to be changed and a long span is made to the new built span 12 ';
The extra-high voltage power line 21 and the extra high voltage power line 23 of the both side poles 10a and 10b are connected by the new jumper line 42 and the extra high voltage power line 21 and the extra high voltage power line 22 A jumper line connecting step of disconnecting the bypass jumper cable 50 connected to the bypass jumper cable 50; And
Removal of the extra high-voltage power line 22 to be removed from the indirect live-wire lifting device 1 and removal of the transient live-wire lifting device 1 mounted on the two electric poles 10a and 10b, And the lifting process of the lifting device is carried out by using the indirect lifting line lifting device for the distribution line.
In the uninterruptible power supply method for changing the interval of the section after the change of the main line when the start and end of the work section in the process of uninterrupted distribution line work,
A pulling-up device installing step of mounting the indirect live-wire pulling-up device 1 by using the mounting portion 100 to one side electric pole 10a and the other side electric pole 10b, respectively, where the existing pin shaft 11 is formed;
The lifting operation part 200 and the horizontal operation part 300 of the indirect live-line lifting device 1 mounted on the electric poles 10a and 10b are operated to move the lifting bars 210 and 210 ' A position adjustment process of adjusting the horizontal bars 310 and 310 'to the left and right and positioning them close to the extra-high voltage power line 21;
The extra high voltage power line 21 is received and constrained in the live wire guide portion 420 of the insulation twist roller 400 so that the elevated bar 210 and 210 ' Separating the horizontal bars 310 and 310 'from the elbow insulator of the main body 11 and separating the horizontal bars 310 and 310' to a safe separation distance on both sides;
(11) of both sides of the work area where the high-voltage power line (21) is separated and the new built-in main shaft (12 ') made of a single built-in brace iron or double helix at the position where the existing pin shaft Establishment of Changzhou New Establishment Process;
The joist 30 is provided in the horizontal bar 310 on the side of the extra high voltage power line 22 to be demounted and the extra high voltage power line 21 outside the newly built internal lid 12 ' And the elevating operation unit 200 and the horizontally operating unit 300 are operated to move the elevating bars 210 and 210 'downward and to the left and right of the horizontal bars 310 and 310' Power line fixing process for temporarily fixing the extra-high voltage power line 21 and the extra-high voltage power line 22 to be demolded by using the supercharger 30 by pulling the special high voltage power line 21 close to the multiplexer 30, ;
A bypass jumper cable 50 is connected to both the extra-high voltage power line 21 outside the change section and both sides of the extra high voltage power line 22 to be removed in the change section around the both side poles 10a and 10b, A jumper cable connection process for operation;
A span separation step of separating the span between the change section and the existing jumper wire 41 of the existing line and separating the extra high voltage power line 21 in the span inside the joiner 30 to secure a safe work space in the change section;
A new span installation process in which a new high voltage power line 23 such as a new electric pole, a new span, and a new span is connected to the location where the old span is to be changed and a long span is made to the new built span 12 ';
A jumper wire connecting process for connecting the extra high voltage power line 21 and the new extra high voltage power line 23 outside the work section to the new jumper wire 42 around the new built-in main wire 12 'on both sides of the work section;
The extra high voltage power line 21 fixed to the supercharger 30 is cut around the new jumper line 42 with respect to the passage change period and the extra high voltage power line 21 outside the change section and the extra high voltage power line 22; And
A lifting device 30 for lifting the indirect live-wire lifting device 1 mounted on both the electric poles 10a and 10b by separating the long-circuiting device 30 from the extra-high voltage power line 22, demolishing the long- And the demolition process is performed by using the indirect lifeline lifting device for the distribution line.
19. The method according to any one of claims 7 to 18,
When the extra-high voltage power line 21 has a plurality of phases,
And the plurality of phases are carried out together. An indirect live wire uninterruptible method using an indirect live wire lifting device for a distribution line.
19. The method according to any one of claims 7 to 18,
When the extra-high voltage power line 21 forms a plurality of stages of a plurality of stages in one electric pole,
And the plurality of lines are carried out together. The indirect live line uninterrupted method using an indirect live line lifting device for a distribution line.
19. The method according to any one of claims 7 to 18,
When the electric pole is replaced,
A new electric pole 10 'is installed on one side of the electric pole 10 in a state where the extra-high voltage electric power line 21 is separated by a safe separation distance and a new pin shaft 11' (12 ') and an extra-high voltage power line is connected to the new pin rail (11') or the new built-in main rail (12 ').
19. The method according to any one of claims 7 to 18,
If you are planning to install a new electric pole,
The induction electric pole 10 "is newly installed on one side of the electric pole 10 in a state where the extra high voltage electric power line 21 is separated by the safe separation distance and the new intrusion electric pole 11 ' (12 ') and an extra-high voltage power line is connected to the new pin rail (11') or the new built-in main rail (12 ').

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