RU2817512C1 - Method of maintenance of strings of insulators of power transmission line, which is under voltage - Google Patents

Abstract

FIELD: production, conversion and distribution of electric energy.

SUBSTANCE: invention relates to methods of operation, repair or dismantling of overhead wire and cable power transmission lines, which are under voltage. Method includes transportation of insulating module 1 on support 2 of power transmission line, installation and fixation of insulating module 1 on crossbar 3, disconnecting current-carrying wire 7 from insulator strings 10 and fixing it on insulating module 1, replacing the insulator, disconnecting current-conducting wire 6 from insulating module 1 and connecting it to insulator strings 10. Disconnection of current-carrying wire 7 from insulator strings 10, its fixation on insulating module 1, disconnection of current-carrying wire 7 from insulating module 1 and its connection to insulator strings 10 is performed by performer of works 4 or 5 located on aircraft 6.

EFFECT: providing the possibility of access of the work performer to the elements of the current-carrying wire fastening without mounting and dismantling of the lifting equipment mechanisms with exclusion of short circuit.

3 cl, 4 dwg

Description

The invention relates to methods for operating, repairing or dismantling overhead wire and cable power lines and can be used when servicing garlands of insulators for live power lines.

There is a known method for servicing garlands of insulators of an energized power line, implemented by using a device for replacing garlands of insulators (authentic certificate SU 1228177, M. Class ⁴ H02G 1/02, publ. 1986) including the participation of at least three performers works (electricians). One of them climbs the ladder onto the traverse of the power line support and secures the rope block at a distance of 0.5-1 m from the support post. The second electrician, located on the ground, screws in the anchor and secures the second end of the rope through the roller. With the help of a rope, a jack with a beam is supplied to the traverse, which is installed on a support above the supporting garland of insulators, insulating blocks that are attached to different channels of the traverse, a block that is attached to the top of the traverse, a traction rope that is passed through the blocks and lowered to the ground with its free end and connected to the upper part of the insulator, the second end of which is connected to the upper part of the hanging mechanic's chair, a polypropylene rope tucked into two blocks and secured to the upper part of the chair, and the other end to the cable of the emergency mechanism, plastic rods that are suspended by hooks on the wires, and the second ends are connected to the jack cable. A rope ladder and an auxiliary insulating rope are attached to the bottom of the chair. Using a winch, lift the chair without an electrician to the level of the wire and use a rope to bring it to the wire, keeping it under voltage for 1 minute. After the insulation test, the chair is lowered to the ground. It then houses a third electrician, who is wearing a protective shielding kit. The presence of electrical connections between the elements of the shielding kit is checked, and the potential transfer rods on the chair are connected. Using a winch and a traction rope, the chair is lifted to the live wire at a distance of 0.3-0.5 m. An electrician located in the chair, through the opening, first transfers the power potential and then the potential wire potential with rods to the chair and the shielding set. The lifting of the suspended mechanic's chair ends when the upper end of the ribbed insulator approaches the traverse at a distance of no more than 0.3 m. The winch is stopped, the chair is connected to the wire using an auxiliary rope, and the upper part of the ribbed insulator is reconnected to the channel of the traverse. The end of the traction rope is passed through the block and reconnected to the top of the insulator string. The auxiliary insulating rope is also reconnected to the bottom of the insulator garland. The tension is released through the block with a traction rope and the garland of insulators is disconnected from the supporting clamp. Using a rope ladder, a chair is moved from the ground along the wire to a distance of 0.5 m from the garland of insulators, the garland of insulators is disconnected from the traverse, pulled from the ground using an auxiliary insulating rope and lowered to the ground. Repairs and replacement of defective elements of the insulator garland are carried out. The repaired garland of insulators is winched up to the traverse. An electrician on the traverse attaches a garland of insulators to the traverse of the support. The electrician in the chair brings the string of insulators to the wire, disconnects the auxiliary insulating rope from it and attaches it to the bottom. An electrician on the traverse reconnects the end of the traction rope to the ribbed insulator, lifts it using a winch and disconnects the end from the fastening on the traverse. Electricians on the ground use a rope ladder and an auxiliary insulating rope to support the suspended electrician's chair, and the electrician in the chair releases the fastenings of the chair to the wires and prepares the power and potential rods to move away from the wire. The winch lowers the chair to a distance of 0.5 m from the wire. An electrician in a chair quickly removes the potential and then the power rod. After this, the electrician on the ground continues to lower the chair to the ground. The electrician on the traverse lowers the jack and transfers the load of the weight of the wire to the garland of insulators. Equipment and fixtures are dismantled and lowered to the ground. The electrician, located on the traverse, lowers to the ground.

The disadvantage of this method is its high labor intensity, which is explained by the need to install lifting equipment mechanisms, which require the participation of at least three performers. In addition, if it is necessary to change the position of the electrician located in the chair, in order to provide access to the fastening elements of the current-carrying wire and garlands, it is necessary to dismantle and re-install the ropes with fastenings to the traverse, and the mechanisms of the chair’s lifting equipment. This increases the likelihood of a short circuit when accessing the service areas of the insulator strings. Also, at high humidity, conductive tracks can form on the insulating parts of lifting mechanisms, serving as a channel for the floors. Also, on some lines, as the distance between the wire and the support post decreases, it becomes necessary to place an electrician on the outside of the wire, which will require the installation of an additional console block at the end of the support beam.

The closest to the claimed method and adopted as a prototype is the method of servicing garlands of insulators of an energized power line (I.G. Barg, S.V. Polevoy “Repair of overhead power lines under voltage”, M., Energoatomizdat, 1989. , pp. 104-105), including transporting the insulating module (retractable frame) to the power line support, installing and fixing the insulating module on the traverse of the power line support, disconnecting the current-carrying wire from the insulator garlands and fixing it on the insulating module (on the frame roller), replacing the insulator garlands, disconnecting the current-carrying wire from the insulating module and connecting it to the insulator garlands.

The disadvantage of this method is its high labor intensity, which is explained by the need to install lifting equipment mechanisms to deliver an electrician, which requires the participation of at least three workers. In addition, if it is necessary to change the position of the electrician located on the ladder, in order to provide access to the fastening elements of the current-carrying wire (both on the insulating module and to the garlands of insulators), it is necessary to dismantle and re-install the mechanisms of the lifting equipment. Also, at high humidity, conductive paths can form on the insulating parts of lifting mechanisms, serving as a channel for the ceiling (i.e., it can lead to a short circuit).

The technical result of the proposed method is to provide the worker with access to the fastening elements of the current-carrying wire (both on the insulating module and to the garlands of insulators) without installing and dismantling the mechanisms of lifting equipment, other auxiliary devices and equipment, such as insulating ladders, ladders, ropes, excluding the possibility of a short circuit between the live wire and elements of the power line support or the ground, or other live wires in the power line.

The technical result is achieved by improving the method of servicing garlands of insulators of an energized power line, including transporting the insulating module to a power line support, installing and fixing the insulating module on the traverse of the power line support, disconnecting the current-carrying wire from the garlands of insulators and fixing it on the insulating module , replacing the insulator, disconnecting the current-carrying wire from the insulating module and connecting it to the garlands of insulators.

This improvement consists in the fact that the disconnection of the current-carrying wire from the garlands of insulators, fixing it on the insulating module, the disconnection of the current-carrying wire from the insulating module and its connection to the garlands of insulators is carried out by the work performer located on the aircraft.

Such operations performed by a work performer located on an aircraft allows the work performer to have reliable access to the elements of fastening the current-carrying wire (both on the insulating module and to the insulator garlands) without installing and dismantling the lifting equipment mechanisms due to the possibility of the work performer approaching the work sites maintenance work. This eliminates the possibility of a short circuit between the live wire and elements of the power line support or the ground, or other live wires in the power line.

In addition, a robotic manipulator can be used as a performer of work, which makes it possible to mechanize the performance of maintenance work on garlands of insulators of an energized power line.

In addition, the performer of the work can be an electrician who is delivered to the places of maintenance work by aircraft - an option for servicing garlands of insulators of an energized power line when it is not economically feasible to use an expensive robotic manipulator.

The method is illustrated by drawings, in which in Fig. 1 shows a power line support at the moment of approach of an aircraft with a work performer - a robotic manipulator; in FIG. 2 - extension element A of FIG. 1 on an enlarged scale, in FIG. 3 shows a power line support at the moment of approach of an aircraft with a work performer - an electrician; in FIG. 4 - extension element B of fig. 3 enlarged,

The method of servicing garlands of insulators of an energized power line is carried out as follows.

The necessary tools, devices and accessories are transported to the place of work on servicing the insulator strings, including transporting the insulating module 1 to the power line support 2. On the traverse 3 of the power line support 2, an insulating module 1 is installed and fixed. The performer of the work is a robot manipulator 4 (Fig. 1 and Fig. 2) or an electrician 5 (Fig. 3 and Fig. 4), installed on the aircraft 6, with approaching the current-carrying wire 7 with the help of a shunt wire 8, the potential from the wire is transferred to the aircraft 6 and to the shielding (electrically conductive) set of overalls 9 of the work performer if the work performer is an electrician 5 (the shielding set forms a Faraday cage, inside which the field effect is minimized) , transfer the weight and tension of the wire 7 to the insulating module 1, disconnect the current-carrying wire 7 from the garlands of insulators 10 and fix it on the insulating module 1. Replace the insulator/s 10. After this, the performer 4 or 5 disconnects the current-carrying wire 7 from the insulating module 1 and connects it to the garlands of insulators 10. The performer of work 4 or 5 has the opportunity to fly on an aircraft 6 to the places where maintenance work is carried out. This eliminates the possibility of a short circuit between the current-carrying wire 7 and the elements of the power line support 2 or with the ground, or other current-carrying wires 11 of the power line. When carrying out work, safety requirements are met regarding the inadmissibility of reducing the insulation distance, which takes into account the breakdown voltage between the system wire 7 - the performer of work with the aircraft - traverse 3, post 12 of support 2, or another wire 11 of the power line, or the ground. The insulation distance is calculated based on the geometric parameters of the high-voltage power line and the electric field strength in the line in each specific case. For this purpose, the aircraft 6 is equipped with a system of sensors with software that determines the distances from the current-carrying wire 7, other wires 11, the cross-beam 3 and the rack 12 of the support 2 to the aircraft 6, taking into account the protruding elements with the performer's tool 4 or 5. In the embodiment (Fig. 1 and Fig. 2) using the robot manipulator 4 as a performer, all operations to disconnect the current-carrying wire 7 from the garlands of insulators 8 and fixing it on the insulating module 1, disconnecting the current-carrying wire 7 from the insulating module 1 and connecting it to the garlands of insulators 8 are performed. according to a given program with remote control by an operator on the ground, or in fully automatic mode.

Calculation and modeling showed the possibility of using this method to replace insulators on overhead power lines from 35 kV to 1150 kV on metal lattice supports U35-1+5, U1150-1+5 and steel polyhedral support PM220-2.

Thus, the use of the proposed method provides the ability for the work performer to access the fastening elements of the current-carrying wire (both on the insulating module and to the garlands of insulators) without installing and dismantling the mechanisms of lifting equipment, with the exception of a short circuit between the current-carrying wire and the elements of the power line support, the ground, or other live wires in power lines.

Claims (3)

1. A method for servicing garlands of insulators of an energized power line, including transporting an insulating module to a power line support, installing and fixing the insulating module on the traverse of the power line support, disconnecting the current-carrying wire from the garlands of insulators and fixing it on the insulating module, replacing the insulator, disconnecting the current-carrying wire from the insulating module and connecting it to the garlands of insulators, characterized in that the disconnection of the current-carrying wire from the garlands of insulators, fixing it on the insulating module, disconnecting the current-carrying wire from the insulating module and connecting it to the garlands of insulators is carried out by the work performer located on the aircraft . 2. The method according to claim 1, characterized in that a robotic manipulator is used as a performer of work. 3. The method according to claim 1, characterized in that the performer of the work is an electrician.