CN110943396B - Operation method for live access equipotential of power transmission line in river network area - Google Patents

Abstract

The invention discloses an operation method for electrified access equipotential of a power transmission line in a river network area, which comprises the steps of checking the working site condition, checking tools and materials, checking double names, arranging hanging points on a tower, making a transmission rope system, a transmission pulley block system, enabling an equipotential electrician to enter equipotential, eliminating the defect of the line, enabling the equipotential electrician to exit equipotential, enabling the equipotential electrician to sit in a Chinese character 'shi' ladder and arranging the upper tools and the lower tools of the tower to go out of the equipotential. The invention has the beneficial effects that: in the step A, reasonable and accurate data are conveniently provided for erection of a river network, normal operation of projects is guaranteed, in the step C, tools are convenient to take, the number of operators is increased, working efficiency is improved, in the step D, the pulley system is guaranteed to provide a sufficient labor-saving effect, operation burden of electricians is reduced, erection of wires is facilitated, in the steps A and E, the minimum combination gap is guaranteed to be 5.02 meters, the combination gap is enabled to meet live working conditions, and the operation space of users is guaranteed.

Description

Operation method for live access equipotential of power transmission line in river network area

Technical Field

The invention relates to an operation method, in particular to an operation method for live access equipotential of a power transmission line in a river network area, and belongs to the technical field of erection of power transmission lines in river network areas.

Background

With the high-speed development of power grids in China, the scale of power construction is larger and larger, power transmission line equipment is huge, the terrains of power transmission channel corridors are more and more complex, the natural environments are more and more severe, the proportion of special lines needing to be specially patrolled to all lines is more and more, the difficulty of operation and inspection of the power transmission lines is large, and the quality requirement is high.

Although the existing operation method is widely applied, the problems still exist in the actual use process, one is that the current river network mud and marsh area ditches and ditches are numerous, lakes and fish ponds are numerous, compared with the common transmission line engineering, the river network area has difficult traffic and large electric power operation difficulty, and has higher requirements on live working of the transmission line, the other is that the live working of the transmission line is limited by geographical division of the river network area and bridges according to the characteristics of geology and topography of the river network area, roads are generally difficult to reach a tower position, the geology of the river network area is poor, the underground water level is high, the periphery of a tower foundation is relatively narrow, the third is that the live working of an overhead line relates to high-altitude working, needs to be matched with ground and high-altitude personnel, and places which are relatively flat are needed to put live working tools, the tools used in the live working need to be protected from moisture and insulation, and insulation must be carried out on the near water or on the water of the river network to ensure the moisture protection of the insulation tools such as an insulating pole and an insulating rope, the device can not contact with water, so that the live working of the power transmission line on the near water or water is limited or has potential safety hazard.

Disclosure of Invention

The invention aims to solve the problems and provide an operation method for live access of an electric transmission line in a river network region to an equipotential.

The invention realizes the purpose through the following technical scheme: an operation method for live access of an electric transmission line in a river network area to an equipotential comprises the following steps:

step A: checking the working site condition, checking tools and materials, surveying and detecting the tools on site, putting the tools on a damp-proof tarpaulin, neatly putting the tools, comprehensively checking the appearance without leakage, cleaning the surfaces of a hard insulating tool and a new insulator by using a dry and clean towel, measuring the current temperature and humidity and wind speed by a ground electrician, supervising the appearance checking and testing of the tools and materials by the ground electrician by a working responsible person, and checking the connection condition of the electrician and an equipotential worker wearing shielding clothes on a tower by the working responsible person;

and B: checking the double names, performing a safety tool test, checking the double names of lines and the tower numbers, performing the safety tool test and inspection before tower climbing by a tower climbing person, and recording by a work responsible person;

and C: arranging hanging points on a tower, tying a transmission rope system, enabling an electrician to carry 3 backup protection ropes of 6 meters, climbing an insulating rope sleeve to the end part of a cross arm, tying a 6-meter extension rope, tying two extension ropes of 6 meters to the proper position of the end part of the cross arm, transmitting the other ends of the 2 extension ropes to the equipotential electrician from a horizontal plane below the cross arm, fixing the insulating rope sleeve at the proper position in the middle of the cross arm, climbing the tower to the tail part of the cross arm along with a second electrician on the tower by the insulating rope sleeve, tying the 6-meter extension rope on an equipotential electrician safety belt buckle by the second electrician on the tower, and fixing the insulating rope sleeve at the proper position of the tail part of the cross arm by the equipotential electrician;

step D: the system comprises a transmission pulley block system, a ground electrician, a pulley block system and a herringbone ladder, wherein the ground electrician arranges a circulating rope system on a tower foot, the transmission rope is placed in a tower foot pulley after the electrician on the tower beats a transmission rope hanging point, a transmission rope hook is tied, the pulley block system and the herringbone ladder are transmitted to the electrician on the tower, a first electrician on the tower transmits the pulley block system to a second electrician on the tower from a cross arm lower plane, the second electrician on the tower is rapidly transmitted to an equipotential electrician, the equipotential electrician hooks the pulley block hook on an insulating rope sleeve after receiving the pulley block, and the herringbone ladder and a 6-meter extension rope are hooked on the pulley block;

step E: the equipotential electrician enters the equipotential, two ground electricians are matched with the equipotential electrician to enter the equipotential, the equipotential electrician sits on a Chinese character 'shi' ladder, a report work responsible person applies for entering the equipotential, the equipotential is quickly entered after the consent of the work responsible person, a lead is grabbed at a position 0.5 m away from the lead, the inner side of the lead is quickly drilled between sub-leads, and the Chinese character 'shi' ladder is hooked on the lead;

step F: eliminating the defect of the line, namely, routing the equipotential to the defect position on the lead to eliminate the defect;

step G: the equipotential electrician goes out the equipotential, the equipotential electrician sits in the T-shaped ladder, report work person in charge, under the cooperation of two ground electricians, the equipotential electrician waits that the loose hand withdraws from the equipotential after the assembly pulley atress, the equipotential arrives on the cross arm, untie assembly pulley, T-shaped ladder, 6 meters extension rope, give the assembly pulley second electrician on the tower by the plane transfer under the cross arm, second electrician on the tower gives first electrician on the tower rapidly, first electrician on the tower transfers the assembly pulley to the cross arm outside hanging point by the plane transfer under the cross arm, hook on the transmission rope couple. Meanwhile, a second electrician on the tower puts the stringing screw rod into a small hard canvas barrel and hangs the stringing screw rod on a transfer rope hook, the base is put into a common canvas barrel, and a ground electrician transfers the hard canvas barrel, the common canvas barrel, the ladder shaped like a Chinese character 'shi' and the transfer rope system to the ground;

step H: the device is arranged on the tower, the first electrician on the tower carries the transmission rope to go down the tower, the second electrician on the tower carries 2 extension ropes with the length of 6 meters and 1 extension rope with the length of 4 meters, the insulating rope sleeve is arranged on the tail of the first electrician to go down the tower, and the equipotential electrician carries the insulating rope sleeve to be arranged on the tail of the second electrician to go down the tower.

Preferably, in order to provide reasonable and accurate data for erecting a river network and ensure normal operation of the project, in the step a, according to field survey data, the construction of the floating bridge is based on data L of a distance from a river bank to a tower measured by an unmanned aerial vehicle, the width D of the floating bridge (3 meters without special circumstances) and the number of buoys used, the area S of the floating bridge is L × D, handrails should be arranged on two sides of the floating bridge, the height of the floating bridge is 1.2 meters, the area of the live working operation platform is calculated according to the area needed by the tower root opening and the working, the area S1+ S2, the area S1 is L1 × L1, the area S2 is L1 × L2, the tower root opening is L1, the actual working use length of the L2 is determined, and the number of the buoys is determined according to the area of the live working operation platform.

Preferably, in order to facilitate taking of the tools and increase the number of operators, the work efficiency is improved, in the step C, 3 electrician horizontal stations are arranged on the tower, and the portable tool bag is carried by the electrician.

Preferably, in order to ensure that the pulley system can provide a sufficient labor-saving effect, reduce the operation burden of electricians, and facilitate the erection of the wires, in the step D, the insulating transmission rope system climbs the tower to the end of the cross arm, the second electrician on the tower takes out the first electrician transmission rope system, hooks on the insulating rope sleeve, and the pulley block hook hooks on the insulating rope sleeve.

Preferably, in order to ensure that the minimum combined gap is 5.02 m, so that the combined gap meets the live-line operation conditions and the operation space of users is ensured, in the steps a and E, firstly, the combined gap is checked, the combined gap of the tower is the same as that of the tower on the land, the combined gap of the tower and the tower on the land are checked according to a conventional checking mode under the condition that the humidity of the tower and the tower on the land does not reach 80%, and the checking method is used for checking the tower 1 through AUTOCAD software: 1, drawing, namely simulating a hanging basket method or a Chinese character 'shi' ladder method for a tower window structure to meet the safety distance required by safety regulations.

The invention has the beneficial effects that: the operation method for live entrance and exit of the transmission line in the river network area to the equipotential is reasonable in design, in the step A, according to site survey data, the construction of the floating bridge is based on the distance data L from a river bank to a tower measured by an unmanned aerial vehicle, the width D (3 meters without special conditions) of the floating bridge, the using number of the floating pontoons is calculated, the area S of the floating bridge is L multiplied by D, handrails are arranged on two sides of the floating bridge, the height is 1.2 meters, the area of a live working operation platform is calculated according to the area needed by the root of the tower and during operation, S is S1+ S2, S1 is L1 multiplied by L1, S2 is L1 multiplied by L2, the root of the L1 tower and the actual use length of the L2 operation, the number of the floating pontoons is determined according to the area of the live working operation platform, reasonable and accurate data are conveniently provided for the erection of the river network, the normal operation of the project is ensured, in the step C, 3 electrician horizontal stations are arranged on the tower, and the equipotential carries portable tool bags, make things convenient for getting of instrument to take, thereby increase operating personnel's quantity and improve work efficiency, step D, insulating transmission rope system steps on the tower to the cross arm tip, second electrician takes out first electrician transmission rope system on the tower, hook on insulating fag end, and the assembly pulley couple hooks on insulating fag end, guarantee that this pulley system can provide sufficient laborsaving effect, reduce electrician's operation burden, and make things convenient for the erectting of wire, in step A and E, at first make up the clearance check, it is the same with "river net area" shaft tower combination clearance and land shaft tower combination clearance to communicate with the expert of the china department of electrical sciences, carry out according to conventional check mode under the condition that satisfies humidity and does not reach 80%, check method is through AUTOCAD software to shaft tower 1: drawing, simulating a hanging basket method or a Chinese character 'shi' ladder method for a tower window structure, meeting the safety distance required by safety regulations, ensuring that the minimum combined gap is 5.02 meters, ensuring that the combined gap meets the hot-line work condition and ensuring the operation space of users.

Drawings

FIG. 1 is a schematic view of the structure of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an operation method for live-line access of an electric transmission line in a river network area to an equipotential includes the following steps:

step A: checking the working site condition, checking tools and materials, surveying and detecting the tools on site, putting the tools on a damp-proof tarpaulin, neatly putting the tools, comprehensively checking the appearance without leakage, cleaning the surfaces of a hard insulating tool and a new insulator by using a dry and clean towel, measuring the current temperature and humidity and wind speed by a ground electrician, supervising the appearance checking and testing of the tools and materials by the ground electrician by a working responsible person, and checking the connection condition of the electrician and an equipotential worker wearing shielding clothes on a tower by the working responsible person;

and B: checking the double names, performing a safety tool test, checking the double names of lines and the tower numbers, performing the safety tool test and inspection before tower climbing by a tower climbing person, and recording by a work responsible person;

and C: arranging hanging points on a tower, tying a transmission rope system, enabling an electrician to carry 3 backup protection ropes of 6 meters, climbing an insulating rope sleeve to the end part of a cross arm, tying a 6-meter extension rope, tying two extension ropes of 6 meters to the proper position of the end part of the cross arm, transmitting the other ends of the 2 extension ropes to the equipotential electrician from a horizontal plane below the cross arm, fixing the insulating rope sleeve at the proper position in the middle of the cross arm, climbing the tower to the tail part of the cross arm along with a second electrician on the tower by the insulating rope sleeve, tying the 6-meter extension rope on an equipotential electrician safety belt buckle by the second electrician on the tower, and fixing the insulating rope sleeve at the proper position of the tail part of the cross arm by the equipotential electrician;

step D: the system comprises a transmission pulley block system, a ground electrician, a pulley block system and a herringbone ladder, wherein the ground electrician arranges a circulating rope system on a tower foot, the transmission rope is placed in a tower foot pulley after the electrician on the tower beats a transmission rope hanging point, a transmission rope hook is tied, the pulley block system and the herringbone ladder are transmitted to the electrician on the tower, a first electrician on the tower transmits the pulley block system to a second electrician on the tower from a cross arm lower plane, the second electrician on the tower is rapidly transmitted to an equipotential electrician, the equipotential electrician hooks the pulley block hook on an insulating rope sleeve after receiving the pulley block, and the herringbone ladder and a 6-meter extension rope are hooked on the pulley block;

step E: the equipotential electrician enters the equipotential, two ground electricians are matched with the equipotential electrician to enter the equipotential, the equipotential electrician sits on a Chinese character 'shi' ladder, a report work responsible person applies for entering the equipotential, the equipotential is quickly entered after the consent of the work responsible person, a lead is grabbed at a position 0.5 m away from the lead, the inner side of the lead is quickly drilled between sub-leads, and the Chinese character 'shi' ladder is hooked on the lead;

step F: eliminating the defect of the line, namely, routing the equipotential to the defect position on the lead to eliminate the defect;

step G: an equipotential electrician goes out of the equipotential, the equipotential electrician sits in the T-shaped ladder, reports a working responsible person, under the coordination of the two ground electricians, the equipotential electrician loosens the hands after the pulley blocks are stressed and then quits the equipotential, after the equipotential reaches the cross arm, the pulley blocks, the T-shaped ladder and the 6-meter extension rope are untied, the pulley blocks are transmitted to a second electrician on the tower from the lower plane of the cross arm, the second electrician on the tower rapidly transmits the pulley blocks to a first electrician on the tower, the first electrician on the tower transfers the pulley blocks to a hanging point outside the cross arm from the lower plane of the cross arm, hooks the pulley blocks on a transmission rope hook, meanwhile, the second electrician on the tower puts a stringing lead screw into a small hard canvas barrel and hangs the transmission rope hook, a base is put into a common canvas barrel, and the ground electrician transmits the hard canvas barrel, the common canvas barrel, the T-shaped ladder and the transmission rope system to the ground;

step H: the device is arranged on the tower, the first electrician on the tower carries the transmission rope to go down the tower, the second electrician on the tower carries 2 extension ropes with the length of 6 meters and 1 extension rope with the length of 4 meters, the insulating rope sleeve is arranged on the tail of the first electrician to go down the tower, and the equipotential electrician carries the insulating rope sleeve to be arranged on the tail of the second electrician to go down the tower.

In the step A, according to site survey data, the construction of a floating bridge calculates the number of buoys used according to distance data L from a river bank to a tower measured by an unmanned aerial vehicle, the width D of the floating bridge (3 meters without special condition), the area S of the floating bridge is L multiplied by D, handrails are arranged on two sides of the floating bridge, the height is 1.2 meters, the area of a live working operation platform is calculated according to the area needed by the root of the tower and the operation, S is S1+ S2, S1 is L1 multiplied by L1, S2 is L1 multiplied by L2, L1 is root of the tower, the actual using length of L2 is calculated, the number of the buoys is determined according to the area of the live working operation platform, reasonable and accurate data are conveniently provided for the erection of a river network, the normal operation of a project is ensured, in the step C, 3 electrician horizontal stations are arranged on the tower, and the portable tool bags are carried by the electrician, the tools are conveniently taken, and the number of operators is increased, so that the working efficiency is improved, in the step D, the insulating transmission rope system climbs the tower to the end of the cross arm, the second electrician on the tower takes out the first electrician transmission rope system, hooks the insulating rope sling and the pulley block hook on the insulating rope sling, so as to ensure that the pulley system can provide enough labor saving effect, reduce the operation burden of the electrician, and facilitate the erection of the lead, in the steps a and E, the combination gap is checked first, the combination gap of the tower and the tower in the "river network area" which is communicated with the experts of the chinese academy of electrical sciences is the same as the combination gap of the tower and the tower on the land, the combination gap of the tower and the tower on the land are checked according to a conventional checking mode under the condition that the humidity does not reach 80%, and the checking method is performed on the tower 1 through AUTOCAD software: drawing, simulating a hanging basket method or a Chinese character 'shi' ladder method for a tower window structure, meeting the safety distance required by safety regulations, ensuring that the minimum combined gap is 5.02 meters, ensuring that the combined gap meets the hot-line work condition and ensuring the operation space of users.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (1)

1. An operation method for live access of an electric transmission line in a river network area to an equipotential is characterized by comprising the following steps: the method comprises the following steps:

step A: checking the working site condition, checking tools and materials, surveying and detecting the tools on site, putting the tools on a damp-proof tarpaulin, neatly putting the tools, comprehensively checking the appearance without leakage, cleaning the surfaces of a hard insulating tool and a new insulator by using a dry and clean towel, measuring the current temperature and humidity and wind speed by a ground electrician, supervising the appearance checking and testing of the tools and materials by the ground electrician by a working responsible person, and checking the connection condition of the electrician and an equipotential worker wearing shielding clothes on a tower by the working responsible person;

and B: checking the double names, performing a safety tool test, checking the double names of lines and the tower numbers, performing the safety tool test and inspection before tower climbing by a tower climbing person, and recording by a work responsible person;

and C: arranging hanging points on a tower, tying a transmission rope system, enabling an electrician to carry 3 backup protection ropes of 6 meters, climbing an insulating rope sleeve to the end part of a cross arm, tying a 6-meter extension rope, tying two extension ropes of 6 meters to the proper position of the end part of the cross arm, transmitting the other ends of the 2 extension ropes to the equipotential electrician from a horizontal plane below the cross arm, fixing the insulating rope sleeve at the proper position in the middle of the cross arm, climbing the tower to the tail part of the cross arm along with a second electrician on the tower by the insulating rope sleeve, tying the 6-meter extension rope on an equipotential electrician safety belt buckle by the second electrician on the tower, and fixing the insulating rope sleeve at the proper position of the tail part of the cross arm by the equipotential electrician;

step D: the system comprises a transmission pulley block system, a ground electrician, a pulley block system and a herringbone ladder, wherein the ground electrician arranges a circulating rope system on a tower foot, the transmission rope is placed in a tower foot pulley after the electrician on the tower beats a transmission rope hanging point, a transmission rope hook is tied, the pulley block system and the herringbone ladder are transmitted to the electrician on the tower, a first electrician on the tower transmits the pulley block system to a second electrician on the tower from a cross arm lower plane, the second electrician on the tower is rapidly transmitted to an equipotential electrician, the equipotential electrician hooks the pulley block hook on an insulating rope sleeve after receiving the pulley block, and the herringbone ladder and a 6-meter extension rope are hooked on the pulley block;

step E: the equipotential electrician enters the equipotential, two ground electricians are matched with the equipotential electrician to enter the equipotential, the equipotential electrician sits on a Chinese character 'shi' ladder, a report work responsible person applies for entering the equipotential, the equipotential is quickly entered after the consent of the work responsible person, a lead is grabbed at a position 0.5 m away from the lead, the inner side of the lead is quickly drilled between sub-leads, and the Chinese character 'shi' ladder is hooked on the lead;

step F: eliminating the defect of the line, namely, routing the equipotential to the defect position on the lead to eliminate the defect;

step G: an equipotential electrician goes out of the equipotential, the equipotential electrician sits in the T-shaped ladder, reports a working responsible person, under the coordination of the two ground electricians, the equipotential electrician loosens the hands after the pulley blocks are stressed and then quits the equipotential, after the equipotential reaches the cross arm, the pulley blocks, the T-shaped ladder and the 6-meter extension rope are untied, the pulley blocks are transmitted to a second electrician on the tower from the lower plane of the cross arm, the second electrician on the tower rapidly transmits the pulley blocks to a first electrician on the tower, the first electrician on the tower transfers the pulley blocks to a hanging point outside the cross arm from the lower plane of the cross arm, hooks the pulley blocks on a transmission rope hook, meanwhile, the second electrician on the tower puts a stringing lead screw into a small hard canvas barrel and hangs the transmission rope hook, a base is put into a common canvas barrel, and the ground electrician transmits the hard canvas barrel, the common canvas barrel, the T-shaped ladder and the transmission rope system to the ground;

step H: arranging an upper tool and a lower tool of a tower, carrying a first electrician on the tower to lower the tower, carrying 2 extension ropes with the length of 6 meters and 1 extension rope with the length of 4 meters by a second electrician on the tower, carrying an insulation rope sleeve by the equipotential electrician to follow the first electrician to lower the tower, and following the upper tool of the second electrician to lower the tower;

in the step A, according to field survey data, building a floating bridge, according to distance data L from a river bank to a tower measured by an unmanned aerial vehicle, the width D of the floating bridge, calculating the number of used floating bowls, wherein the area S of the floating bridge is L multiplied by D, handrails are arranged on two sides of the floating bridge, the height of the floating bridge is 1.2 meters, the area of a live working operation platform is calculated according to the area needed by the root opening of the tower and the operation, S is S1+ S2, S1 is L1 multiplied by L1, S2 is L1 multiplied by L2, the root opening of the tower is L1, the actual service length of the operation is L2, and the number of the floating bowls is determined according to the area of the live working operation platform;

in the step C, 3 electrician horizontal stations are arranged on the tower, and the portable tool bag is carried by the electrician;

step D, the insulating transmission rope system ascends the tower to the end part of the cross arm, a second electrician on the tower takes out the first electrician transmission rope system and hooks the insulating rope sleeve, and the pulley block hook hooks the insulating rope sleeve;

in the steps A and E, firstly, the combination gap is checked, the tower combination gap is the same as the ground tower combination gap, the tower combination gap and the ground tower are checked according to a conventional checking mode under the condition that the humidity does not reach 80%, and the checking method is used for checking the tower 1 through AUTOCAD software: 1, drawing, namely simulating a hanging basket method or a Chinese character 'shi' ladder method for a tower window structure to meet the safety distance required by safety regulations.

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