阅读说明：本技术 一种串接式压缩灭弧绝缘子 (Series connection type compression arc extinguishing insulator ) 是由 李籽剑 王巨丰 王锟 张清河 徐宇恒 彭斐 黄萍 王嬿蕾 李继强 王国锋 于 2019-10-16 设计创作，主要内容包括：本发明公开了一种串接式压缩灭弧绝缘子,属于输配电架空线路防雷技术领域,包括若干个绝缘子和连接杆,若干个绝缘子通过连接杆串接构成绝缘子串,绝缘子串两端均设置有压缩灭弧装置,压缩灭弧装置包括导弧电极、导线和端位绝缘子,所述导弧电极设置在外部的连接件上,且通过导线连接到端位绝缘子上。本发明绝缘子灭弧时间提前,由传统的贯穿闪络绝缘配合提前到局部闪络绝缘配合,局部闪络后绝大多数绝缘没有击穿,仅仅出现沿面放电,此时灭弧对象只是极弱冲击电弧的流注,脆弱性高、灭弧难度低。(The invention discloses a series connection type compression arc extinguishing insulator, which belongs to the technical field of lightning protection of power transmission and distribution overhead lines and comprises a plurality of insulators and connecting rods, wherein the insulators are connected in series through the connecting rods to form an insulator string, compression arc extinguishing devices are arranged at two ends of the insulator string, each compression arc extinguishing device comprises an arc guide electrode, a lead and an end insulator, and the arc guide electrodes are arranged on external connecting pieces and are connected to the end insulators through the leads. The insulator has the advantages that the arc extinguishing time is advanced, the traditional flashover penetrating insulation fit is advanced to the local flashover insulation fit, most of insulation is not broken down after the local flashover, only surface discharge occurs, at the moment, an arc extinguishing object is just the flow of an extremely weak impact arc, the brittleness is high, and the arc extinguishing difficulty is low.)

1. The utility model provides a tandem type compression arc extinguishing insulator, includes a plurality of insulator (2) and connecting rod (1), and a plurality of insulator (2) concatenates through connecting rod (1) and constitutes insulator chain, its characterized in that, insulator chain both ends all are provided with compression arc control device, and compression arc control device is including leading arc electrode (3), wire (4) and end position insulator (5), lead arc electrode (3) and set up on the connecting piece of outside, and be connected to on end position insulator (5) through wire (4).

2. The tandem compression arc-extinguishing insulator according to claim 1, wherein: a plurality of arc extinguishing channels (6) are arranged in the end insulator (5), the arc extinguishing channels (6) comprise a plurality of accelerating arc extinguishing channels (9) and a plurality of recoil arc extinguishing channels (10), the accelerating arc extinguishing channels (9) and the recoil arc extinguishing channels (10) are arranged alternately, and connecting wires (11) are arranged for electrical connection.

3. A tandem compression arc extinguishing insulator according to claim 2, characterised in that: the accelerating arc extinguishing channel (9) and the recoil arc extinguishing channel (10) are both arranged to be sealed at one end, the opening at the other end is arranged, the middle part is provided with a lightning receiving piece (12), the opening end of the accelerating arc extinguishing channel (9) is arranged to be an accelerating nozzle (8), and the opening end of the recoil arc extinguishing channel (10) is arranged to be a recoil nozzle (7).

4. A tandem compression arc extinguishing insulator according to claim 3, wherein: with higher speed arc extinguishing passageway (9) including compression conduction section (9.1) and acceleration blowout section (9.2), compression conduction section (9.1) and acceleration blowout section (9.2) an organic whole set up, meet sudden strain of a muscle piece (12) and set up at compression conduction section (9.1) and acceleration blowout section (9.2) junction, compression conduction section (9.1) both ends seal up and set up, accelerate blowout section (9.2) one end opening, the other end seal up.

5. The tandem compression arc-extinguishing insulator according to claim 4, wherein: the recoil arc extinguishing channel (10) comprises a recoil section (10.1) and an extrusion conduction section (10.2), the lightning receiving piece (12) is arranged at the joint of the recoil section (10.1) and the extrusion conduction section (10.2), the two ends of the extrusion conduction section (10.2) are arranged in a sealing mode, one end of the recoil section (10.1) is arranged in a sealing mode, and the other end of the recoil section is opened.

6. A tandem compression arc extinguishing insulator according to claim 3, wherein: the sealing ends of the accelerating arc extinguishing channel (9) and the recoil arc extinguishing channel (10) are provided with arc striking electrodes (13), the arc striking electrodes (13) are arranged to be metal rings, and the outer side walls of the metal rings are tightly attached to the inner side walls of the accelerating arc extinguishing channel (9) and the recoil arc extinguishing channel (10).

7. The tandem compression arc-extinguishing insulator according to claim 5, wherein: wire (4) are connected with one of them striking electrode (10) of accelerating arc extinguishing passageway (9), set up to the electric arc entry, and accelerate arc extinguishing passageway (9) and recoil arc extinguishing passageway (10) nonparallel setting, and the recoil spout (7) of accelerating spout (8) and recoil arc extinguishing passageway (10) of accelerating arc extinguishing passageway (9) are connected through connecting wire (8), and extrusion conduction section (10.2) are connected conduction electric arc through connecting wire (8) with compression conduction section (9.1).

8. The tandem compression arc-extinguishing insulator according to claim 7, wherein: the side walls of the accelerated arc extinguishing channel (9) and the recoil arc extinguishing channel (10) are made of high-strength, high-temperature-resistant and high-pressure-resistant non-conductive materials, the non-conductive materials are made of alloy ceramics, rare earth ceramics, graphene-ceramic composite materials, organic ceramics, synthetic silicon rubber, organic insulating materials, alloy glass, rare earth glass, graphene glass or organic glass, and the inner diameters of the accelerated arc extinguishing channel (9) and the recoil arc extinguishing channel (10) are increased along with the increase of the voltage grade of the power transmission line.

9. The tandem compression arc-extinguishing insulator of claim 8, wherein: the diameter ratio of end position insulator (5) is big than the diameter of insulator (2), accelerates spout (8) and recoil spout (7) and sets up in the upper end of end position insulator (5), accelerates arc extinguishing passageway (9) and recoil arc extinguishing passageway (10) and all inlays the inside of establishing in end position insulator (5).

10. A tandem compression arc extinguishing insulator according to claim 9, characterised in that: the arc guiding electrode (3) is of a metal lantern ring structure and is sleeved on the external metal connecting piece.

Technical Field

The invention relates to the technical field of lightning protection of power transmission and distribution overhead lines, in particular to a series connection type compression arc-extinguishing insulator.

Background

When the clouds aggregate to form a difference between the clouds and earth, a very non-uniform electric field is always induced at the insulator. Research shows that the distribution of the electric field intensity among different pieces of insulators is also very uneven when lightning strike occurs, and the electric field intensity of the insulator pieces at two ends of the insulator string is high, and the electric field intensity of the middle part of the insulator string is low. Because the electric field intensity of the insulators at the first end and the last end is high, the electric field intensity of the middle part of the insulator is low, lightning flashover arcs firstly appear at the two ends of the insulator string, and then the lightning flashover arcs develop from the two ends of the insulator string to the middle part.

The lightning arrester and the parallel gap widely adopted in the power line nowadays mainly intervene when lightning stroke occurs, and the traditional lightning arrester has many defects, such as: difficult maintenance, low lightning protection effect, incapability of protecting superposed lightning stroke and the like. The parallel gap also has a number of disadvantages, such as: (1) the parallel gap installation needs additional hardware fittings, and the installation has certain difficulty; (2) the insulation matching of the parallel gap is designed according to the highest breakdown voltage of the head and tail insulators of the insulator string, and partial discharge firstly occurs at the head end and the tail end, so that the insulation matching ratio of the parallel gap needs to be low, the insulation level of a line can be reduced, and the lightning trip-out rate is increased; (3) the parallel gap electrode is burnt by power frequency follow current electric arc for many times, which can lead to the ablation of the metal electrode and reduce the insulation matching capability of the parallel gap and the insulator.

Aiming at the defects of the lightning arrester and the parallel gap, the serial compression arc-extinguishing insulator applied to the lightning protection of the power transmission line is provided.

Disclosure of Invention

The invention aims to provide a series connection type compression arc-extinguishing insulator to solve the technical problems in the background technology.

The utility model provides a tandem type compression arc extinguishing insulator, includes a plurality of insulator and connecting rod, and a plurality of insulator concatenates through the connecting rod and constitutes insulator chain, and the insulator chain both ends all are provided with compression arc control device, and compression arc control device is including leading arc electrode, wire and end position insulator, lead the arc electrode setting on the connecting piece of outside, and be connected to on the end position insulator through the wire.

Further, be provided with a plurality of arc extinguishing passageway in the end position insulator, the arc extinguishing passageway includes a plurality of arc extinguishing passageway and a plurality of recoil arc extinguishing passageway with higher speed, and arc extinguishing passageway and recoil arc extinguishing passageway alternate setting with higher speed to set up the connecting wire and realize electrical connection.

Further, arc extinguishing channel and recoil arc extinguishing channel all set up to one end sealed with higher speed, and the other end opening sets up, and the centre is provided with the lightning-arrest piece, and the open end of arc extinguishing channel sets up to spout with higher speed, and the open end of recoil arc extinguishing channel sets up to the recoil spout.

Furtherly, including compression conduction section and acceleration blowout section with higher speed arc extinguishing channel, compression conduction section and the integrative setting of acceleration blowout section, meet and dodge the piece setting at compression conduction section and acceleration blowout section junction, compression conduction section both ends seal up and set up, and blowout section one end opening is sealed with higher speed to the other end.

Furthermore, the recoil arc extinguishing channel comprises a recoil section and an extrusion transmission section, the lightning receiving piece is provided with a joint of the recoil section and the extrusion transmission section, two ends of the extrusion transmission section are hermetically arranged, one end of the recoil section is hermetically arranged, and the other end of the recoil section is opened.

Furthermore, arc striking electrodes are arranged at the sealing ends of the accelerated arc extinguishing channel and the recoil arc extinguishing channel, the arc striking electrodes are metal rings, and the outer side walls of the metal rings are tightly attached to the inner side walls of the accelerated arc extinguishing channel and the recoil arc extinguishing channel.

Furthermore, the wire is connected with an arc striking electrode of one of the accelerating arc extinguishing channels, the wire is arranged as an arc inlet, the accelerating arc extinguishing channels and the recoil arc extinguishing channels are not parallel, accelerating nozzles of the accelerating arc extinguishing channels are connected with recoil nozzles of the recoil arc extinguishing channels through connecting wires, and the extrusion conduction section and the compression conduction section are connected with conduction arcs through the connecting wires.

Furthermore, the side walls of the accelerated arc extinguishing channel and the backflushing arc extinguishing channel are made of high-strength, high-temperature-resistant and high-pressure-resistant non-conductive materials, the non-conductive materials are made of alloy ceramics, rare earth ceramics, graphene-ceramic composite materials, organic ceramics, synthetic silicone rubber, organic insulating materials, alloy glass, rare earth glass, graphene glass or organic glass, and the inner diameters of the accelerated arc extinguishing channel and the backflushing arc extinguishing channel are increased along with the increase of the voltage grade of the power transmission line.

Furthermore, the diameter of the end insulator is larger than that of the insulator, the accelerating nozzle and the backflushing nozzle are arranged at the upper end of the end insulator, and the accelerating arc extinguishing channel and the backflushing arc extinguishing channel are embedded inside the end insulator.

Further, the arc conducting electrode is of a metal lantern ring structure and is sleeved on the external metal connecting piece.

The first and last two insulators of insulator chain's local field intensity is high, and easy preferred flashover, so at the great insulator of first and last both ends design two areas of insulator chain, install the arc extinguishing module in first and last two insulators for protect the first and last both ends of insulator chain. At the leading stage of thunder and lightning discharge, to inhomogeneous electric field partial discharge characteristic part, two great insulators of area are designed at the first and last both ends of insulator string, install the arc extinguishing module in first and last two insulators, it is insulating to run through the flashover insulation cooperation of tradition in advance to the partial flashover, the realization is effectively extinguished to the partial discharge electric arc, thereby eliminate to develop into the basic condition of main discharge from partial discharge, greatly reduce the arc extinguishing degree of difficulty, eliminate the thunderbolt flashover and build the arc harm, ensure that the thunderbolt does not trip.

And arc striking electrodes are respectively arranged at the head end and the tail end of the insulator string, are respectively sleeved at the head end and the tail end of the insulator string and are in contact with the metal outer walls at the head end and the tail end of the insulator. The arc striking electrodes are made of metal materials and are respectively connected with the arc extinguishing modules in the insulators at the first end and the second end through leads to extinguish arcs with local flashover, so that flashover penetration is prevented. Function of the arc striking electrode: when lightning flashover arcs occur near the insulator, the arc striking electrodes can pull the nearby arcs into the arc extinguishing modules of the insulator pieces at two ends. The arc extinguishing module is arranged inside the insulator pieces at the two ends and consists of arc extinguishing channel paths with a multi-section Z-shaped sawtooth structure. An arc extinguishing tube is arranged in each arc extinguishing channel path, the arc extinguishing tube can be designed to be of a compression structure, and the arc extinguishing tube material is a high-strength insulating material, such as a ceramic tube. The arc tubes in different arc passage paths are connected by arc guiding lines to make the arc change in the appointed arc passage. And the outer surface of the insulator sheet at the head end and the tail end is provided with an electric arc nozzle, and the outer nozzle is communicated with the inner electric arc channel.

Further, the compression pipe is of a hollow structure with two open ends, and a metal arc guide piece is arranged in the middle of the compression pipe for plugging to form two semi-closed spaces.

The basic principle of the invention is as follows:

the compression principle is as follows: the impact electric arc enters the compression arc-extinguishing tube, is strongly compressed and bent by the compression arc-extinguishing tube, generates extremely high axial pressure gradient in the arc-extinguishing tube, is sprayed out to the outside from the compression arc-extinguishing tube, blows and draws the inflection point of the electric arc, and stretches and refines the electric arc once more, so that the electric arc is blown out more easily and is not re-combusted.

By adopting the technical scheme, the invention has the following technical effects:

(1) the insulator has the advantages that the arc extinguishing time is advanced, the traditional flashover penetrating insulation fit is advanced to the local flashover insulation fit, most of insulation is not broken down after the local flashover, only surface discharge occurs, at the moment, an arc extinguishing object is just the flow of an extremely weak impact arc, the brittleness is high, and the arc extinguishing difficulty is low.

(2) Arc extinction is easier, an arc building channel belongs to a non-through channel, and damping is huge.

(3) The re-ignition is more difficult, the medium recovery is faster once the weak arcing is interrupted, the arc path vulnerability is greater, and the deionization area is larger.

(4) The arc extinguishing module has the advantage of safety, and flashover caused by power frequency overvoltage is also extinguished in the partial discharge stage. The arc extinguishing module can be prevented from being damaged by large energy, the range of the arc extinguishing module for suppressing overvoltage and the durability of the arc extinguishing module are improved, and the requirement of the arc extinguishing capability of pure power frequency overvoltage is completely met.

(5) The arc extinguishing module and the insulator string are integrated, so that the installation is simple and the economical efficiency is high.

Drawings

Fig. 1 is a schematic view of the structure of the insulator of the present invention.

Fig. 2 is a schematic view of the end insulator structure of the present invention.

Fig. 3 is a cross-sectional view of an end insulator of the present invention.

Fig. 4 is a schematic view of the internal recoil structure of the end insulator of the present invention.

Fig. 5 is a schematic view of an arc extinguishing channel structure according to the present invention.

Fig. 6 is a schematic view of the internal connection of the end insulator of the present invention.

Fig. 7 is a schematic diagram of a compressed arc chute of the present invention.

FIG. 8 is a graph showing the distribution of the induced electric field intensity of the insulator string according to the present invention.

In the figure: 1-a connecting rod; 2-an insulator; 3-leading arc electrode; 4-a wire; 5-end insulator; 6-arc extinguishing channel; 7-backflushing nozzles; 8-accelerating nozzle; 9-accelerating arc extinguishing channel; 9.1-compressing the conductive segments; 9.2-accelerated ejection section; 10-recoil arc extinguishing channel; 10.1-back flushing section; 10.2-extruding the conductive section; 11-connecting lines; 12-a lightning receptor; 13-arc ignition electrode.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail below with reference to the accompanying drawings by way of examples of preferred embodiments. It should be noted, however, that the numerous details set forth in the description are merely for the purpose of providing the reader with a thorough understanding of one or more aspects of the present invention, which may be practiced without these specific details.

An embodiment of the invention is further described in accordance with the above-described principle description and with reference to fig. 1:

as shown in fig. 8, the first and last two insulators of the insulator string, that is, the end insulator 5, as the 1 st and 7 th insulators in fig. 1, have high local field strength and are easy to preferentially flashover, so that two insulators with large areas are designed at the first and last ends of the insulator string, and the first and last two insulators are provided with the compression arc-extinguishing devices for protecting the first and last ends of the insulator string. The compression arc-extinguishing device can be formed by internally reserving a space in the manufacture of the terminal insulator 5 or by post-drilling. At the leading stage of thunder and lightning discharge, to inhomogeneous electric field partial discharge characteristic part, two great insulators of area (the 1 st, the 7 th) are designed at the first and last both ends of insulator string, install compression arc control device in two first and last insulators, it is insulating to run through flashover insulation cooperation to the partial flashover in advance with traditional, the realization is effectively extinguished to the partial discharge electric arc, thereby eliminate to develop into main discharge's basic condition from partial discharge, greatly reduce the arc extinguishing degree of difficulty, eliminate thunderbolt flashover and build the arc harm, ensure that the thunderbolt does not trip.

Firstly, after lightning strike, lightning is transmitted to the arc-conducting electrode 3 through an external metal connecting piece, and the arc is transmitted to the end insulator 5 by the arc-conducting electrode 3 through the lead 4 for recoil arc extinction.

As shown in fig. 1, arc-guiding electrodes 3 are respectively arranged at the head end and the tail end of the insulator string, and the arc-guiding electrodes 3 are respectively sleeved at the head end and the tail end of the insulator string and are in contact with the metal outer wall at the head end and the tail end of the insulator. The arc-guiding electrode 3 is made of metal materials and is respectively connected with the compression arc-extinguishing devices in the insulators at the head end and the tail end through a lead 4. Function of the arc-guiding electrode 3: when lightning flashover arcs occur near the insulator, the arc guide electrode 3 can pull the nearby arcs into the compression arc extinguishing devices of the insulator pieces at two ends.

The diameter of the end insulator 5 is larger than the diameter of the other insulator in the middle, and the two ends are covered by the diameters of the two ends, so that the arc extinguishing effect of the two ends can be realized.

As shown in fig. 2 to 6, a plurality of arc extinguishing channels 6 are provided in the end insulator 5, each arc extinguishing channel 6 includes a plurality of accelerating arc extinguishing channels 9 and a plurality of recoil arc extinguishing channels 10, the accelerating arc extinguishing channels 9 and the recoil arc extinguishing channels 10 are alternately disposed, and connecting lines 11 are provided to connect each other. The arc extinguishing channel 9 conducts the electric arc with higher speed, then through one end accelerating section for the electric arc is toward spouting outward with higher speed, passes to next recoil arc extinguishing channel 10 through connecting wire 8 simultaneously, and recoil arc extinguishing channel 10 is through the recoil, makes to carry out the recoil to electric arc and cuts, better arc extinguishing.

The accelerating arc extinguishing channel 9 and the recoil arc extinguishing channel 10 are both arranged to be sealed at one end, the opening at the other end is arranged, the middle part is provided with a lightning receptor 12, the opening end of the accelerating arc extinguishing channel 9 is arranged to be an accelerating nozzle 8, and the opening end of the recoil arc extinguishing channel 10 is arranged to be a recoil nozzle 7. Accelerating the arc extinguishing passageway 9 and including compression conduction section 9.1 and accelerating the blowout section 9.2, compression conduction section 9.1 and accelerating the blowout section 9.2 an organic whole setting, meet dodging the piece 12 setting at compression conduction section 9.1 and accelerating the blowout section 9.2 junction, compression conduction section 9.1 both ends seal up and set up, accelerate blowout section 9.2 one end opening, the other end seal up and set up. The recoil arc extinguishing channel 10 comprises a recoil section 10.1 and an extrusion conduction section 10.2, the lightning receptor 12 is arranged at the joint of the recoil section 10.1 and the extrusion conduction section 10.2, two ends of the extrusion conduction section 10.2 are hermetically arranged, one end of the recoil section 10.1 is hermetically arranged, and the other end of the recoil section is open. The sealing ends of the accelerated arc extinguishing channel 9 and the recoil arc extinguishing channel 10 are both provided with arc striking electrodes 13, the arc striking electrodes 13 are metal rings, and the outer side walls of the metal rings are tightly attached to the inner side walls of the accelerated arc extinguishing channel 9 and the recoil arc extinguishing channel 10. The wire 4 is connected with an arc striking electrode 10 of one of the accelerating arc extinguishing channels 9 and is arranged as an arc inlet, the accelerating arc extinguishing channels 9 and the recoil arc extinguishing channels 10 are not parallel, the accelerating nozzle 8 of the accelerating arc extinguishing channels 9 is connected with the recoil nozzle 7 of the recoil arc extinguishing channels 10 through a connecting wire 8, and the extrusion conduction section 10.2 and the compression conduction section 9.1 are connected with conduction arcs through the connecting wire 8.

As shown in fig. 6, the lightning impulse arc sequentially passes through the arc striking electrode at the head end and the tail end of the insulator string and the conducting wire to enter the arc channel in the insulator sheets at the head end and the tail end, the arc enters the first section of the compression arc extinguishing tube to perform compression arc extinguishing action on the impulse arc, and the arc is sprayed out from the nozzle a. The rest of the unquenched electric arc enters the second and third sections of the compression arc extinguishing tubes under the action of the arc guiding line 6, the compression arc extinguishing action is carried out on the electric arc, and the electric arc is sprayed out from the nozzle B. The process is then the same until the arc is extinguished.

As shown in FIG. 7, the outer arc may be defined as having a velocity v0 at the inlet, a pressure p0, a density ρ 0, and a temperature T0. After the outer arc enters the recoil assembly, an inlet arc velocity v1, a pressure p1, a density ρ 1 and a temperature T1 are formed. After passing through the arc striking assembly, the outlet arc speed v2 is p2, the pressure is p2, and the temperature is T2. The outer arc enters the recoil assembly through the inlet to form an inner arc, the inner arc is limited by the recoil assembly wall, the diameter is mechanically compressed by a large scale, and the temperature, the density, the pressure and the speed of the inner arc are all increased. Regardless of arc energy loss and friction effects, when the inlet arc passes the compression electrode to achieve a resilient impact moment, v1 is considered to be-v 2, i.e., the inlet arc velocity is equal in magnitude and opposite in direction to the outlet velocity. Considering the energy loss and friction of the arc, when the inlet arc collides with the compressive electrode, it is considered that | v2 | v1 | that the outlet velocity is smaller than the inlet velocity and the direction is opposite. The outlet arc is impeded by the inlet arc, which is smaller in diameter than the inlet arc, so that the outlet arc has a greater density, temperature and pressure than the inlet arc, i.e. ρ 2 > ρ 1, T2 > T1, p2 > p1, which in combination accelerate v2 more than v1, i.e. a2 > a 1. As the outlet arc diameter is increasingly compressed, resulting in an increase in outlet arc density, temperature and pressure, v2 > v1 eventually causes the outlet arc to rush out of the recoil assembly from the inlet. After the electric arc at the outlet rushes out of the recoil component, a cavity effect is formed on the external electric arc, the continuity of the electric arc is damaged, the energy of the electric arc is weakened, and the cutting and extinguishing of the electric arc are accelerated.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics 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.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that those skilled in the art can make various improvements and modifications without departing from the principle of the present invention, and these improvements and modifications should also be construed as the protection scope of the present invention.