RU2408104C1 - Pin-type insulator with monitoring of internal insulation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to linear pin-type high-voltage insulators intended for insulated fixation of wires to metal, reinforced concrete and wooden supports on overhead power transmission lines and pin-type support insulators of distribution devices of stations and substations for voltage of up to 35 kV AC of industrial frequency of 50 Hz. High-voltage insulator comprises metal end terminal for fixation to support cross beam, metal end terminal for fixation of wire and electric insulation part. Insulator differs by the fact that electric insulation part is made of evenly tempered glass with extent of tempering of more than 700 millimicron/cm, and is inseparably connected to end terminal. End terminal is arranged in the form of pipe for placement onto pin.

EFFECT: provides for easy detection of insulator internal insulation breakthrough.

3 cl, 3 dwg

Description

Technical field

The invention relates to the electric power industry, and in particular to linear pin high-voltage insulators designed for insulated fastening of wires to metal, reinforced concrete and wooden poles on overhead power lines, and to pin support insulators in switchgears of stations and substations for voltage up to 35 kV AC of industrial frequency 50 Hz.

State of the art

Known pin linear insulators made of high-voltage porcelain or glass, consisting of one insulating element for voltages up to 20 kV inclusive ("Line insulators" A.I. Tsimberov, "Energy", M. 1976, S. 6-8, Fig. 1 a-d). Known insulators are made in accordance with the general specifications according to GOST 1232-82. According to this standard, pin insulators made of insulating glass are annealed. All pin linear insulators are produced from annealed glass. The main disadvantage of such insulators is the impossibility of identifying them during breakdown of the insulator on the support of the power line when viewed from the ground.

High-voltage insulators are known, consisting of a metal cap firmly connected by means of a cement-sand bond to a tempered glass part, and a dielectric rod in rigid connection with the glass part (SU 1529296, Cl. H01B 17/20). The disadvantage of this insulator is the need to protect the dielectric polymer rod from weathering, tracking leakage currents, partial microdischarges in the polymer body, etc. This significantly increases the cost of the insulator design, and the polymer rod has a very small electric capacitance in comparison with the glass part, which leads to uneven distribution electrical loads inside the insulator. In addition, the thermal stability of such an insulator depends on the material and the difference in the coefficients of thermal expansion of the polymer and glass.

The closest analogue is the insulator according to the patent of Russian Federation 2113741, consisting of a metal cap, an insulating part made of tempered glass, and a metal pin rigidly fixed in the insulating part. The glass part is unevenly tempered. The power head of the insulator is hardened more than the skirts of the insulator.

A significant drawback of these insulators and analogue is the inability to identify the loss of insulating properties by the insulator. When the insulator breakdown according to the patent of the Russian Federation 2113741, the power head, hardened for mechanical strength to large values than skirts, is destroyed. But the skirts may not collapse and may remain on the insulator. Only internal cracks that are invisible at a great distance can occur in them. In this case, it is impossible to identify the breakdown of the internal insulation by the appearance of the insulator. This will make it difficult to quickly detect a broken insulator and energize the power line.

The use of tempered glass instead of annealed glass in traditional insulators is impossible due to the fact that when the tempered glass part is destroyed, the wire falls on the beam or the ground, burns out, leads to the ignition of the power transmission line support and poses a threat to life of people and animals on the ground. On traditional insulators, the wire is directly attached to the neck of the glass and porcelain insulator. Therefore, the insulator is made of annealed glass, which in case of breakdown does not collapse completely and holds the wire on the support, and the insulator itself is held on the pin of the power transverse beam also due to incomplete destruction. Almost in the insulator there is a microcrack or micro-hole in the place of breakdown, and the insulator itself retains mechanical strength. In the case of manufacturing it from tempered glass during the breakdown, explosive-like destruction and fall of the wire to the ground or the metal traverse of the support are inevitable.

Thus, on the one hand, it is necessary that the pin insulator during electrical breakdown collapses completely to quickly identify it, and, on the other hand, it must be mechanically strong to keep the wire from falling. This contradiction is resolved in the present invention.

The aim of the invention is to develop a reliable inexpensive insulator with the ability to easily detect breakdown of its internal insulation.

Description of the invention

This result is achieved due to the fact that the high-voltage insulator contains a metal terminal (pin, pipe) for attaching to the traverse, a metal terminal for attaching the wire and an electrical insulating part with a head and ring ribs. The insulator is characterized in that the insulating part is made of insulating glass having a uniform tempering of at least 1.5 pores / cm (more than 700 mmkm / cm) and is connected inseparably to the metal cap and flange so that after breaking the glass part the insulator remains mechanically durable. The use of a glass insulating part with uniform quenching of more than 700 mmkm / cm in the design of the insulator allows you to quickly identify a failed insulator. In the event of an internal breakdown during the occurrence of any microcrack, the uniformly tempered glass part is completely destroyed not only in the head, but the insulator skirts are also destroyed. Electrical breakdown of internal insulation is always associated with the flow of electric discharge current from one metal terminal to another. The electric discharge channel violates the integrity of the insulating part. A through hole from one terminal to another appears in it. Since the entire insulating glass part is in tension, a through hole leads the entire system to a loss of balance and explosive destruction of all parts completely. Thus, if the integrity of the glass part is violated, it crumbles into a large number of small fragments. Since hardening is carried out to a level of more than 700 mmkm / cm, the size of glass fragments does not exceed 1-2 cm. At the same time, the destroyed remnant of the insulator retains mechanical strength up to 70% of the initial strength due to uniform breaking into regular fragments that remain sandwiched between metal terminators. The design of the terminators is such that the loads in the insulator head during its operation are only compressive. After the destruction of the insulating part, all the numerous fragments already experience compressive loads. As a result, the wire attached to one of the terminators does not fall to the ground, but remains attached to the insulator. However, the absence of skirts at the insulator allows you to quickly find and replace it. As a result, repair work is significantly reduced, and the time for disconnecting consumers from electricity is reduced. The use of a uniformly tempered glass part with a degree of tempering more than 700 mmkm / cm increases its thermal stability. Conventional annealed glass insulators withstand short-term temperature differences of not more than 45 ° C. Tempered glass insulators with metal terminators have a thermal resistance of more than 80 ° C, and with an increase in the degree of tempering, the thermal resistance of the insulators increases. Thermal resistance for pin insulators is essential. Pin insulators are mainly used on power lines with voltage up to 20 kV without the use of lightning protection. When lightning strikes a power line, the pin insulator overlaps through the air, the lightning discharge from the wire to the crosshead passes through the air directly near the surface of the insulator. Heating can also occur as a result of uneven contamination of the insulator and leakage current flowing over its surface. At the same time, rapid heating of the insulator section can lead to destruction of the insulator and its failure. Destruction occurs mainly due to uneven heating of different parts of the insulator and uneven thermal expansion of the insulating part. An increase in thermal stability leads to more reliable operation of the insulator and the entire power line.

The shape of the electrical insulating part and the terminators must be such that, after destruction, the rest of the glass experiences compressive loads. For example, the glass part may be in the form of an inverse cone. The terminators mating with it are also made in the form of inverse cones. After connecting to each other, the air gap between the terminators and glass can be filled with a hardening mixture (cement-sand bond, for example). Filling the gap with the hardening mixture achieves the one-piece connection of the ends and the glass tempered part.

The glass part may have protrusions on the sides mating with the ends. After filling the air gap with the hardening mixture, one-piece connection of the terminators and the glass component takes place.

The shape of the terminals may also vary depending on the location and operating conditions of the insulator. In particular, when replacing old annealed glass insulators, it may be necessary to install the insulators on existing crosshead pins. In this case, the terminator of the insulator for mounting on the pin of the beam is made in the form of a hollow tube, which is mounted on this pin. To install the insulator on a flat surface, the insulator may have a terminal in the form of a plate with holes for bolting. This does not exhaust the diversity of terminal shapes. All that is significant for the invention is only the form interfaced with glass, which makes it possible to create an integral connection even when the glass insulating part is destroyed.

The implementation of the invention

A consignment of insulators was manufactured at the applicant enterprise. The insulating part was made of insulating glass with a low alkali content. After manufacturing, the glass parts were heat treated to relieve internal stresses and were tempered with a degree of more than 900 mmkm / cm (900 nm / cm). The insulating part had a head in the form of an inverse cone. The upper terminal was also a reverse cone made of aluminum. A thickened steel pin was inserted inside the glass part. All parts were connected using a cement-sand bond with a final strength of cement stone of at least 50 MPa.

Types of tests that the proposed insulators passed

1. Heat resistance tests: the number of cycles of different heating and cooling is 3, the holding time for heating and cooling is 15 minutes, the temperature difference between hot and cold water is 90 ° C, and the test time under the influence of a continuous stream of sparks is 1 minute. The thermal resistance of the insulator is higher than all known glass insulators.

2. Test destructive mechanical force in bending: normalized mechanical destructive force of 18-19 kN, while the bent pin was bent.

3. Breakdown test: normalized value of the specific volumetric electrical resistance of the insulating medium (1-5) · 10 ⁷ Ohm / m, the actual value of the breakdown voltage is 170-200 kV (insulators did not break through). When a voltage of more than 250 kV was applied, the insulator was broken and the glass part was completely destroyed to identify the failure of the insulator. At the same time, the same insulators made using annealed glass parts gave lower values - at the level of 12-150 kV.

4. Withstand voltage test with a frequency of 50 Hz in the dry state and in the rain

- withstand voltage of 50 Hz in a dry state - 76 kV;

- withstand voltage of 50 Hz in the rain - 52-55 kV;

atmospheric conditions during the test: P = 1.014 · 105 Pa, t = 20.2 C;

Contamination = 9.5 g / m ² .

The insulators also withstood pulsed voltage tests with a steep wave front.

5. After mechanical destruction of the glass part, the remainder of the insulator withstood a bend of 18 kN, while, as in the tests of whole insulators, the metal pin of the traverse was bent, and no visible changes were found in the insulator.

According to the test results, it was concluded that it is advisable to use these insulators on power lines, taking into account their increased heat resistance, increased electrical strength and the possibility of quick identification of failure.

The design of the insulator is illustrated by drawings.

In all the drawings, the following notation:

1 - terminal for fastening the wire

2 - head of an insulating tempered glass part

3 - skirt of insulating tempered glass parts

4 - pin or terminal for attaching to the traverse

The wire in all the drawings is conventionally not shown. The wire is fixed in any traditional way.

Figure 1 is a view of a pin linear insulator containing an electrical insulating body 2 with a skirt 3, a terminal for attaching a wire 1 and a terminal for attaching to a traverse 4, made in the form of a metal pin.

Figure 2 is a view of a pin linear insulator containing an electrical insulating body 2 with a skirt 3, a terminal for attaching a wire 1 and a terminal for attaching to a traverse 4, made in the form of a metal tube for a snug fit on the traverse pin.

Figure 3 is a view of a pin support insulator containing an electrical insulating body 2 with a skirt 3, a terminal for attaching a wire 1 and a terminal for attaching to a stand 4.

Claims (3)

1. A pin insulator comprising a terminal for attaching a wire, a terminal for attaching to a traverse, an electrical insulating part comprising a head and a skirt, characterized in that the electrical insulating part is made of uniformly tempered glass with a degree of tempering of more than 700 mmkm / cm and is permanently connected to the terminators, due to the uniformity of hardening of the head and the skirt during electrical breakdown of the head, the insulator skirt also breaks into small fragments, indicating an internal breakdown. 2. The insulator according to claim 1, characterized in that the insulating part and the terminators have protrusions on the mating surfaces for inseparable connection between them when filling the gap between them with a hardening mass. 3. The insulator according to claim 1, characterized in that the terminal for attaching to the traverse is made in the form of a pipe for putting on the traverse pin.

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