EA027535B1 - String of discharger insulators - Google Patents

Abstract

The invention discloses a string of discharger insulators comprising insulation bodies made of a dielectric, connecting accessories linked mechanically to insulation bodies, each discharge insulator including two main electrodes linked mechanically to insulation bodies, and two or more intermediate electrodes linked mechanically to insulation bodies and allowing generation of discharges between adjacent main and intermediate electrodes and between adjacent intermediate electrodes. Two or more discharger insulators are joined to each other by means of one or more insulators having insulation parts and connecting accessories linked mechanically to insulation parts. The insulators may have no additional electrodes, or each insulator may have not more than one electrode extending along the edge of the insulating part and linked mechanically to a connecting accessory or the insulating part and, e.g., protruding beyond the outline of the insulating part in the plane perpendicular to the direction formed by connecting accessories of the joined discharger insulators. The technical result of the invention is prevention of joining of discharges generated by adjacent discharger insulators.

Description

The present invention relates to insulators of power lines and electrical equipment, in particular to insulators with lightning protection elements and garlands of such insulators.

State of the art

From KI2346368 patent a spark gap arrester is known for lightning protection elements of an electric equipment or power line, comprising an insulating body made of a solid dielectric, two main electrodes mechanically connected to the insulating body, and two or more electrodes located between the main electrodes with a mutual offset of at least along the longitudinal axis of the insulating body and configured to form a streamer discharge between adjacent main and intermediate electrodes.

Due to the formation of multiple discharge gaps by means of intermediate electrodes between the main electrodes, this arrester has a high arcing ability. At the same time, for use on power lines with high operating voltages (35, 110 kV), such insulator dischargers need to be combined in garlands. At the same time, insulator dischargers are located close enough to each other so that spark discharges of neighboring insulator dischargers, depending on weather conditions and the magnitude of lightning overvoltage, can be combined, thereby reducing the efficiency of insulator dischargers and jeopardizing electrical equipment and power lines.

In addition, in order that discharges between the main electrodes occur between the main electrodes, the insulator-dischargers must be oriented so that the main electrodes are preferably under each other. For this, it is necessary to correctly orient them when installing insulator-dischargers in the garlands, which complicates the work of installers and, if their work is erroneous, can lead to the fact that the garland of insulator-dischargers cannot perform the functions of lightning protection.

SUMMARY OF THE INVENTION

The objective of the invention is to eliminate the disadvantages of the prior art, in particular the elimination of the possibility of combining the discharges of adjacent insulator dischargers when installing them in a garland.

This problem is solved using a garland of insulator dischargers containing insulating bodies made of a dielectric, connecting fittings mechanically connected to insulating bodies, two main electrodes mechanically connected to insulating bodies, and two or more intermediate electrodes mechanically associated with insulating bodies and installed with the possibility of forming between adjacent main and intermediate electrodes, as well as between adjacent intermediate electrodes of discharges. To eliminate the possibility of combining the discharges of adjacent insulator arresters, adjacent insulator dischargers are interconnected by one or more insulators having insulating parts and connecting fittings mechanically connected to the insulating parts. These insulators do not have or each insulator has an electrode extended along the edge of the insulating part, mechanically connected to the connecting fittings or insulating part. An extended electrode can be installed with the protrusion beyond the contour of the insulating part in a plane perpendicular to the direction formed by the fittings of the connected insulator-arresters. In one embodiment, no more than one such electrode extended along the edge of the insulating part of the electrode is installed on each insulator.

The intermediate electrodes of the insulator-discharger can be located inside the insulating body and separated from its surface by a dielectric layer, while discharge chambers extending to the surface of the insulating body can be made between adjacent electrodes.

An electrode extended along the edge of the insulating part can be mechanically fixed to / in the insulating part. In addition, the electrode extended along the edge of the insulating part may have a length along the edge of the insulating part of not less than 0.4, 0.45 or 0.5 of the length of the contour of the insulating part in a plane perpendicular to the direction formed by the fittings of the connected discharge insulators. In a preferred embodiment, an electrode extended along the edge of the insulating part bends around the contour of the insulating part in a plane perpendicular to the direction formed by the fittings of the connected insulator-arresters, along the entire length of the specified circuit.

The present invention also solves the power line containing supports, at least one wire under high voltage and a string of insulator-dischargers in accordance with any of the above options, mechanically mounted on a support and connected directly or through fixing devices with a wire.

The technical result of the present invention is to eliminate the possibility of combining the discharges of adjacent insulator dischargers when they are installed in a daisy chain due to their separation by an intermediate insulator that does not have discharge gaps (that is, discharges cannot form in it). An additional technical result is a decrease in the complexity and volume of work of installers while ensuring the lightning protection properties of a garland of arresters. In addition, installation is further facilitated and operation is simplified due to the lack of need

- 1 027535 to fix the position of the insulators in the garland (since the electrode on the insulator is extended, it is not necessary to turn the insulator-dischargers in a position opposite each other and it is not necessary to prevent further rotation of the insulator-dischargers relative to each other). In addition, other additional technical results are reduced production costs, simplified production and increased efficiency of lightning protection.

List of figures, drawings

In FIG. 1 shows a garland of insulator dischargers in accordance with the invention for a 35 kV power line.

In FIG. 2 shows a garland of insulator arresters in accordance with the invention for a 110 kV power line.

In FIG. 3 shows another embodiment of a string of insulator arresters in accordance with the invention for a 110 kV transmission line.

Information confirming the possibility of carrying out the invention

In FIG. 1 shows a string of insulator arresters in accordance with the invention for a 35 kV power line. The garland consists of two insulator dischargers 1 and 2 (upper and lower), containing insulating bodies 4 made of a dielectric, connecting fittings mechanically connected with insulating bodies, two main electrodes 5 and 6 (upper and lower), mechanically connected with insulating bodies, and two or more intermediate electrodes mechanically connected with insulating bodies 4 and installed with the possibility of forming between adjacent main and intermediate electrodes, as well as between adjacent intermediate bubbled electrodes discharges. Insulator dischargers 1 and 2 are interconnected by means of an insulator 3 having an insulating part 10 and connecting fittings (in this case, a cap 8 and a rod, in particular a pestle 9; the same fittings can be provided for insulator dischargers), mechanically connected with insulating part 4 (in Fig. 1 it is shown in partial section). The specified insulator 3 has one electrode 11 extended along the edge of the insulating part, mechanically connected by the insulating part 10 (in some cases, it can be connected with connecting fittings) and installed with protruding beyond the contour of the insulating part 4 in a plane perpendicular to the direction formed by the fittings of the connected insulator-arresters 1 and 2.

In some embodiments, the extended electrode may not protrude beyond the contour of the insulating part if discharge conditions are provided. For example, a discharge can go around the edge of an insulating part and enter an electrode that is not within sight of the electrode that is the source of the discharge (from which the discharge develops towards the electrode that does not protrude beyond the edge of the part). In addition, the insulators can have paired electrodes extended along the edge of the insulating part, which can be located on different sides of the insulating part (for example, essentially opposite each other) and can have an electrical connection enveloping or passing through the insulating part. In this case, the discharge will go to the electrode that is visible to it, is in direct access without enveloping.

In the insulator-dischargers shown in the drawings, the intermediate electrodes are located inside the insulating body and are separated from its surface by a dielectric layer, while discharge chambers 7 extending to the surface of the insulating body are made between adjacent electrodes. At the same time, such insulator-dischargers are possible in which the intermediate electrodes located not inside the insulating body, but, for example, on its surface, and therefore not separated from the surface by a dielectric layer. The discharge chambers, in turn, can be made between adjacent electrodes that do not extend to the surface, but, for example, directly on the surface of the insulating body. This can be realized if, for example, the intermediate electrodes are located on the surface of the insulating body or inside the insulating body, but at the same time they exit, for example, at their ends to the surface of the insulating body. The discharge gaps thus formed on the surface of the insulating body may have walls which will thus form the discharge chambers. In addition, there may not be any discharge chambers at all, and discharges may simply flow between the electrodes. All of these described and undescribed options are included in the scope of protection of the present invention defined by the independent claims.

When the insulators are connected in series by connecting the fittings of the insulator dischargers and the insulator (this can be, for example, a rod (pestle) / cap connection or bolt-on fittings with a hole in the flat part for connection), a garland of insulator dischargers is formed. The insulator included in the garland of FIG. 1 is provided with one (metal) electrode 11 extended along the edge of the insulating part, in particular in the form of a ring. However, on the insulators in accordance with the present invention, electrodes such as shown in FIG. 2.

The garland shown in FIG. 2, is a garland of insulator dischargers 21, 22, 23, 24, designed for installation on a 110 kV transmission line. Between the insulator dischargers 21, 22, 23, 24, insulators 25, 26, 27, respectively, are installed, which do not have electrodes (in the event that the fittings are made using metal, it is not considered to be electric in the sense of the present invention, since does not protrude beyond the contour of the insulating part in a plane perpendicular to the direction formed by the fittings of the connected insulator-arresters). This allows you to achieve the technical result of the present invention, which consists in eliminating the conditions for combining the discharges of adjacent insulator dischargers, since thanks to the insulator without electrodes they are located at a distance that prevents such a combination of discharges, and the absence of electrodes (in the more general case of two or more electrodes) ensures the absence discharges on the insulator, which could combine with the discharges between the intermediate electrodes of the insulator-arresters.

Overvoltage can be transferred from one insulator-discharger to another insulator-discharger by spark discharge between the main electrodes of insulator-dischargers: between the lower main electrode of the upper insulator-discharger and the upper main electrode of the lower insulator-discharger. For the upper pair of insulator dischargers 21 and 22 in FIG. 2, this can happen quite easily, since the main electrodes 28 and 29 of these insulator dischargers are located one above the other. However, for the middle pair of insulator dischargers 22 and 23, this is somewhat difficult, since their main electrodes 30 and 31 are not located one above the other due to the rotation of one of the insulator dischargers relative to the other, but, nevertheless, it is possible, since these electrodes are within line of sight and relative proximity. At the same time, the overvoltage transition between the main electrodes 32 and 33 of the lower pair of insulator dischargers 23 and 24 is impossible due to the fact that the main electrodes 32 and 33 are on opposite sides relative to the axis or line of the string defined by the connected fittings, and are hidden from each other by an intermediate insulator 27 due to the rotation of one insulator-arrester in relation to another relative to the specified axis or line - therefore, a discharge between them cannot occur, since they are not in direct visibility to each other itelno other.

This situation can be eliminated by turning the insulator-discharger so that the main electrodes are within line of sight relative to each other or preferably one above the other. Such a turn can be made during the installation or adjustment of garlands, which complicates the work and requires additional efforts of the installers. An additional complication is introduced by the fact that there are more than two insulator dischargers and, for their orientation relative to each other, must be carried out for each pair.

To eliminate this situation and simplify the work of installers, intermediate insulators 3 can be equipped with one electrode 11 extended along the edge (contour) of the insulating part, as shown in a similar garland in FIG. 3. There should be no more than one such electrode on each insulator (the absence of electrodes is also included in this condition) so that there are no discharges between the electrodes on the insulator itself, which could combine with the discharges between the electrodes of the insulator-arresters.

The length of the electrode along the edge (contour) of the insulating part simplifies the work of installers due to the fact that now the main electrodes of the neighboring insulator-dischargers are located one above the other or within the line of sight, it is now not necessary to turn the insulator-dischargers, since the length of the electrode on the insulator there will always be such sections of the electrode that will be opposite the main electrodes or within the direct line of sight of the main electrodes of the insulators - azryadnikov. Due to the fact that the specified electrode is preferably located along a plane perpendicular to the direction formed by the reinforcement of the connected insulator-arresters, its various sections will be located essentially at the same distance from the main electrodes of the insulator-dischargers regardless of their rotation.

Extended electrodes must be mechanically connected to the reinforcement (caps or rods) or insulating parts of the insulators in order to ensure the presence and constancy of the lightning protection properties of the insulator string. In addition, the electrodes should be installed with the protrusion beyond the contour (edge) of the insulating part in a plane perpendicular to the direction formed by the fittings of the connected insulator-dischargers, so that the electrodes are within the direct line of sight of the main electrodes of the insulator-dischargers insulating parts. In this case, it is necessary to ensure that the electrodes protrude beyond the contour (edge) of the insulating part in a plane perpendicular to the direction formed by the fittings of the connected insulator-dischargers, along all or most of the electrode extension along the edge (contour) of the insulating part - due to this, for any angular orientation of the insulator relative to neighboring insulator dischargers, their electrodes or at least electrode sections will be within the direct line of sight of the main electrodes and, thereby, form e the gaps between the main electrodes and the extended electrode.

In one embodiment, the electrodes are mechanically mounted on / in the insulating part (for example, on / in its edge, in which case the extended electrode may be called a conductive edge). Due to this arrangement of the electrodes, it is possible to reduce the metal consumption and, accordingly, the weight of the insulators, since the electrodes are located near the edge of the insulating part and there is no need to use additional parts that would connect the electrode distributed along the edge of the insulating part with the electrode mounting unit on / in the cap or rod . The electrodes can be fixed on an insulating part (fittings (cap, rod)) by gluing or snapping-in or by crimping the insulating part from above / below or along the entire contour if the electrode or its mounting part is made, for example, in the form of a ring (this option is described in more detail below). Thanks to such an electrode fastening, the present invention can be implemented on existing insulator strings, that is, they can be upgraded. In another embodiment, the electrodes can be fixed in an insulating part (fixture) during manufacture (for example, when pouring into the mold a hardening mixture forming an insulating part) or after, for example, at the installation site (for example, by screwing or inserting followed by gluing or snapping the electrode into the hole in the part / cap / shaft). In this case, it is possible to obtain ready-made insulators with electrodes extended along the edge of the insulating part in a simple way, which simplifies the installation of strings, or, as above, it is possible to upgrade existing insulator strings or simplify transportation when the electrodes mounted in the insulator begin to take up excess space.

In an advantageous embodiment, the electrode along the edge of the insulating part has a length of at least 0.4, 0.45 or 0.5 of the length of the contour (edge, perimeter) of the insulating part in a plane perpendicular to the direction formed by the fittings of the connected insulator-arresters (i.e., in the plane in which the insulating part has a predominant length, for example, in the horizontal plane, when the garland of insulator dischargers hangs from top to bottom). When the length of the electrode is half the length of the circuit, for any orientation of adjacent insulators relative to the insulator-dischargers, the extended electrode will form a discharge gap with the main electrodes of the insulator-dischargers, since the electrodes will be on top of each other or the end of the extended electrode will be within the direct line of sight of the main electrodes (in in the case when the insulators and insulator dischargers are oriented relative to each other so that the electrodes are on opposite sides of the other yg from a friend). Even in the case when the electrode along the edge of the insulating part has a length of at least 0.4, 0.45, the electrodes will form discharge gaps, because even in the worst case, when the electrodes of adjacent insulators and insulator dischargers are on opposite sides of the insulators, the ends of the electrodes will be within the line of sight of the main electrodes and this will allow the development of an electric discharge. The use of electrodes passing along only part of the contour of the insulating part allows to reduce the metal consumption on the electrodes and, accordingly, the weight of the insulator, while maintaining the simplification of the installation of the insulator string, since the installers can still not pay attention to the angular orientation of the insulators relative to each other during installation, while maintaining lightning protection properties of a garland of insulators.

At the same time, in a preferred embodiment, the electrode bends around the contour of the insulating part in a plane perpendicular to the direction formed by the fittings of the connected insulator-arresters, along the entire length of the specified circuit. This can provide a simplification of the production of insulators and the elimination of critical operating conditions when the electrodes can form discharge pairs only at their ends.

The insulator according to the present invention can be supplemented with a ring made using metal and with the possibility of mechanical fastening on the insulating part of the insulator. The extended electrode may have a partial extension along the ring made, for example, using dielectric materials, for example silicone rubber, and the ring itself can be attached using adhesive or snap fastening. This allows a simple method to fix an electrode of arbitrary length on the insulator. In one embodiment, the ring may be made of metal and has a groove on the inner surface of the ring, the ring being cut and the ends of the ring cut provided with a connection / retraction device to each other. This simplifies the design of the electrode and the method of fixing it.

The garlands described above can be used in electrical equipment, such as power lines. In particular, the power line may include supports, at least one wire under high electrical voltage and a string of insulator-dischargers in accordance with any of the above options, mechanically mounted on a support and connected directly or via fixing devices to the wire. The use of such garlands provides increased lightning protection of power lines, which means their reliability and stability of operation, due to the lightning protection properties of garlands formed by such insulators. At the same time, due to the length of the insulator electrodes, the simplification of the installation of insulator strings is additionally ensured. In the event that one or more insulator dischargers are used in the daisies, the permissible operating voltage and the class of lightning protection of the power line are increased.

Claims (8)

CLAIM 1. A garland of insulator-dischargers containing insulating bodies composed of dielectric, connecting fittings mechanically connected to insulating bodies, two main electrodes, mechanically connected to insulating bodies, and two or more intermediate electrodes, mechanically connected with insulating bodies and installed with the possibility of formation between adjacent main and intermediate electrodes, as well as between adjacent intermediate electrodes of discharges, and at least two of insulator-arrester interconnected by one or more insulators having insulating parts and the connection fitting are mechanically connected with the insulating parts. 2. The garland according to claim 1, characterized in that the intermediate electrodes are located inside the insulating body and are separated from its surface by a dielectric layer, while discharge chambers extending to the surface of the insulating body are made between adjacent electrodes. 3. The garland according to claim 1, characterized in that at least one insulator has an electrode extended along the edge of the insulating part, mechanically connected to the connecting fittings or insulating part. 4. The garland according to claim 1, characterized in that the electrode extended along the edge of the insulating part is installed with protruding beyond the contour of the insulating part in a plane perpendicular to the direction formed by the reinforcement of the connected insulator-arresters. 5. The garland according to claim 4, characterized in that the electrode extended along the edge of the insulating part bends around the contour of the insulating part in a plane perpendicular to the direction formed by the fittings of the connected insulator-arresters, along the entire length of the specified circuit. 6. The garland according to claim 3, characterized in that the electrode extended along the edge of the insulating part is mechanically fixed to / in the insulating part. 7. The garland according to claim 3, characterized in that the electrode extended along the edge of the insulating part has along the edge of the insulating part at least 0.4, 0.45 or 0.5 of the length of the contour of the insulating part in a plane perpendicular to the direction formed by the reinforcement to be connected discharge insulators. 8. A power line containing supports, at least one wire under high voltage and a string of insulator-dischargers in accordance with any one of claims 1 to 7, mechanically mounted on a support and connected directly or by means of fixing devices to the wire.