RU2402848C1 - Discharger (versions) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: discharger contains an insulating housing (1) and a dielectric (6) represented by a flat ring positioned between the surfaces of the first and the second electrodes, each represented by a flat graphite ring, two electric outputs each represented by a conductive flat ring and a connective plate having one of its ends fixed within the area of the outer surface of the conductive flat ring circumference with its other end projecting outside through the housing side surface, and one or two safety valves mounted accordingly on one or on the both ends of the cylindrical housing that, in case of arc discharge occurrence, perform discharge of electric erosion products from the space between the electrodes outside the housing (1) and prevent ingress of dust and moisture particles inside the housing (1).

EFFECT: improvement of the discharge operational stability and extension of its service life under powerful over-voltage conditions.

2 cl, 4 dwg

Description

The proposed technical solutions relate to the field of electrical engineering and can be used to create arresters having high stability of operation and their operating threshold, as well as a long service life with powerful overvoltage values.

Similar technical solutions are known, see, for example, the description of the invention to the USSR copyright certificate No. 815809, which contains:

- electrical insulating cylindrical body;

- the first electrode installed inside the insulating casing;

- a second electrode installed inside the insulating casing;

- a dielectric insert made in the form of a cylinder with a longitudinal groove on its side surface and installed between the end internal surfaces of the first and second electrodes;

- the first electrical terminal installed by one of its lateral surface on the surface of the first electrode;

- a second electrical terminal mounted by one of its lateral surfaces on the surface of the second electrode.

Common features of the proposed technical solution and the above-described analogue are:

- electrical insulating cylindrical body;

- the first electrode installed inside the insulating cylindrical body;

- a second electrode installed inside the insulating cylindrical body;

- a dielectric insert installed between the inner end surfaces of the first and second electrodes;

- the first electrical terminal installed by one of its end surface on the surface of the first electrode;

- a second electrical terminal mounted with one of its end surface on the surface of the second electrode.

A similar technical solution is also known, see the description of the invention for the USSR copyright certificate No. 1330682, which is selected as a prototype and which contains:

- electrical insulating cylindrical body;

- the first electrode located inside the insulating cylindrical body;

- a second electrode located inside the insulating cylindrical body;

- a dielectric made in the form of dielectric disks with metal circular overlays and installed between the surfaces of the first and second electrodes;

- a first electrical terminal mounted on the surface of the first electrode;

- a second electrical terminal mounted on the surface of the second electrode.

Common features of the proposed technical solution and prototype are the following features:

- electrical insulating cylindrical body;

- the first electrode installed inside the insulating cylindrical body;

- a second electrode installed inside the insulating cylindrical body;

- a dielectric mounted between the surfaces of the first and second electrodes;

- a first electrical terminal mounted on the surface of the first electrode;

- a second electrical terminal mounted on the surface of the second electrode.

The technical result, which cannot be achieved by any of the known similar technical solutions, consists in the maximum possible exclusion of the influence of electroerosion products, external dust and moisture particles on the performance of the arresters.

The reason for the impossible achievement of the above technical result is that the current practice in creating arresters on issues related to the maximum possible exclusion of the effect of electroerosion products on the performance of the arresters and the exclusion of dust and moisture particles from the surrounding space into the interelectrode space did not give due attention, therefore this issue remained unresolved.

The technical result indicated above, according to the first embodiment, is achieved by the fact that a spark gap comprising an electric insulating cylindrical body, a first electrode installed inside the electric insulating cylindrical body, a second electrode installed inside the electric insulating cylindrical body, a dielectric installed between the surfaces of the first and second electrodes, the first electric a terminal mounted on the surface of the first electrode and a second electrical terminal mounted on the surface of the WTO This electrode is equipped with a safety valve mounted and fixed on one end of the cylinder of the insulating cylindrical body, the dielectric is made in the form of a flat ring, fixed by the outer side surface of its circumference in a recess made on the inner surface of the insulating cylindrical body, the first electrode is made in the form of a flat graphite a ring mounted with its one end surface on one end (left) surface of a plane dielectric ring, the first electrical terminal is made in the form of an electrically conductive disk mounted on the other end of the cylinder of the electrical insulating cylindrical body and installed with one end surface on the inner surface of the cover of the electrical insulating cylindrical body and its other end surface on the other (left) surface of the graphite flat ring of the first electrode, and electrically conductive a connecting plate fixed to one of its ends in the area of the outer surface of the circumference of the electric wire a disk and extending outward with its other end through the side surface of the insulating cylindrical body, the second electrode is made in the form of a graphite flat ring mounted with its one (left) end surface on the other end surface of the dielectric flat ring, the second electrical terminal is made in the form of an electrically conductive flat ring, installed one of its end surface on the other (right) end surface of the graphite flat ring of the second electrode and located its m with a central hole at the inlet of the safety valve, and an electrically conductive connecting plate fixed to one of its ends in the region of the outer surface of the circumference of the electrically conductive flat ring and exiting with its other end to the outside through the side surface of the insulating cylindrical body.

The technical result indicated above according to the second embodiment is achieved in that the arrester comprising an electric insulating cylindrical body, a first electrode installed inside the electric insulating cylindrical body, a second electrode installed inside the electric insulating cylindrical body, a dielectric installed between the surfaces of the first and second electrodes, the first electric a terminal mounted on the surface of the first electrode and a second electrical terminal mounted on the surface of the WTO This electrode is equipped with a first safety valve mounted and fixed on one end of the cylinder of the insulating cylindrical body, a second safety valve mounted and secured on the other end of the cylinder of the insulating cylindrical body, the dielectric being made in the form of a flat ring fixed to the outer side surface of its circumference in the recess made on the inner surface of the insulating cylindrical body, the first electrode is made in the form of a graphite flat ring mounted with its one end surface on one (right) end surface of the dielectric flat ring, the first electrical terminal is made in the form of an electrically conductive flat ring installed with its one end surface (left) on the other end surface of the graphite flat ring of the first electrode and located at its inlet at the inlet of the first safety valve, and an electrically conductive connecting plate fixed to one of its ends in the region of the outer circumference of the electrically conductive flat ring and its other end facing out through the side surface of the insulating cylindrical body, the second electrode is made in the form of a graphite flat ring mounted with its one end surface (right) on the other end surface of the dielectric flat ring, the second electrical output is made in the form of a conductive flat ring mounted with one of its end surface (right) on the other end surface g a rafite flat ring of the second electrode and located at its inlet at the inlet of the second safety valve, and an electrically conductive connecting plate fixed at one of its ends in the region of the outer circumference of the electrically conductive flat ring and exiting with its other end outward through the side surface of the insulating cylindrical body.

The introduction of the safety valve, as well as the execution of the dielectric, the first and second electrodes, the first and second electrical leads and their location, as described above for the first embodiment of the arrester, allows for the occurrence of surge voltages and their arrival on the corresponding surfaces of the graphite flat rings of the first and second electrodes and the occurrence of electric breakdown in the interelectrode space, and then an arc discharge (leading to a sharp increase in temperature and pressure inside the elec of the insulating cylindrical body, as well as the occurrence of electrical discharge products), sharply limit the amount of overvoltage and at the same time, due to the pressure inside the insulating cylindrical housing, open the inlet of the safety valve and discharge the products of electroerosion through the corresponding holes of the safety valve from the interelectrode space into the surrounding space and to exclude the maximum possible effect of electroerosion products on the performance p the arrester and its threshold, and in the absence of overvoltage and arc discharges, return the safety valve to its original state and block the central hole of the second electrical outlet, preventing external particles of dust and moisture from entering the interelectrode space and not allowing them to deposit on the surface of the graphite flat rings of the first and the second electrodes, thus excluding their influence on the performance of the arrester and on its response threshold, which is the achievement of technical cut tata to the first embodiment of the arrester.

The introduction of safety valves, as well as the execution of the dielectric, the first and second electrodes, the first and second electrical leads and their location, as described above for the second embodiment of the arrester, allows for the occurrence of surge voltages and their arrival on the corresponding surfaces of the graphite flat rings of the first and second electrodes and the occurrence of electric breakdown in the interelectrode space, and then an arc discharge, leading to a sharp increase in temperature and pressure inside the elec of the waterproofing cylindrical body, as well as the occurrence of electrical discharge products, sharply limit the amount of overvoltage and at the same time, due to the pressure inside the electrical insulating cylindrical body, open the inputs of the first and second safety valves and discharge the products of electroerosion through the corresponding holes of the first and second safety valves from the interelectrode space in the surrounding space and thereby exclude the maximum possible effect of pr of electrical discharge erosion on the operability of the arrester and on its response threshold, and in the absence of overvoltage and arc discharges, return the first and second safety valves to their original state and block the central holes of the first and second electrical leads, preventing external particles of dust and moisture from penetrating into the interelectrode space and not allowing them to precipitate on the surfaces of graphite flat rings of the first and second electrodes, thus eliminating their influence on the performance of the arrester and on its about the threshold, which is the achievement of the technical result for the second version of the arrester.

The analysis of the known similar technical solutions showed that none of them contains both the entire set of features and the distinctive features of the proposed technical solutions with their inherent properties, which allowed us to conclude that the proposed technical solutions meet the patentability criteria of “novelty” and “inventive” level".

The proposed versions of the arrester are explained in the following description and drawings, in which Fig. 1 shows a sectional view of the arrester according to the first embodiment, Fig. 2 shows the arrester according to the first embodiment (side view of the relief valve), Fig. 3 shows a sectional view of the arrester according to the second embodiment and figure 4 shows the arrester according to the second embodiment (view of the location of the safety valves).

The proposed arrester according to the first embodiment contains:

- electrical insulating cylindrical body - 1 with a cover - 2, mounted on one of the ends of the cylinder of the electrical insulating cylindrical body - 1;

- the first electrical output, made in the form of an electrically conductive disk - 3, mounted on one of the ends of the cylinder of the insulating cylindrical body - 1 and located with one of its end surfaces on the inner surface of the cover - 2 of the insulating cylindrical body - 1, and the conductive connecting plate - 4, for example , rectangular in shape, fixed by one of its ends in the region of the outer surface of the circumference of the electrically conductive flat disk - 3 and going out with its other end, gaplessly on I am driving through the side surface of the insulating cylindrical body - 1;

- the first electrode, made in the form of a graphite flat ring - 5, installed with its one end surface on the other end surface of the conductive flat disk - 3 of the first electrical output;

- a dielectric made in the form of a flat ring - 6 (for example, made of fluoroplastic), fixed with its outer lateral surface of a circle in a recess made on the inner surface of the insulating cylindrical body - 1 and installed with one of its end surfaces on the other end surface of a graphite flat ring - 5 the first electrode;

- the second electrode, made in the form of a graphite flat ring - 7, installed with its one end surface on the other end surface of the flat ring - 6 dielectric;

- the second electrical terminal, made in the form of an electrically conductive flat ring - 8, mounted with one of its end surfaces on the other end surface of a graphite flat ring - 7 of the second electrode, and an electrically conductive connecting plate - 9, for example, of a rectangular shape fixed by one of its ends in the region the outer surface of the circumference of the electrically conductive flat ring - 8 and facing its other end, gaplessly outward through the side surface of the insulating cylindrical body - 1;

- a safety valve made in the form of a disk - 10 (for example, from polypropylene) with holes - 11, 12, 13, 14, 15, 16, 17 and 18, made in the central region of the circumference of the disk - 10, fixed to the end (right) an electrical insulating cylindrical body - 1 (by means of, for example, adhesive bonding) and a shutter made in the form of a cylindrical rubber protrusion - 19, mounted one of its ends in a recess made on the inner surface of the disk - 10 and a rubber circle - 20, fixed with one of its end surface on rugom end of the cylindrical protrusion of the rubber - 19 and its other end mounted on the output surface of the central opening of the flat conductive rings - 8 of the second electrical terminal. In this case, the diameter of the rubber circle is 20 more than the diameter of the rubber cylindrical protrusion is 19 and more than the diameter of the hole of the electrically conductive flat ring is 8 of the second electrical output, and the flat graphite ring is 5 of the first electrode, the flat ring is 6 dielectrics, the flat graphite ring is 7 of the second electrode and a conductive flat ring - 8 of the second electrical terminal are installed coaxially with their holes.

The proposed arrester according to the second embodiment contains:

- electrical insulating cylindrical body - 1;

- a dielectric made in the form of a flat ring - 6 (for example, of fluoroplastic), fixed with its outer lateral surface of a circle in a recess made on the inner surface in the center of the insulating cylindrical body - 1;

- the first electrode, made in the form of a graphite flat ring - 7, installed with its one end surface on one (right) end surface of the flat ring - 6 dielectric;

- the first electrical terminal, made in the form of an electrically conductive flat ring - 8, installed one of its end surface on the other (right) end surface of a graphite flat ring - 7 of the first electrode, and an electrically conductive connecting plate - 9, for example, a rectangular shape, fixed by one of its ends in the area of the outer circumference of the electrically conductive flat ring - 8 and protruding through its other end through the lateral surface of the insulating cylindrical body - one;

- the first safety valve, made in the form of a disk - 10 (for example, from polypropylene) with holes - 11, 12, 13, 14, 15, 16, 17 and 18, made in the Central region of the circumference of the disk - 10, mounted on the end (right ) of an electrical insulating cylindrical body - 1 (by means of, for example, adhesive bonding) and a shutter made in the form of a rubber cylindrical protrusion - 19, mounted one of its ends in a recess made on the inner surface of the disk - 10 and a rubber circle - 20, fixed with one of its own end face one at the other end of the cylindrical rubber protrusion - 19 and installed with its other end surface at the outlet of the central hole of the electrically conductive flat ring - 8 of the first electrical outlet, while the diameter of the rubber circle is 20 more than the diameter of the rubber cylindrical protrusion - 19 and more than the diameter holes conductive flat rings - 8 of the first electrical output;

- the second electrode, made in the form of a graphite flat ring - 5, installed with its one end surface on the other (left) end surface of the flat ring - 6 dielectric;

- the second electrical terminal, made in the form of an electrically conductive flat ring - 3, mounted with one of its end surfaces on the other (left) end surface of a graphite flat ring - 5 of the second electrode, and an electrically conductive connecting plate - 4, for example, of a rectangular shape, fixed by one of its ends in the area of the outer surface of the circumference of the electrically conductive flat ring - 3 and going to its other end gaplessly out through the side surface of the insulating cylindrical body - one;

- the second safety valve, made in the form of a disk - 31 (for example, made of polypropylene) with holes - 21, 22, 23, 24, 25, 26, 27 and 28, made in the Central region of the circumference of the disk - 31, mounted on the end (left ) electrical insulating cylindrical body - 1 (through, for example, adhesive bonding) and a shutter made in the form of a rubber cylindrical protrusion - 29, mounted one of its ends in a recess made on the inner surface of the disk - 31 and the rubber circle - 30, fixed one of its end face on the other end of the rubber cylindrical protrusion - 29 and installed by its other end surface at the outlet of the Central hole of the conductive flat ring - 3 of the second electrical output. Moreover, the diameter of the rubber circle is 30 more than the diameter of the rubber cylindrical protrusion is 29, and more than the diameter of the hole of the electrically conductive flat ring is 3 of the second electrical outlet, and the electrically conductive flat ring is 8 of the first electrical outlet, the flat graphite ring is 7 of the first electrode, a flat ring - 6 dielectrics, a flat graphite ring - 5 of the second electrode and a conductive flat ring - 3 of the second electrical terminal are installed coaxially with their holes.

The proposed spark gap according to the first embodiment works as follows.

When entering the first - 4 and the second - 9, the electrical leads of a pulse overvoltage of sufficient amplitude an electric breakdown occurs, passing into an arc discharge only between the central regions of the first - 5 and second - 7 electrodes, because this is ensured by a flat ring of 6 dielectrics, the outer diameter of which is larger than the outer diameters of flat graphite rings of 5, 7 electrodes, preventing the occurrence of electrical breakdown on the outer edges of the graphite flat plates of the first - 5 and second - 7 electrodes, and the inner diameter is larger than the diameter of the electrode hole 5 and 7.

In this case, the magnitude of the overvoltage drops sharply and, accordingly, the overvoltage is limited. In an arc discharge, the arrester resistance is on the order of tenths of an Ohm. In the presence of graphite electrodes, an arc discharge occurs at current densities of ≈500 A / cm ² (threshold). At the same time, in the presence of metal electrodes, an arc discharge occurs at current densities of ≈5000 A / cm ² .

When an arc discharge occurs in the interelectrode space, the temperature and, accordingly, the pressure rises sharply. This leads to the fact that the products of electroerosion are ejected from the interelectrode space into the central hole and pass through the central coaxially located hole of the second electrical outlet - 8 to the inlet of the safety valve. Under the action of pressure, the rubber circle - 20 of the shutter of the safety valve opens the central hole of the electrically conductive flat ring - 8 of the second electrical outlet and provides the discharge of electrical discharge products through the holes - 11, 12, 13, 14, 15, 16, 17 and 18 of the disk - 10 of the safety valve for the limits of the inner cavity of the insulating cylindrical body - 1, thus excluding the effect of electrical discharge products on the performance of the arrester.

In the absence of overvoltages and, accordingly, arc discharges, the rubber circle - 20 of the shutter of the safety valve returns to its original state and overlaps the central hole of the electrically conductive flat ring - 8 of the second electrical outlet. At the same time, neither moisture nor dust particles from the environment enter the interelectrode space and do not precipitate in the interelectrode space zone and thus exclude the influence of moisture and dust particles on the performance of the arrester, which, in turn, ensures high and stable performance of the arrester and its operating threshold, as well as the long life of the arrester with powerful overvoltage values.

The proposed spark gap according to the second embodiment works as follows.

Upon receipt of the first - 9 and second - 4 electrical leads of a pulse overvoltage of sufficient amplitude, an electrical breakdown occurs between the first and second electrodes, passing into an arc discharge.

In this case, the magnitude of the overvoltage drops sharply and, accordingly, the overvoltage is limited. In an arc discharge, the arrester resistance is on the order of tenths of an Ohm. In the presence of graphite electrodes, an arc discharge arises at current densities of ≈500 A / cm ² , while in the presence of metal electrodes, an arc discharge arises at current densities of ≈5000 A / cm ² . When an arc discharge occurs in the interelectrode space, the temperature and, accordingly, the pressure rises sharply. This leads to the fact that the products of electroerosion are ejected from the interelectrode space into the central holes of flat graphite rings - 7 and 5 and flow through the central coaxially located holes of the first and second electrodes and the first and second electrical leads to the inputs of the first and second safety valves.

Under the action of pressure, the rubber circle - 20 shutters of the first safety valve and the rubber circle - 30 shutters of the second safety valve open the central holes of the electrical conductive flat ring - 8 of the first electrical outlet and the electrical conductive flat ring - 3 of the second electrical outlet and thereby discharge electrical discharge through the holes - 11, 12, 13, 14, 15, 16, 17 and 18 of the disk - 10 of the first safety valve and through the holes - 21, 22, 23, 24, 25, 26, 27 and 28 of the disk - 31 of the second safety valve the limits of the inner cavity of the insulating cylindrical body - 1, thus excluding the effect of electrical discharge products on the performance of the arrester.

In the absence of overvoltage and, accordingly, arc discharges, the rubber circle - 20 shutters of the first safety valve and the rubber circle - 30 shutters of the second safety valve return to their original state and overlap the central holes of the electrical conductive flat ring - 8 of the first electrical output and electrical conductive flat ring - 3 of the second electrical output. At the same time, neither moisture nor dust particles from the environment enter the interelectrode space and do not precipitate in the interelectrode space zone and thus exclude the influence of moisture and dust particles on the performance of the arrester, which, in turn, ensures high and stable performance of the arrester and its operating threshold, as well as the long life of the arrester with powerful overvoltage values.

Thus, the proposed versions of the arresters due to the implementation of the dielectric, the first and second electrodes and the introduction of one or two safety valves provide the elimination of the influence of electroerosion products, dust and moisture particles on the performance of the arrester and provide high and stable operation of the arresters and their response threshold, as well as long-term service life at powerful overvoltages. Therefore, the proposed versions of arresters will take their rightful place among the well-known objects of a similar purpose.

Claims (2)

1. Arrester containing an insulating cylindrical body, a first electrode installed inside the insulating cylindrical body, a second electrode installed inside the insulating cylindrical body, a dielectric installed between the surfaces of the first and second electrodes, a first electrical terminal mounted on the surface of the first electrode, and a second electrical an output mounted on the surface of the second electrode, characterized in that it is equipped with a safety valve, setting insulated and fixed at one end of the cylinder of the insulating cylindrical body, the dielectric is made in the form of a flat ring, fixed by the outer side surface of its circumference in a recess made on the inner surface of the insulating cylindrical body, the first electrode is made in the form of a graphite flat ring mounted with its one end surface on one of the end surfaces of the plane dielectric ring, the first electrical terminal is made in the form of an electrically conductive plate oskogo disk mounted on the other end of the insulating cylindrical body and installed with one of its end surface on the other end surface of the graphite flat ring of the first electrode, and an electrically conductive connecting plate fixed at one of its ends in the outer circumference of the circle of the electrically conductive flat disk and facing its other end outward through the side surface of the insulating cylindrical body, the second electrode is made in the form of a graphite plate oskogo ring mounted on its one end surface on the other end surface of the plane dielectric ring, the second electrical output is made in the form of an electrically conductive flat ring mounted on one of its end surface on the other end surface of the graphite flat ring of the second electrode and located at its inlet at the inlet of the safety valve, and an electrically conductive connecting plate fixed to one of its ends in the region of the outer surface of the circle e ektroprovodnogo flat ring and leaving the other end thereof outwardly through the lateral surface of the electrically insulating cylindrical body. 2. A spark gap containing an insulating cylindrical body, a first electrode installed inside the insulating cylindrical body, a second electrode installed inside the insulating cylindrical body, a dielectric installed between the surfaces of the first and second electrodes, a first electrical terminal mounted on the surface of the first electrode, and a second electrical an output mounted on the surface of the second electrode, characterized in that it is provided with a first safety valve, installed and fixed on one end of the cylinder of the insulating cylindrical body, a second safety valve mounted and secured on the other end of the cylinder of the insulating cylindrical body, the dielectric is made in the form of a flat ring fixed by the outer side surface of its circumference in a recess made on the inner surface of the insulating cylindrical body , the first electrode is made in the form of a graphite flat ring installed with its one end face surface on one of the end surfaces of the plane dielectric ring, the first electrical terminal is made in the form of an electrically conductive flat ring mounted on its other surface on the other end surface of the graphite flat ring of the first electrode and located at its inlet at the inlet of the first safety valve, and an electrically conductive connecting plate, fixed by one of its ends in the area of the outer surface of the circumference of the electrically conductive flat ring and exiting with its other end outward through the side surface of the insulating cylindrical body, the second electrode is made in the form of a graphite flat ring mounted with its one end surface on the other end surface of the flat dielectric ring, the second electrical output is made in the form of an electrically conductive flat ring mounted with one of its end surface on the other end surface of a graphite flat ring of the second electrode and located at its input th the relief valve, and the conductive interconnector plate, fixed by one of its ends in the outer circumferential surface of the flat conductive rings and its other end emerging outwardly through the lateral surface of the electrically insulating cylindrical body.

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