RU2329579C1 - Commutation contact for vacuum arresters - Google Patents

Abstract

FIELD: electric engineering.

SUBSTANCE: commutation contact for vacuum arresters with radial or axial magnet field contains contact board and pot-shaped contact holder with coil for creation of magnet field, which is formed by azimuthal slots of pot-shaped contact holder wall. External diameter of pot slotted wall is less than the diameter of contact board installed on it. Between contact board and base of contact holder ring-shaped support body is inserted, which embraces contact holder in at least slotted area. "Vacuum" gap is installed between external support body and slotted wall of pot.

EFFECT: increase of contact power.

2 dwg

Description

The invention relates to a switching contact for vacuum arresters according to the preamble of claim 1.

In the prior art, switching contacts for vacuum dischargers are known, which consist of a switching contact holder and a contact plate, the switching contact holder comprising a coil segment for creating a magnetic field, which is formed by side cuts of a pot-shaped contact holder. In particular, EP 0104384 B1 and EP 0155376 B1 describe similar contact devices. Depending on the mutual orientation of the two switching contacts, either a radial or axial magnetic field is created, and in practice they are important for high voltages, in particular, such devices with an axial magnetic field. For an axial magnetic field, the slots of the contact carrier in both contacts are oriented in the same direction.

Specifically, AMF (Axial Magnetic Field) -contacts (contacts of the axial magnetic field type) in the medium and high voltages region under normal contact forms after the processes of switching off short-circuit currents have pronounced radial expansion of the slotted coil segments, due to which at the edges of these coil segments increased electric fields appear, which accordingly noticeably worsens the dielectric properties of the arrester.

To ensure the stability of the contact device also at high currents and voltages in the prior art, there are also support bodies made of high heat resistant steels. These supporting bodies, however, are always located inside the contact pot. A contact of a vacuum circuit breaker in which an external cuff is used for the latter purpose is already known from DE 9305125 U1. The aim is, however, to increase contact stability in the same way. DE 3302939 A1 further describes a vacuum circuit breaker chamber with contacts, in the case of which a device with coil segments is centrally located in the contact, and therefore an annular gap with at least partially passing jumper. This device also serves solely to increase stability.

The objective of the invention, in contrast, is the creation of switching contacts with high power.

The task is solved according to the invention by the features of paragraph 1 of the claims. Further forms of development are indicated in the dependent claims.

In the switching contact of the invention, the outer diameter of the slotted wall of the pot is smaller than the diameter of the contact plate located thereon. In addition, there is an annular support body outside, that is, an external support body that is inserted between the contact plate and the base of the contact holder, that is, the bottom of the pot, and covers the contact holder, at least in the slotted region. In this case, there is a free gap between the external supporting body and the slotted wall of the pot, which, if used properly in a vacuum spark gap, forms a vacuum gap.

The invention has created an improved switching contact, which, in particular, is used in vacuum arresters with an axial magnetic field, and the increased field strengths appearing at the edges of the slots are minimized. No suitable solution is known from the prior art for the problem of interfering electric fields. If the coil body is covered by means of a steel strip extending externally as a cuff according to DE 9305125 U1 with only medium conductivity, then in still conventional manufacturing methods, the switching capacity is typically degraded in a typical manner by approximately 30%, which leads to a significant increase and thereby a rise in the cost of vacuum arresters. The reason for this deterioration in switching ability lies in a partial short circuit caused by a steel tape between two recessed coil elements, and a short circuit is caused by a tight electrical contact between the steel tape and coil elements or, respectively, between two adjacent coil elements, arising during soldering.

According to the invention, the AMF contact with the external support body is made such that a distance of typically 1 millimeter is maintained between the external support body and the coil body, and the external support body is soldered to the contact system only in its upper and lower edge regions. With such a gap width, direct shunting of the gap by flowing solder is excluded. Nevertheless, if the coil body in the switching mode expands during short circuit disconnections, then between the two coil elements there is only an electrical connection with only a small bandwidth and a relatively high resistance so that the contact itself undergoes only a slight decrease in switching capacity due to parallel electrical shunting through external supporting body. If an external support body is selected from an electrically non-conductive material, for example, ceramic, or a metal external support body is provided on its inner side with a layer of ceramic material, then parallel electrical shunting during expansion of the support body completely disappears and the switching capacity does not decrease.

Conventional contact structures and dimensions can also be applied, and even larger angles of the recesses of the coil body are possible due to the present invention to increase the switching ability, since the external support body acts in a stabilizing manner on the entire contact system. Due to this, with the same dimensions, relatively large breaking capacities can be achieved than in the prior art.

Further details and advantages of the invention are obtained from the following description of the figures, as well as exemplary embodiments based on the drawings in connection with the claims. At the same time show

Figure 1 is a perspective view of a pair of AMF contacts according to the prior art and

Figure 2 is a section through the contact with the external support body according to the invention.

The Figure 1 shows the device of the pair of contacts 1 according to the prior art, which consists of two identical contacts 10, 10 ′. The contacts 10, 10 ′ respectively comprise a contact bolt 11, 11 ′, a contact carrier 12, 12 ′ and a contact plate 15, 15 ′.

In Figure 1, the contact carrier 12, 12 ′ is made pot-like and has straight or curved, azimuthally inclined slots 14, 14 ′ on its annular part, which is designated as the wall of the pot 13, 13 ′. The slots 14, 14 ′ extend on the lateral surface of the wall of the pot 13, 13 ′ from the base, that is, the bottom of the pot, to the free end of the wall of the pot 13, 13 ′. At the free end of the wall of the pot 13, 13 ′, they enter the slots 16, 16 ′ supported on the contact carrier 12, 12 ′ of the contact plate 15, 15 ′. The slots 16, 16 ′ are often directed radially, however, they can also enclose an angle other than zero with a radius.

A similar device is known from the prior art, for which reference is made to the prior art cited in the introduction. Due to the azimuthal slots 14, 14 ′, coil segments are formed in the contact carrier 12, 12 ′, in which a switched current flows. By means of a switched current, a magnetic field is created, which, in the case of the orientation of the slots 14, 14 ′ shown in Figure 1, is directed axially in the same direction to the contact device and causes, when the contacts 10, 10 ′ are opened, a diffuse electric arc, which is marked with L _B in the Figure.

If the slots 14, 14 ′ - in contrast to Figure 1 - in both contacts 10, 10 ′ pass in the opposite direction relative to each other, then a radial magnetic field between the contacts 10, 10 ′ is obtained, as a result of which in this case a compressed electric arc is driven into motion on the circuit board 15, 15 ′ outward. To do this, the slots in the circuit board can, if necessary, be helical.

In the case of the device shown in FIG. 1, the recessed reel segments lie freely in the outer region and can expand after switching operations. Due to this, an increased external electric field arises at the edges of the slots, which can lead to switching failures, in particular when using a contact device in the high voltage region.

In Figure 2, the switching contact according to Figure 1 is modified according to the invention. Similarly, there is a switching bolt 21, a contact holder 22 with an annular part 23 as a pot wall and azimuthal slots 24, as well as a contact plate 25 with slots. The wall of the pot 23 with coil segments is made in Figure 2, however, shifted inward. Thus, a recess is formed by the wall of the pot with a diameter D _S together with the base 22a of the contact holder 22 and the contact plate 25 with the corresponding diameter D _K. An annularly extending external support body 20 is introduced into the recess, which surrounds at least the coil part of the wall of the pot 23.

The external support body 20 is made of steel or other similar material with low electrical conductivity. The supporting body 20 may also be made of an electrically non-conductive material, such as ceramic. It is also possible to coat a metal ring on its inner side with a layer of ceramic material.

The external support body 20 should be soldered into the recess. In this case, the solder can penetrate into the slots 24 and thereby cause a short circuit or partial short circuit, which leads to a decrease in the magnetic field and thereby to a deterioration in the switching properties of the contact.

According to Figure 2, it is provided that the external support body 20 is thin and inserted into the recess so that between the wall of the contact holder 22 with coil segments and the support body 20 there remains a circumferential hollow space 30, which, when used appropriately for the use of the contact device in a vacuum spark gap, implements a "vacuum gap".

By means of a vacuum gap 30 between the external support body 20 and the coil segment, it is avoided that solder can penetrate into the azimuthal slots 24 or, respectively, between adjacent slots 24 and the external support body 20. This achieves a mechanically strong connection between the external support body 20 and other contact parts, without the possibility of well-conducting short circuits or partial short circuits in the coil segments or between the coil segments and the external support body.

Claims (8)

1. A switching contact for vacuum arresters with a radial or axial magnetic field, with a contact holder and a contact plate, the contact holder having a coil for creating a magnetic field, which is formed by the azimuthal slots of the wall of the pot-shaped contact holder, for which the outer diameter (D _S ) of the slotted pot wall (23 ) is smaller than the diameter (D _K) located thereon a contact board (25), wherein there is an annular support body (20) which is inserted between the contact plate (25) and the base kontaktoder STUDIO (22) and covers the contact carrier (22) at least in the slotted area, and wherein there is a free gap (30) between the inner wall of the support body (20) and slotted wall of the pot (23). 2. The switching contact according to claim 1, characterized in that the gap (30) is less than 3 mm, in particular, has an order of magnitude of 1 mm. 3. A switching contact according to claim 1, characterized in that the annular supporting body (20) has a markedly lower electrical conductivity than the contact holder (22) with a coil element. 4. A switching contact according to claim 3, characterized in that the annular supporting body (20) is made of iron-based material. 5. A switching contact according to claim 3, characterized in that the annular supporting body (20) is at least on its inner side made of electrically non-conductive material. 6. The switching contact according to claim 5, characterized in that the electrically non-conductive material is ceramic. 7. A switching contact according to claim 1, characterized in that the annular supporting body (20) is soldered to the contact holder (22) or, respectively, to the contact plate (25) only in its upper and lower edge region. 8. A switching contact according to claim 1, characterized in that the annular supporting body (20) has the same outer diameter (D _K ) as the contact plate (25).

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