DD230958A1 - VACUUM arc chute - Google Patents

Abstract

The vacuum arc chamber contains a Zylindergehaeuse, frontally bounded by flanges, in the direction of Gehaeuseachse corrugated tubes, and is divided by a parallel to the flanges partition into two cavities. The partition is made of non-magnetic conductive material. Within each cavity there are housed a fixed contact secured to the bulkhead, a movable contact secured to a current conducting bar passing through the corrugated tube of the corresponding flange, and a system of screens. At least one of the contacts of each cavity is designed as a current-conducting base plate, a coiled at the periphery of the metallic base plate spiral winding and coaxial with the metallic base plate, electrically connected to the spiral winding electrically conductive plate whose height is smaller than that of the spiral winding. The winding directions of the spiral turns of these contacts coincide with each other. The ratio of the distance between the surfaces of the immobile contacts facing the movable contacts to the outer diameter of the contact is within limits of 0.05 to 1. FIG. 1

Description

β ο ο ο

Berlin, 24.6.1983 61 875/17

Yak uum-L i ent b ο genl acac hkammer

Field of application of the invention;

The present invention relates to high-voltage switching technology for high power, and more particularly relates to vacuum arc-quenching chambers.

The device according to the invention is used in the field of the field of electrolysis »in the commutation of metallurgical electric arc furnaces, the commutation of capacitor banks and inductive storage»

Characteristic of known technical solutions

Vacuum arc arc quenching chambers are known which contain a housing made of a vacuum-tight insulating material, which is delimited by splashes on the front side and in which several contacts, which are movable relative to one another, are connected in series (see, for example, SU-certificate 290341, class HO1H'33) / 66). The two of the known contacts are attached to the splitter, one of which is movable and has a lead-out for connection to a drive, the remaining intermediate contacts are in series in the height of the housing and are slidably disposed, either by 'application of Viellrohren or pedestrians that hold all interposers in the open state when performing a turn-off operation through the chamber. "Such chambers are designed for a low (not more than 10 kA) cut-off current, which limits their scope. This is due to the fact that the force at the contact opening by the

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Elasticity of the corrugated pipe © or · limited springs, and at high currents Verchweißung the contacts with each other with a force is possible, which exceeds the spring force of the Weilrohre or Pedern. As a result, the intermediate contacts or a part thereof are not opened when switching off, d. h " the chamber will fail completely"

There are vacuum arc extinguishing chambers (s, for example, the SU-certificate 705909, Kl. H 01 H 33/66) are known in which at least one of the contacts in the form of a metallic base plate, a coiled on the circumference of the metallic base plate and coaxial therewith and a coaxial with the metallic base plate fixed current-conducting plate is executed. The current conducting plate is electrically coupled to the spiral winding. The height of the current-conducting plate is smaller than that of the spiral winding. The chamber with such contacts is sized to turn off currents up to several tens of kA at a voltage of a few tens of kV. For a further increase in voltage, it is necessary to insert between the contacts a partition with attached intermediate contacts.

Also known are vacuum arc quenching chambers (see, for example, U.S. Patent No. 3,798,484, Kl. 313-198), which include a cylinder housing made of a vacuum-tight insulating material which is delimited at the front by splashing, in which direction Housing axis corrugated tubes lie, and which is divided by a wall parallel to the flanges partition into two cavities. Within each of the cavities are arranged at one in the direction of the housing axis and through the corrugated tube of the corresponding

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The contacts of the two cavities of the chamber are in the form of flat discs, the diameter of which is larger than that of the current-conducting rods, resulting in a fixed plane contact fixed to the separating wall creates an electromagnetic force acting on the arc.

In each cavity are arranged around the current conducting bars and contacts around two groups of stick electrodes. The first of them is attached to the splash, the second to the partition. The stick electrodes of the first and second groups alternate with each other. The two groups of stick electrodes are surrounded by three shields, one of which is insulated from the other electrodes, while the other two are connected to the planch or partition. The diameter of the insulated screen is smaller than that of the other two screens. When pulling out the movable current-conducting rods, the contacts between which an arc is formed, opened in the two cavities. This arc is applied to the rod electrodes by the action of the electromagnetic force and initiates diffusion arcs between the rod electrodes of the two groups. As a result, the current flowing through the chamber is distributed to the contacts and the stick electrodes, and therefore the chamber of such construction has an increased current absorbing capacity. Since the two cavities of the chamber are also electrically connected in series, this construction also has an increased

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The described vacuum arc quenching chamber, however, has a low electrical strength, large dimensions and material intensity. "The low electrical strength is due to the presence of a large number of electrically parallel connected vacuum spaces, which through the contacts, stick electrodes, splashing and the partition are formed »The total number" K "of such spaces in a cavity results" to:

K = 6C + 1

Here, C is the number of pairs of the stick electrodes. For example, the total number of parallel gaps in four pairs of stick electrodes is 25 · Usually, the number of stick electrodes exceeds four in powerful chambers, thereby increasing the number of electrically parallel gaps and the breakdown voltage of the system of parallel gaps with their increasing Number decreases. Thus, lowering the 50% discharge voltage for a number of spaces is equal to 25 ca, 2 <f, where S is a standard deviation of the breakdown function of the breakdown voltage. For example, if the 50% breakdown voltage of the vacuum space is 100 "kV and the standard deviation is 15 to 20 kV (a common ratio between the breakdown voltage and the standard deviation for the vacuum spaces), then the 50% breakdown voltage for a system will make up 25 such gaps Their parallel connection 60 to 70 kV, so it drops by 30 to 40 % , which makes up the corresponding value "The insufficient electrical strength of said chamber is also due to the presence of the stick electrodes, which has an enlarged surface

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in the range of a high electric field strength * The increase of the dimensions and the material intensity of the chamber is due to the presence of the large number of sticked in the cavities of the chamber stick electrodes. Moreover, the ability to reduce the dimensions and material intensity is also limited by the characteristics of arc burning in the system with the stick electrodes. Between the stick electrodes burns a diffusion arc, which is characterized in that form at the stick electrodes cathode spots of the first kind whose propagation velocity across the cathodes is 10 to 40 m / s »The burning time of the arc in the chamber reaches 10 ms and more, for this time, the cathode spots go through a distance of 0.1 to 0.4 m. Thus, as they form on the stick electrodes, they access the end flanges and the dividing wall, through which they can reach umbrellas lying around their circumference, protecting the casing from dusting. The screens, however, fulfill their puncture only on the condition that the cathode spots are absent. The transition of the cathode spots on the screens causes a failure of the chamber by a loss of electrical strength due to a metallization of the housing. In order to prevent this, the path length of the cathode spots on the stick electrodes, the dividing wall and the splashing to the screens must not be more than 0.1 m, while the immovable contacts must be fixed to the dividing wall by means of an electrically conductive bar.

Object of the invention

The present invention aims to reduce the dimensions and material intensity of the vacuum arc quenching chamber.

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Presentation of the essence of the invention

The present invention has for its object to provide such a vacuum arc quenching at. which allow the arrangement and the structural design of elements ea, to increase the electrical strength, to simplify the construction, to reduce the dimensions and the cost of materials.

This is achieved in that in the vacuum arc quenching chamber, which includes a cylinder housing made of a vacuum-tight insulating material, the front side bounded by flanges, which lie in the direction of the housing axis corrugated tubes, and which is divided by a wall parallel to the flanges partition into two cavities within which there is housed each a stationary contact connected to the partition, a movable contact secured to a current-carrying rod passed through the Y / ellrohr of the corresponding flange and a system of screens, one of which is electrically coupled to the partition, according to Invention, the immovable contacts of the two cavities are attached directly to the partition wall, which is made of a non-magnetic conductive material and at least one of the contacts gedes cavity in the form of a current-conducting base plate, a arranged on the circumference of the metallic base plate and coaxial therewith Piralwindung and a coaxial with the metallic base plate attached to the spiral winding electrically coupled current-conducting plate whose height is smaller than that of the spiral winding, wherein the winding directions of the spiral turns of these contacts coincide and the ratio of the distance between the surfaces of the movable contacts facing immovable contacts to the outer diameter of the

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Contact for generating a arc between the contacts stabilizing magnetic axial field within limits of 0.05 to 1 moves.

It is desirable that the ratio of the resistivity of the non-magnetic conductive material of the partition wall to the specific copper resistance for reducing the value of eddy currents in the partition wall of the vacuum arc quenching chamber is between 1.5 and 100.

The application of the present invention provides the ability to increase the voltage to the vacuum arc quenching chamber, lower the arc voltage, and thereby reduce power generation in the chamber during power down.

In addition, this reduces the contact erosion and increases the electrical operating life of the vacuum arc quenching chamber.

Model game

The advantages of the present invention will become apparent from the following detailed description of the vacuum arc quenching chamber, its embodiments and the accompanying drawings. Show it

Pig. 1: an overall view of a vacuum arc quenching chamber according to the invention (in longitudinal section);

FIG. 2 shows a movable contact according to the invention (in plan view). FIG

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Pig. 3: a movable contact according to the invention (in H-II section nacii Fig «2 in side view)!

4 shows another embodiment of the contact system according to the invention (in longitudinal section through the contact region);

5 shows a third embodiment of the contact system according to the invention (in longitudinal section through the contact area).

The vacuum arc quenching chamber contains a cylinder housing 1 (Pig.1) made of a vacuum-tight insulating material which is delimited by planters 2 and 3 at the end. 1 and 2 are located in the direction of the axis 4 of the housing 1 corrugated pipes 5, 6. The housing 1 is divided by a parallel to the splitter 2 and 3 partition 7, which is made of a non-magnetic conductive material whose specific electrical resistance exceeds that of copper by 1.5 to 100 times. As a result, the partition wall 7 counteracts a superposition of both sides of this generated magnetic fields in any way. Thus, two cavities 8, 9 form. Within each cavity 8, 9 immobile contacts 10, 11 are housed. The immovable contacts 10, 11 are made in the form of discs of an arc-fast material, which are soldered on both sides of the partition 7. There are also -Jewegliche contacts 12, 13 are provided, which are attached to current-conducting rods 14, 15. The current-conducting rods 14 »15 extend through the corrugated tubes" 5, 6 hinduroh. In the housing 1, a system of umbrellas is arranged, which consists of umbrellas 16, to the splashing, on the insulated part of the housing 1 fixed insulated umbrellas 18, 19, and with the partition 7 elek-

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Each of the movable contacts 12, 13 consists of a current-conducting base plate 22, a spiral winding 23, a current-conducting plate 24 "a ring 25 and a web 26. Each of the movable contacts 12 and 13 is on its base plate 22 connected to the respective current-conducting rod 14, 15. The spiral winding 23 is arranged on the circumference and coaxial with the current-conducting base plate 22. The current-conducting plate 24 is arranged coaxially with the metallic base plate 22 and electrically connected to the spiral winding 23 via the web 26. The height of the current-conducting plate 24 is smaller than that of the spiral winding 23 », which is why the contact surface of the movable contacts 12, 13 and the immovable contacts 10, 11 coincides with the surface of the spiral winding 23. The ring 25 is made of a mechanically strong material with a high electrical resistivity, for example of stainless steel, and arranged on the peripheral part of the current-conducting base plate 22 and mechanically connects the current-conducting base plate 22 with the spiral winding 23. Stromleitende bars 14, 15 electrically conductive Base plates 22, spiral windings 23, current-conducting plates 24 and webs 26 of the movable contacts 12, 13 are made of materials having a high electrical conductivity, for example, of copper or its alloys.

Between the current-conducting plate 24 and the spiral winding 23 there is an annular gap 27 (Mg.sub.2) in which the web 26 lies. The spiral winding 23 has a gap 28 '"on.

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One end 29 (Pig 3) of the spiral winding 23 is soldered to the current-conducting base plate 22, the other end 30 of the spiral winding 23 is not connected to any of the parts.

A variant is possible, where a ring 31 made of an arc-resistant material is soldered to the immovable contact 10, 11 facing side of the spiral winding.

Pig. 4 shows another embodiment variant of the system of immovable and movable contacts 10, 11, 12, 13. In this embodiment, the stationary contacts 10, a current-conducting base plate 22, a spiral winding 23 "have an electrically conducting plate 24, a ring 25 and a web 26 on. The movable contacts 12, 13 are made in the form of sheets of arc-fast material, which are fixed to the current-conducting rod 14 and 15, respectively.

It is a third embodiment of the system of immovable and movable contacts 10, 11, 12, 13 possible, where all contacts 10, 11, 12, 13 current-conducting base plate 22, spiral winding 23 »current-conducting plate 24, ring 25 and web 26 have.

In the practice of any of the embodiments of the contact system (Figures 1, 4, 5), the helix directions of the spiral turns 23 of the contacts 10, 11, 12, 13 in the two cavities 7 ₉ 8 are the same.

The ratio of the distance between the surfaces of the stationary contacts 10, 11 facing the movable contacts 12, 13 to the outer diameter of any one of the contacts 10, 11, 12, 13 is within limits of 0.05

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to 1, which ensures the required magnetic field strength «

The vacuum arc quenching chamber operates as follows. When the contacts 10 (Pig.1) and 12, 11 and 13 are closed together, a current flows through them in an electrical circuit in which the chamber is located. The current flows in the chamber via current-conducting rod 14, base plate 22, spiral winding 23, contact 12, stationary contact 10, partition 7 and further immovable contact 11, movable contact 13 and current-conducting rod 15 · Since the current over the same Wickelsinn wound and both sides of the partition wall 7 at a distance not greater than the diameter of the contact arranged spiral turns flows, a magnetic field with an axial component of the induction of about 0.01 T / kA is constructed. The partition 7 disturbs a superimposition of the magnetic fields of the mutually arranged on the spiral spirals 23 in no way. At the opening of the contacts 10 and 12, 11 and 13, which comes about by displacement of the movable contacts 12, 13, arise between them electric arc. However, since the immovable contact 10, 11 facing surface of the spiral winding 23 projects beyond the surface of the current-conducting plate 24, the arcs are preferably between said surface of the spiral winding 23 and the immovable, contact

10, 11 formed. The magnetic field generated by the spiral windings 23 is at the opening of the contacts 10, 12 and

11, 13 and when burning the electric arc between them maintained, which is why the electrical arcs are stabilized by this field «

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Due to the stabilization of the electric arcs by the magnetic field, the arc voltage in each of the cavities 8, 9 does not exceed a few tens of volts with an amplitude of the dissipating current of a few tens of kA. A decrease in the arc voltage causes a reduction in the power generation in the chamber, which 'has a reduction in the erosion of the contacts 10, 11, 12, 13, an increase in the electrical operating life of the chamber, a reduction in its diameter result. In addition, the stabilization of the arc by the magnetic field prevents its passage from the contacts 10 and 11 to the partition wall 7 and to the screens 20 and 21.

The screens 16, 17 on the splashing, the insulated screens 18, 19 and the electrically coupled to the partition wall 7 umbrellas 20, 21 serve to treasure the cylinder housing 1 aus'einem vacuum-tight insulating against the action of combustion products at the opening of the, contacts 1.0 .., 12. .Lind 11, 1.3 arising electric arc. The insulated shields 18, 19 balance the distribution of stress across the housing 1.

The corrugated pipes 5, 6 ensure the maintenance of the hermetic seal of the housing 1 with a displacement of the movable contacts 12 and 13 ·

A portion of the sheet stream flows through the current conducting plate 24, whereby the turn-off current also increases. However, so that the current flowing through the current-conducting plate 24 does not exceed a certain level at which their destruction is possible, the current-conducting plate 24 is connected to the spiral winding 23 through the web 26 located in the annular gap 27. Sin part of the arc current, over

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the current-conducting plate 24 flows parallel to the current-conducting base plate 22, generates an electromagnetic force, which transmits the arc from the current-conducting plate 24 to the spiral winding 23, which just the limitation of flowing over the current-conducting plate 24 portion of the arc current is achieved. When closing and opening the contacts 10, 12 and 11, 13 of the chamber and the flow of currents up to a few tens of kA through them, they are subjected to an action of forces that many thousands of pounds F. »To withstand these effects, the Spiral winding 23 mechanically connected to the current-conducting base plate 22 through the ring 25. The preparation of the ring 25 made of stainless steel makes it possible to prevent a considerable current dissipation through this of the spiral winding 23 in the current-conducting base plate 22 in circumvention of the soldered to the base plate 22 end 29 of the spiral winding 23, wherein a sufficient mechanical strength of the contacts 12th The presence of a respective pair of the contacts 10, 12 and 11, 13 in the two cavities 8, 9, which are connected in series for the electric circuit, allows currents of a few tens to be made with the aid of this chamber kA to switch off at a voltage of one hundred and more kV in the circuit.

The other embodiments of the vacuum arc quenching chamber shown in Figs. 4, 5 are analogous to those described above. However, each of these embodiments has a preferred field of application «

An embodiment shown in FIG. 1 is preferred.

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form, because in such a design of the immovable and movable contacts 10, 11, 12, 13, the chamber gives the opportunity to obtain a maximum cut-off current «If the chamber is provided for load switch, it is better that in Pig. 4 embodiment to be used, because in the embodiment of the immovable contacts 10, 11 with the spiral winding 23, the heat dissipation from the contacts 10, 11 is improved to the housing 1. This allows a maximum henning current. to obtain the vacuum arc quenching chamber. The variant of the chamber shown in FIG. 5 gives the possibility of realizing the highest breaking capacity since, in the embodiment of both the fixed contacts 10, 11 and the movable contacts 12, 13 with the spiral windings 23, the vacuum arc extinguishing chamber Maximum current at the maximum voltage during power off switches off.

The use of the vacuum arc extinguishing chambers according to the invention in the switches makes it possible to reduce their number by about twice.

As a result of such reduction funds are thus saved by cost savings in terms of the chambers as well as by reducing costs at the switch by simplifying its construction

Claims (2)

-15- 24.6.1983 61 875/17 Experiement3an sprucn 1, vacuum arc extinguishing chamber, aie Zylindergehäuae of a vacuum-tight insulating material, the front side bounded by flanges, which lie in the direction of the housing axis corrugated pipes, and which is divided by a parallel to the flanges partition into two cavities, within which ever with the stationary wall connected immovable contact, accommodating a movable contact secured to a 3-way bar passing through the corrugated pipe of the corresponding flange and a system of screens, one of which is electrically coupled to the partition wall, characterized in that the immovable contacts (10, 11) of the two cavities (8, 9) are fixed directly to the partition (7), which is made of a non-magnetic conductive material and at least one contact (10, 11, 12, 13) of each cavity (8, 9) in Form of a current-conducting base plate (22), one at the periphery of the metallic base plate (22) and coaxial with the ser arranged spiral winding (23) and a coaxial with the metallic base plate (22) attached to the spiral winding (23) electrically coupled current-conducting plate (24) is designed whose height is smaller than that of the spiral winding (23), wherein the winding directions of the spiral turns (23) of these contacts (10, 11, 12, 13) coincide and the ratio of the distance between the surfaces of the movable contacts (12, 13) facing immobile contacts to the outer diameter of the contact (10, 11, 12, 13) Generating an arc between the -16- 24.6.1933 61 875/17 Contacts (10, 11, 12, 13) stabilizing magnetic axial field within limits of 0.05 to 1 moves 2, Yakuum-arc extinguisher according to item 1, characterized in that the ratio of the resistivity of the non-magnetic conductive material of the partition wall (7) to the specific copper resistance within limits of 1.5 to 100 moves » Hlerzu_J> ^ Pages Drawings