RU2457564C1 - High-voltage junction - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: high-voltage junction into a contaminated zone through the metal wall of a protective structure, in particular - an explosion-proof chamber, contains a metal body tightly installed inside the wall with two insulation elements tightly placed therein, an electric conductor passing through the elements. On the outer butt-ends the both insulation elements are consolidated to the body with the help of movable nuts. Grooves are made on the body seat surface for installation of sealing rings into them. A ceramic insulator is installed in the body between the insulation elements using spelter glass, the glass-soldered electric conductor passing through the insulator. The body, glass and ceramic materials are matched in terms of the thermal linear expansion coefficient.

EFFECT: invention enhances the device reliability.

6 cl, 1 dwg

Description

The invention relates to electrical engineering and can be used to enter electrical conductors into a contaminated area, in particular, used in an explosion-proof chamber (VZK).

One of the most important and critical operations during explosive experiments is to supply a special high-voltage pulse to drive the test object. At the same time, in the place of installation of the transition, the tightness of the IBD should not be violated both during and after the experiments.

A device is known for introducing electrical conductors into a contaminated zone, for example, into a nuclear reactor zone through a reinforced concrete wall with metal cladding [USSR copyright certificate No. 714944, MKI ⁵ Н01В 17/26, publ. 07/07/1991]. The device comprises a metal housing mounted in the wall with an insulating element located therein through which electrical conductors pass. At the ends of the body are flanges with connecting elements.

This device is compact and easy to manufacture.

However, the disadvantage of this device is that when mounting the flange to the housing, welding is used during mounting and dismounting. This reduces the reliability of protection in this area, since the presence of welds leads to the formation of stress concentrators and a change in the structure of the metal, reducing its strength characteristics, leading to cracking, which leads to a limitation of the scope, especially at the test site of the BLC.

Known transition high-voltage into the contaminated area through the metal wall of the protective structure, in particular explosion-proof chamber [RF patent No. 2322719, IPC ⁸ НВВ 17/26, publ. April 20, 2008]. This device is taken as a prototype, as the closest in technical essence to the claimed.

The device contains a metal housing hermetically mounted in the wall with two insulating elements located inside it, through which an electric conductor sealed inside them passes, both insulating elements are sealed from the external ends with the housing using movable nuts, grooves are made on the landing surface of the housing for installation in them o-rings.

This transition has a steel casing in which caprolon insulation elements are hermetically sealed with rubber o-rings. An electric conductor made of silver-plated brass and sealed with rubber o-rings also passes through the insulating elements.

The presence on the landing surface of the housing of the sealing rings provides ease of installation of the transition high-voltage in the OCC.

The disadvantage of this transition is the low reliability of the device due to the presence in it of elements made of rubber and caprolon, which are short-lived and age over time, are destroyed. In addition, the properties of the material of the seals is such that during assembly of the transition structure, their shape may be distorted, respectively, reliable contact is not provided over the entire surface of the connection of the insulating elements with the housing and the electrical conductor. This negatively affects the tightness, reduces the reliability of the junction design and can lead to a loss of tightness of the chamber during the explosion of environmentally hazardous objects in the cavity of the air-borne defense and after the experiment during long-term storage of the chamber.

The objective of the invention is to increase the reliability of the device.

The technical result, the invention is aimed at, is to maintain integrity and structural integrity during the explosion of environmentally hazardous objects in the cavity of the air-blast gun and after the experiment during long-term storage of the chamber (due to the reliable fastening of transition structure elements).

The indicated technical results are achieved by the fact that in the transition from the high-voltage to the contaminated area through the metal wall of the protective structure, in particular the explosion-proof chamber, which contains a metal enclosure sealed in the wall with two insulating elements sealed inside it, through which the electric conductor passes, from both ends insulating elements are sealed with the housing using movable nuts; grooves are made on the landing surface of the housing for installing the sealant in them According to the invention, a ceramic insulator is installed in the housing between the insulating elements, through which an electric conductor passes, a ceramic insulator is connected to the housing and the electrical conductor using solder glass, and the materials of the housing, glass and ceramics are matched according to the coefficient of linear thermal expansion.

The installation of a ceramic insulator in the casing and its connection with the casing and the electric conductor using the solder glass makes it possible to obtain a large length of the connection, providing high mechanical strength and tightness of the connection. The glass and ceramic case materials are matched by the coefficient of linear thermal expansion (CTE) so that if the CTE of the glass material is α ₁ , the CTE of ceramic is α ₂ , and the CTE of the case material is α ₃ , then the following dependence α ₃ ≥α ₂ ≥ α ₁ . As a result of the fulfillment of this condition, the glass is in a state of compression stress, which is necessary to maintain the integrity of the glass solder, thereby ensuring the tightness of the device and structural integrity during the explosion of environmentally hazardous objects in the cavity of the SCZ and after the experiment during long-term storage of the chamber.

The execution of the body of titanium provides its high strength under shock loads arising from the explosion in the explosive guns. The electric conductor is made of tantalum with elements of titanium, silver-plated brass, which ensures minimal transient electrical resistance when docking with the mating part and leads to minimal losses in the transmission of an electrical impulse. The insulating elements are made of polycarbonate, which has high mechanical and electrical insulation properties. The presence of o-rings on the landing surface of the high-voltage transition housing ensures its tightness in the wall of the explosion-proof chamber.

To further improve the reliability (impact resistance) of the structure during an explosion in an air-blast gun, the high-voltage transition is made up of two equivalent parts, fastened internally at the outer ends of the insulating elements, and outside the junction of the parts is fixed with a threaded element. In the event of the explosion of environmentally hazardous objects in the cavity of the IBD with the possible destruction of one of the parts of the transition (internal), the other part retains its tightness and structural integrity after testing and continues to be preserved during long-term storage of the IBD.

The presence in the claimed invention features that distinguish it from the prototype, allows us to consider it appropriate to the condition of "novelty."

New features (installation in the case between the insulating elements with the help of glass of a solder ceramic insulator through which the electric conductor sealed by glass passes, and the materials of the body, insulating elements, glass and ceramics are coordinated by the coefficient of linear thermal expansion) are not revealed in technical solutions for a similar purpose. On this basis, we can conclude that the claimed invention meets the condition of "inventive step".

The drawing shows the construction of the high voltage transition.

The device is as follows.

The high-voltage junction contains a titanium case 1, in which insulating elements 2, 3 are placed with a ceramic insulator 4 installed between them. The insulating elements 2, 3 are made of polycarbonate, which has high mechanical and insulating properties. Each insulating element 2, 3 is pressed from the outer end to the housing 1 by a movable nut 5. An electric conductor 6 passes through the insulating elements 2, 3 and the ceramic insulator 4. The conductor 6 made of tantalum is soldered into the ceramic insulator 4 using solder glass 7. The ceramic insulator 4 is connected to the housing 1 by means of solder glass 8. On the landing surface of the housing 1 there are grooves for installing the sealing rings 9 in them, which ensure the tightness of the high-voltage transition in the chamber wall (not shown).

The high-voltage junction is equipped with elements for installing other mates.

The assembly of the high voltage transition is as follows.

The insulator 4 is installed in the housing 1 using the solder glass 8, the electrical conductor 6 is placed in the insulator 4 using the solder glass 7. Next, insulating elements 2, 3 are installed in the housing 1. To ensure the solidity of the structure, compensation gaps between the ceramic insulator 4 and insulating elements 2 , 3 pour glue. A tip 10 is wound to an electrical conductor 6 with a collet 11 soldered onto it, having a guide surface for connecting with other mating parts (not shown). Each insulating element 4 from the external ends is pressed to the housing 1 by a movable nut 5. The ends of the high-voltage transition are protected by short-circuits 12.

To further improve the reliability (impact resistance) of the structure during an explosion in the air-blast gun, the high-voltage junction structure is duplicated by a similar part, fastening both parts inside with glue at the outer ends of the insulating elements 3, the joint is fixed from the outside with a nut (not shown). Thus, two independent sealing loops are formed, ensuring the tightness of the transition even when fragments of one of them are destroyed, the second loop remains tight.

The enterprise installed a high-voltage transition to the contaminated area through the metal wall of the protective structure, in particular an explosion-proof chamber. Tests were conducted, the results of which confirm the tightness of the IBD at the junction installation site both during and after the tests. The transition withstood shock loads of up to 5000 g at a test voltage of at least 16 kV, while maintaining integrity. The release of explosion products into the environment using known methods and means of registration was not recorded, which is especially important in the case of an explosion of environmentally hazardous objects.

So, the presented information indicates the fulfillment of the following set of conditions when using the claimed invention:

- ensuring increased reliability of the structure;

- ensuring the tightness of the IBD at the junction of the high-voltage both before the tests and after conducting them in the conditions of long-term storage of the IBD;

- for the claimed device in the form in which it is described in the claims, the possibility of its implementation using the means and methods described in the application and known prior to the priority date is confirmed.

Therefore, the claimed invention meets the condition of "industrial applicability".

Claims (6)

1. The high-voltage transition to the contaminated area through the metal wall of the protective structure, in particular the explosion-proof chamber, containing a metal enclosure sealed in the wall with two insulating elements sealed inside it through which the electrical conductor passes, from the outer ends both insulating elements are sealed with the enclosure using movable nuts, on the landing surface of the housing grooves are made for installing sealing rings in them, characterized in that in the housing between the insulator onnymi elements by means of glass solder is a ceramic insulator, which passes through the glass sealed electrical conductor and casing materials, glass ceramics and matched in coefficient of linear thermal expansion. 2. The high-voltage transition according to claim 1, characterized in that the housing is made of titanium. 3. The high-voltage transition according to claim 1, characterized in that the electrical conductor is made of tantalum with elements of titanium, silver-plated brass. 4. The high-voltage transition according to claim 1, characterized in that the insulating elements are made of polycarbonate. 5. The high-voltage transition according to claim 1, characterized in that it is equipped with elements for connecting other mating parts. 6. The high-voltage transition according to claims 1-5, characterized in that it is made up of two equal parts with a junction inside the outer ends of the insulating elements, and on the outside the junction of the parts is fixed with a threaded element.