RU2687287C1 - Multi-contact tight transition - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention is intended for connection of electrical conductors of cable network, including band wires separated by tight wall, through tight transition at limitation on volume of installation place, weight and at high degree of tightness. Multi-contact tight transition consists of thin-walled metal housing (1) of rectangular shape, insulator (2) from cured rubber mixture of isoprene rubber of hot curing, contact group of contacts (3) with holes and cuts on both sides for soldering with different melting point.

EFFECT: technical result is maintaining a high degree of tightness of multi-contact sealed junction over a long period of time.

1 cl, 1 dwg

Description

The invention relates to electrical engineering and is intended to connect the electrical conductors of the cable network, including ribbon wires separated by a sealed wall, through a sealed junction with limited installation space, weight and a high degree of tightness.

Known sealed connectors and transitions:

1. Patent RU 2561608, Н01B 17/26. Cable entry for hermetic passage of electrical circuits / Selivanov AV et al. (03/27/2014) Publ. 08.27.2015 Bul No. 24;

2. Connectors of the EPG SKNTS.5523.142TU. - 2. Common industrial connectors and bushing insulators // Access mode: http://zapadpribor.com/products/epg-prokhodniki/datasheet/epg-prokhodniki-to.pdf; http://zapadpribor.com/epg-prokhodniki/;

3. Patent US 14106011, H01R 13/52, H01R 43/24, H01R 13/521. Sealed electrical connector assembly / Oscar Max Sittner et al. (12/13/2013) Publ. 06/18/2015;

4. Patent RU 2538093, H01B 17/26. Germovvod / Chumakov A.E. et al. (08/01/2013) Publ. 01/10/2015. Bul №1;

5. Patent RU 2322718, HB 17/26. Germovvod / Barnashov S.A. et al. (03.10.2006) Publ. 04/20/2008 Bul No. 11;

6. Patent RU 2532412, HB 17/00. Low-frequency transition / Stepanov AS et al. (09.01.2013) Publ. 10.11.2014. Bul No. 31;

7. 280-009 MIL-DTL-24308/9 Type Hermetic D-Subminiature Pin-to-Pin Feedthrough. - GLENAIR, INC // Access mode: http://www.radiant.su/other/glenair/eng/hermetic_comectors/pdf/j/280_009.pdf;

8. Patent RU 2433494, HB 17/26. A method of manufacturing metal-ceramic small-sized electrical sealed output / Valkov AK et al. (03.08.2010) Publ. 10.11.2011. Bul No. 31;

9. Patent RU 2549202, HB 17/02. Electrical insulator with reinforcing rods / Dziubin A.S. (02.26.2013) Publ. 04/20/2015. Bul №1;

10. Patent RU 2453008 IPC H01B 17/26. Silicone insulator and method of its manufacture / Kim J.M. et al. (03/07/2009) Publ. 10.06.2012. Bul №16.

Cable entry for hermetic passage of electrical circuits [1.] contains a metal cylindrical body, made of a single structure with an internal thrust plate, in which there are openings for electrical conductors, and conductive contacts between themselves and the body are insulated by filling with a polymer compound.

The disadvantage of this cable entry is that the compound as a sealing element cannot provide a high degree of tightness due to its possible porosity and aging. With a reusable rapid temperature cycling at different temperature coefficients of linear expansion of the compound and the housing, the compound can be peeled off from the housing and loss of tightness can occur. The disadvantage is the need to introduce additional structural elements for fixing the supplied conductors to the conductive contacts.

The EPG connector [2.] contains a metal cylindrical body, made of a single structure with an internal thrust plate in which there are openings for electrical contacts that allow soldering on both sides. Contacts between themselves and the housing are isolated by filling with a glass insulator.

The disadvantage of this connector is the need to introduce additional structural elements for fixing the flowed conductors to the conductive contacts and the connector itself, as well as the fragility of the glass insulator, which must be placed in the case with more durable walls to prevent cracking and damage to the insulator.

Sealed electrical connector [3.] includes a connector housing, partially or fully located in a pressure vessel, designed to introduce electrical conductors to / from a pressure vessel. A plurality of elongated conductive pins are located within the connector body, where each pin has an end intended for high pressure and an end intended for low pressure; polymeric resin located inside the connector body, formed into the body surrounding the high pressure ends of the pins to form a seal that is impermeable to liquids and gases between the polymer resin, the conductive pins and the housing.

The disadvantage of this hermetic connector is a housing configured to provide electrically conductive paths that increases the weight of the structure. The disadvantage is also sealing due to polymer resin, which cannot provide a high degree of tightness due to insufficient adhesion and wettability with an incorrect percentage ratio of resin and hardener, especially with a complex configuration of the filled volume and with its small size. With a reusable rapid cyclical temperature change due to different temperature coefficients of linear expansion of the resin and the housing, the compound can be peeled off from the housing and loss of tightness can occur, and this can also occur during housing deformation.

Germovvoda [4., 5.] consist of a contact, an insulator and a sleeve. The material of the insulator is ceramics, and the connection of the component parts of the pressure seal occurs through active copper-titanium solder. The choice of contact materials of the insulator and the sleeve is carried out taking into account temperature coefficients of linear expansion.

Sealed transitions [6., 7.] with a high degree of tightness contain hermetically mounted electrical conductors in the form of conductive pins in the wall of a metal case using a glass insulator. The choice of contact materials, the insulator and the housing is based on the temperature coefficients of linear expansion.

Designs [4., 5., 6., 7.] provide a high degree of tightness, but have drawbacks associated with restrictions on the choice of housing material and contacts, high-tech and energy-intensive processes of manufacturing and soldering insulators. Sealed transitions [6., 7.] have the disadvantage associated with the need for supplying conductors through sockets, which leads to the introduction of additional elements in the design and, consequently, to an increase in overall dimensions. Sealed transitions [4., 5.] have disadvantages associated with the brittleness of the insulator and require placement in strong housings that are resistant to deformation, which leads to an increase in mass.

In the manufacture of metal-ceramic compact electrical pressure seal by the method [8.] in the assembly of pre-prepared elements - insulator, electrical leads and auxiliary materials - before installing electrical leads on an insulator, the surface of a pre-prepared ceramic disc as an insulator, which has through holes for electrical leads through the number of the latter, is activated in a PdCh solution, is chemically coated with a layer of copper, then electroplated Anosylate lead coating followed by removal of the coating layer by etching along a predetermined contour and finally installing electrical leads to the holes of the ceramic disc using soldering of the electrical leads with SnPb solder on the ceramic disc. The method has the same drawbacks as the sealed inlets [4., 5.], with the exception of the use of energy-intensive equipment.

An electric insulator with reinforcing rods [9.] contains an insulating body made using an elastic dielectric material, at least one fixing unit and reinforcing rods partially located in the insulating body, with part of the reinforcing rods being mechanically interconnected. In this case, the reinforcing rods and / or at least one fastening assembly and / or at least one connecting element are made using a conductive material. In this insulator, the elastic dielectric material is silicone rubber, ethylene-propylene rubber or polyurethane.

Silicone insulator and method of its manufacture [10.] contains a conductor and a bearing sleeve with a metal flange, covering the conductor with the formation of a cavity completely filled with a layer of insulation made of silicone rubber, which is used as a vulcanized polymer compound based on liquid synthetic rubbers, the oligomers of which contain end functional groups.

The disadvantages of insulators [9., 10.] are the large dimensions and the presence of a single conductive contact, designed to work in high-voltage lines.

Common disadvantages of silicone rubber insulators are the high price of the material, the lack of adhesion to metals to achieve a high degree of tightness, the lack of adhesion of compounds of wide application. Technological operations for rolling and holding rubber have a long time interval. To fill small volumes of complex configuration due to the viscosity of the silicone rubber mixture requires the creation of high pressure.

Common disadvantages of ethylene-propylene rubber insulators are the lack of adhesion to metals to achieve a high degree of tightness.

The prototype of the proposed hermetic junction is a device for a tight input of conductive elements [11. Patent for PM RU 177141, H02G 3/22. A device for hermetic insertion of conductive elements / Kopekin A.N. et al. (11/14/2017) Publ. 12.02.2018. Bul No. 5.], Comprising a housing made with a cavity filled with compound and a protrusion, characterized in that the cavity is made pass-through. Along the perimeter of the body there is a closed groove in which the sealing ring is installed. Inside the body there is a step, on which a rubber seal is installed, which is fixed by a clamp attached to the case. Through-holes are made in the rubber seal through which the conductive elements pass through the housing.

The disadvantage of this device is the sealing due to the elastic deformation of the rubber seal and compound. Given the shape of the sealing element, the calculation of the compression ratio and the deformation coefficient for each contact is impossible. Without these factors, it is impossible to guarantee a high degree of tightness over a long time. The disadvantage is also the presence of additional elements in the form of a clamp and fasteners. The conductive elements projecting beyond the body increase the overall dimensions and weight of the device due to the introduction of additional structural elements for fixing the supplied conductors.

The task for which the invention is directed, is to create a simple to manufacture, easy, compact, multi-contact hermetic junction, providing a high degree of tightness over a long period of time.

The proposed multi-contact hermetic junction consists of a thin-walled metal case with an insulator hermetically fixed in it, in which electrically conductive contacts are sealed at an equidistant distance. The contacts are recessed relative to the ends of the case and have holes on both sides and sections for soldering wires, rotated 90 ° relative to the long wall of the case. An insulator made of rubber from hot-cure isoprene rubber has a height less than the height of the contact.

The device is illustrated in the drawing. FIG. 1 shows a multi-contact hermetic junction with a rectangular thin-walled metal body 1 and an insulator 2 made of vulcanized rubber compound from hot-vulcanized isoprene rubber, with a contact group of contacts 3 with holes and cuts on both sides for soldering with solder with different melting points.

Insulator 2 made of rubber from isoprene rubber of hot vulcanization, possessing good adhesion to metal (not less than 12 kgf / cm ² ) and selected with regard to electrical insulating properties, is formed by hot vulcanization directly in the housing 1 with the contacts 3 installed in the mold for a given shape . In this case, the surfaces of the housing 1 and the contacts 3, which are to be fixed by hot vulcanization rubber from isoprene rubber, are preliminarily prepared to ensure a high-strength connection. Monolithic body 1 of a multi-contact hermetic junction is made with thin walls in the area of the insulator and flange, which allows to reduce weight, and due to the elasticity of rubber from isoprene rubber of hot vulcanization and its good adhesion to metal, possible deformations of the body and cyclic temperature changes will not lead to loss of tightness. Thickening of the body in the area of the flange is necessary to install a transition through the rubber seal to maintain tightness at the place of installation. Contacts 3 with holes and sections for soldering, recessed relative to the ends of the housing 1, allow the wires to be soldered inside the housing on both sides at different melting points of the solder, followed by fixing the wires in the housing by pouring compound. Sections on the contacts are rotated 90 ° relative to the long wall of the housing to facilitate the soldering process. Fixing the wires with a compound inside the enclosure allows you to protect the soldering point and ensure the fixing of the wires without introducing additional fasteners and keep the minimum overall dimensions.

The tightness of the multi-contact hermetic junction for a long time of service is ensured due to the absence of compression and deformation of the hot-vulcanized rubber insulator made of isoprene rubber and does not require accelerated climatic tests.

The elasticity, fluidity and thermal conductivity in the vulcanization of rubber from isoprene rubber of hot vulcanization allows the manufacture of insulators of various configurations with minimal volumes. To supply a rubber mixture of hot vulcanized isoprene rubber to the mold does not require much pressure and the use of special expensive equipment.

The advantage of this multi-junction hermetic junction consists in a simpler, than analogous, design, since The contacts are vulcanized directly with hot-vulcanized isoprene rubber compound without intermediate details. Therefore, the transition is more simple and economical to manufacture.

The multi-contact hermetic junction can be made in both round and rectangular versions without an isolator.

The multi-contact hermetic junction is reliable in ensuring the tightness of the adjoining cavities of the product at a pressure of at least 29.4 × 10 ⁴ Pa (3 kgf / cm ² ) with a degree of tightness of at least 1 × 10 ^-3 μm RT. v / s

The technical result is the preservation of a high degree of tightness of the multi-contact hermetic junction over a long period of time.

The technical characteristics of the proposed multi-contact hermetic junction are improved compared with the prototype and analogues in terms of weight reduction, overall dimensions with minimal production costs, characterized by equipment and energy intensity.

A multi-contact hermetic junction can be used in products from various industries where it is necessary to conduct signal and low-current electrical wires from one volume to another, between which there is a difference in gas or water pressure, if there are overall restrictions on the installation and fastening of supplied conductors and tightness requirements for a long time in normal climatic conditions, at high and low ambient temperatures, depending on the type of rubber used. For example, it can be sealed enclosures of aircraft, surface and underwater vehicles, premises with predetermined climatic conditions, and capacities of test chambers.

Sources taken into account

1. Patent RU 2561608, Н01B 17/26. Cable entry for hermetic passage of electrical circuits / Selivanov AV et al. (03/27/2014). Publ. 08.27.2015 Bul №24.

2. Connectors of the EPG SKNTS.5523.142TU. - 2. Common industrial connectors and bushing insulators // Access mode: http://zapadpribor.com/products/epg-prokhodniki/datasheet/epg-prokhodniki-to.pdf; http://zapadpribor.com/epg-prokhodniki/.

3. Patent US 14106011, H01R 13/52, H01R 43/24, H01R 13/521. Sealed electrical connector assembly / Oscar Max Sittner et al. (12/13/2013). Publ. 06/18/2015.

4. Patent RU 2538093, H01B 17/26. Germovvod / Chumakov A.E. et al. (01.08.2013). Publ. 01/10/2015. Bul №1.

5. Patent RU 2322718, HB 17/26. Germovvod / Barnashov S.A. et al. (03.10.2006). Publ. 04/20/2008 Bul №11.

6. Patent RU 2532412, HB 17/00. Low-frequency transition / Stepanov AS et al. (01/09/2013). Publ. 10.11.2014. Bul №31.

7.280-009 MIL-DTL-24308/9 Type Hermetic D-Subminiature Pin-to-Pin Feedthrough. - GLENAIR, INC // Access mode: http://www.radiant.su/other/glenair/eng/hermetic_connectors/pdf/j/280_009.pdf.

8. Patent RU 2433494, H01B 17/26. A method of manufacturing metal-ceramic small-sized electrical sealed output / Valkov AK et al. (03.08.2010). Publ. 10.11.2011. Bul №31.

9. Patent RU 2549202, HB 17/02. Electrical insulator with reinforcing rods / Dziubin A.S. (02.26.2013). Publ. 04/20/2015. Bul №1.

10. Patent RU 2453008 IPC H01B 17/26. Silicone insulator and method of its manufacture / Kim J.M. et al. (03/07/2009). Publ. 10.06.2012. Bul №16.

11. The patent for PM RU 177141, H02G 3/22. A device for hermetic insertion of conductive elements / Kopekin A.N. et al. (11/14/2017). Publ. 12.02.2018. Bul №5.

Claims (1)

A multi-contact hermetic junction consisting of a thin-walled metal case with an insulator hermetically fixed in it, in which electrically conductive contacts are sealed at an equidistant distance, characterized in that the contacts are recessed relative to the ends of the case and have openings on both sides and solder sections for 90 ° relative to the long wall of the housing, and the insulator, made of rubber from isoprene rubber of hot vulcanization, has a height less than the height of the contact.

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