RU2710028C1 - Through electrical connector - Google Patents

Abstract

FIELD: electricity.SUBSTANCE: invention relates to a through electrical connector and can be used in electrical connectors and sealed leads in power plants operating under vacuum or in aggressive media, at high temperatures, while providing the required air-tightness. Connector comprises housing (1), in which ceramic insulator (2) is installed, which is made with through holes. Contact pins (4) are inserted into hole and fixed by glass blowing. Contact pins (4) along the whole length are made with square cross section. Housing (1) and pins (4) are made from high-chromium steel. Gap between ceramic insulator (2) and housing 1 can be sealed.EFFECT: increased conductivity, increased uniformity of glass finder distribution, increased accuracy of pin alignment with simplification of installation process, increased resistance to increased temperatures and increased pressure, increased quality of welded joint at simplification of welding process; this allows solving the problem of maintaining electroconductivity and tightness at high temperature and pressure, simultaneously reducing overall dimensions and simplifying the design.7 cl, 3 dwg

Description

Technical field

This technical solution relates to energy and electronics, in particular to switching electrical devices, and can be used in electrical connectors and pressure glands in power plants operating in vacuum or in aggressive environments, while at high temperatures providing the required tightness.

State of the art

A device is known for which RF patent No. 52823 "Hollow porcelain insulator through passage" was received IPC: Class 21c, priority 10.03.03.1937, published. 03/31/1938, author: Blinov N.K. (RU).

A hollow passage porcelain insulator with a current-carrying rod of rectangular cross section, characterized in that the cap of the insulator is equipped with a tide for fastening the current-carrying rod with a transverse bolt.

The disadvantage of this device is the difficulty in manufacturing a ceramic insulator, not tightness, large dimensions, etc. It should also be noted that during the installation of the insulator, the tire may shift. It is possible that this design does not have stringent requirements for centering the tire.

A device is known for which RF patent No. 2231878 was obtained “Heat-resistant sealed heat-resistant electrical connector” IPC: H01R 13/52; Priority January 27, 2004, published. 06/27/2004, authors: Sorokin A.N. (RU), Sobko S.A. (RU), Drovosekov S.P. (RU).

The connector contains a sealed plug and an unpressurized socket, each of which consists of a housing, an insulator and metal contacts located in the holes of the insulator, while the sealed plug contains metal cuffs located between the surfaces of the pin contacts and the insulator and hermetically connected to them. Each node for sealing the pin contact and the cuff is located outside the installation zone of the insulator from the side opposite to the location of the outlet and contains an additional sleeve covering the pin contact and the end part of the cuff having a conical shape.

The disadvantages of the analogue is the significant diametrical size of the plug body. This is due to the fact that when installing the plug in the object of use, there is a likelihood of a leak in the glass junction due to an increase in internal stresses caused by the thermal deformation cycle. It is not possible to reduce the diameter of the sleeve housing to the required dimensions due to the destruction of glass junction. In addition, soldering pins, bushings, insulators and housings is a complex and costly process. You can also note the difficulty in centering the pins.

As a prototype, the patent of the Russian Federation No. 2219623 “Heat-resistant sealed plug” was chosen IPC: H01R 13/40; priority August 27, 2001, published December 20, 2003, authors: Derishev S.A., Drovosekov S.P., Kitaev V.N., Pankratov G.A., Popov I.V.

The device comprises a housing in which a ceramic insulator with contact pins sealed with glass is installed. Each contact pin is equipped with a sleeve connected to the pin with a plastic metal solder, while the height of the sleeve is not less than the height of the insulator, and the materials of the sleeve, case, glass and ceramic are matched by the coefficient of linear thermal expansion.

The disadvantages of this device include large dimensions, a complex, multicomponent design, difficulty in centering contact current-carrying pins in the insulator hole, insufficiently high operating temperature, and high electrical resistance at operating temperatures.

Disclosure of invention

The task to be solved by the claimed invention is directed is the development of a straight through electrical connector ensuring the conservation of electrical conductivity and tightness at elevated temperature and pressure, while reducing overall dimensions, and simplifying the design.

The technical result consists in increasing the conductivity, increasing the uniformity of the distribution of glass solder, increasing the accuracy of centering the pins while simplifying the installation process, increasing the resistance to elevated temperatures and high pressure, increasing the quality of the welded joint while simplifying the welding process.

The technical result of the device is achieved by the fact that the passage-through electrical connector comprising a housing in which a ceramic insulator is installed with contact pins sealed with glass, while the materials of the housing, glass solder and ceramic insulator are aligned according to the KLTR, according to the invention, the contact pins are made with a cross section in the form of a polygon . The material of the pins is approved according to the KLTR with the materials of the body, glass solder and ceramic insulator.

The set of essential features provides a technical result - an increase in conductivity, an increase in the uniformity of the distribution of glass solder, an increase in the accuracy of centering of the pins while simplifying the installation process, an increase in resistance to elevated temperatures and high pressure, an increase in the quality of the welded joint while simplifying the welding process. This allows us to solve the problem of maintaining electrical conductivity and tightness at elevated temperatures and pressures, while reducing overall dimensions, and simplifying the design.

The body and contact pins can be made of high-chromium steel type 15X28. Contact pins can be made of platinum group material, and the housing is made of high-chromium steel type 15X28. It is also possible that the SiO ₂ -M ₅ O-BaO-Al ₂ O ₃ system will be used as glass solder. It is also possible that the ceramic insulator may be made of forsterite ceramic.

This makes it possible to coordinate the material of the contact pins, the housing, the glass solder and the ceramic insulator according to the KLTR and to solve the problem of maintaining electrical conductivity and tightness at elevated temperatures and pressures, as well as reducing overall dimensions and simplifying the design.

It is possible to make contact pins along the entire length with a cross-section in the form of a square. This provides a technical result - an increase in the uniformity of the distribution of glass solder, an increase in the accuracy of centering the pins while simplifying the installation process. That allows us to solve the problem of maintaining tightness, improving the quality of the welded joint while simplifying the welding process.

The gap between the ceramic insulator and the housing can be sealed. This allows us to solve the problem of maintaining tightness at elevated temperatures and pressures.

The achieved result is ensured not only by the presence of known distinctive features, but also depends on their interaction with other essential features of the claimed device. This allows the device to expand its functionality and provide a solution to the problem of reducing overall dimensions, and simplifying the design.

The expanded function provided by the well-known distinguishing features, and obtaining an unexpected result from the use of these features in combination with other features, indicates the conformity of the proposed technical solution with the criterion of “inventive step”.

Brief Description of the Drawings

In FIG. 1 shows the appearance of an electrical connector.

In FIG. 2 shows the location of the contact pins in the insulator.

In FIG. Figure 3 shows the contact pin in the hole of the insulator, fixed with a glass seal.

Embodiments of the invention

As shown in FIG. 1 and FIG. 2, the electrical inlet connector comprises a housing 1 in which an insulator 2 of forsterite ceramic is installed. The insulator 2 is made with through holes 3. Contact pins 4 are inserted into the holes 3, which are fastened with glass solder 5. The housing 1 and the pins 4 are made of high-chromium steel type 15X28.

As a solder, a glass solder having a SiO ₂ —M ₅ O — BaO — Al ₂ O ₃ system was selected. The main criterion for choosing the materials for the components of the electrical connector was their close in value CTE. The CTE of steel and platinum in the temperature range 200-1200 ° С is 10.2⋅10 ^-6 1 / ° С and 9.5⋅10 ^-6 1 / ° С, respectively, the CTE of glass solder is 9.7⋅10 ^-6 1 / ° С, forsterite ceramics 9.6⋅10 ^-6 1 / ° С.

This allows you to get the technical result of increasing resistance to elevated temperatures and high pressure, which allows us to solve the problem of tightness at elevated temperatures and pressures. The connector is designed for use with operating temperature parameters at 1000 ° C and a pressure of 1 MPa.

Install the pins 4 in the holes 3 of the ceramic insulator 2. In this case, the symmetry axes of the holes 3 and pin 4 occur without additional operations and devices, automatically. The centering of the pins 4 in the holes 3. The geometric parameters of each hole 3 of the insulator 2 and each profile of the pin 4 are selected so that the hole 3 describes the profile of the pin 4 (Fig. 3).

This simplifies the assembly process and does not require additional equipment. This means that it increases the accuracy of centering of the pins 4 while simplifying the process of their installation.

After installing the pins 4 in the holes 3 between them four identical through cavities 6 are formed, which are filled with powdery glass solder 5.

The shape of the pins with a circular cross section is known, in which the surface of the hole and the pin forming the cavity can touch and interfere with the penetration of the glass solder into the cavity. It is proposed to make pins 4 with a cross section in the form of a polygon, for example, a square, and holes 3 with a cross section in the form of a circle. This allows the surfaces of the pin 4 and the hole 3 not to touch over the entire length of the pin 4, forming a cavity 6 continuous in length (Fig. 3).

Thus, the uniform distribution of the glass solder 5 in the cavities 6 in the transverse and longitudinal directions, as shown in FIG. 3. In addition, in the process of soldering, the glass solder 5 is melted and its uniform distribution is provided throughout the volume of the cavity 6. This allows us to solve the problem of maintaining tightness at elevated temperatures and pressures.

It has also been experimentally proved that the presence of faces on pin 4 with its square section allows the use of one of the faces as a contact area for welding. Compared with pins with a circular cross-section, this allows to simplify the process of welding elements (wires, cables, thermocouples, etc.) with pins 4 and to increase the quality of the welded joint.

Glass soldering of 5 pins 4 is carried out at a temperature of 1300 ° C in an inert gas environment. The resulting assembly is installed in the housing 1.

To solve the problem of reducing the overall dimensions of the connector, and simplifying the design, the materials of the housing 1, contact pins 4 of insulator 2 and glass solder 5 were optimally selected according to KLTR. In addition, the shape of contact pins 4 was proposed in combination with the shape of the holes 3 in insulator 2. This allowed to exclude the bushings and copper solder described in the prototype, add another contact pin, while reducing dimensions, simplifying the design and simplifying the assembly of the connector while maintaining electrical conductivity and tightness when increased x temperature and pressure.

When conducting analysis of the prior art, including a search by patent and scientific and technical sources of information, and identifying sources containing information about analogues of the claimed invention, analogues were not found that are characterized by a combination of features that are identical to all the essential features of this invention. This confirms that the claimed invention meets the requirement of "novelty."

Industrial applicability

The proposed invention can be used for the manufacture of electrical connectors in aviation and space technology, in nuclear energy, etc. Where increased demands are made on maintaining tightness and electrical performance when operating at elevated temperatures. Tests of the proposed version of the connector were carried out on existing equipment using existing materials. This proves its performance and confirms industrial applicability.

Claims (7)

1. A straight through electrical connector comprising a housing in which a ceramic insulator is installed with contact pins sealed with glass, the materials of the housing, glass solder and ceramic insulator being coordinated according to KLTR, characterized in that the contact pins are made with a cross section in the form of a polygon, and the material of the pins according to KLTR with materials of the case, glass solder and ceramic insulator. 2. A straight through electrical connector according to claim 1, characterized in that the housing and contact pins are made of high-chromium steel. 3. A straight through electrical connector according to claim 1, characterized in that the casing is made of high-chromium steel and the pins are made of platinum group material. 4. A straight through electrical connector according to claim 1, characterized in that the SiO ₂ -M ₅ O-BaO-Al ₂ O ₃ system is used as a glass solder. 5. The straight through electrical connector according to claim 1, characterized in that forsterite ceramic is used as the material of the ceramic insulator. 6. The straight through electrical connector according to claim 1, characterized in that the contact pins along the entire length are made with a cross section in the form of a square. 7. The straight through electrical connector according to claim 1, characterized in that the gap between the ceramic insulator and the housing is sealed.

Images