RU168976U1 - SELF-CENTERING ELECTRICAL CONNECTOR - Google Patents

Abstract

The utility model relates to electrical engineering, in particular to linear connectors, and is intended for use in power electrical installations. EFFECT: increased reliability of connector docking. The connector contains a socket and male parts, designed for installation on stationary and tear-off objects, respectively. The outlet part has a hollow stationary body, in the cavity of which a movable body is installed having a centering pin, designed for installation in the axial centering hole of the fork of the fork. The movable housing from the front end part has deaf radial and axial holes arranged uniformly around the circumference, in which one of the ends of the compression springs is located, the other ends of which interact with the stationary housing. On the side of the rear end part of the movable housing, a spherical element is mounted with a possibility of movement in the radial direction, the spherical surface of which is associated with the spherical surface of the recess made in the movable housing. The top of the spherical surface of the recess is aligned with the axis of the centering pin. 2 ill.

Description

The utility model relates to electrical engineering, in particular to linear connectors, facilitating the connection and disconnection of contacts, and is intended for use in power electrical installations for various purposes, where multiple mechanical docking and undocking of the mating parts of the connection (connector) is required, one of which is installed on a stationary object , and the other on a tear-off object, shifted during the docking process.

Known self-centering electrical connector (USSR author's certificate No. 1064360, H01R 13/62, publ. 12/30/1983), which contains the plug and socket parts, equipped with mounting nodes and, accordingly, a centering pin and a centering socket. Each mounting unit contains a movable casing, covered with a gap by a glass (fixed casing) with a central hole in the bottom, two rings interacting with each other with conical and spherical surfaces, elastic and guide elements. A ring with a conical surface is located on the outer surface of the bottom of the glass, and a ring with a spherical surface is located outside the glass on the rear of the movable body. The guide elements are made in the bottom of the glass in the form of blind axial holes in which elastic elements, such as springs, are placed, while some ends of the elastic elements are located in the guide elements, while others interact with the body. The known design of the connector allows you to compensate for angular displacements in conjunction with radial and axial longitudinal displacements, as well as each of these installation errors separately. However, this design may not be applicable in power electrical installations due to the excess weight and the number of parts of the mounting nodes of the plug and socket parts. In addition, in the known invention, both the male part and the female part are movable during the docking process, therefore, when self-centering the male and female parts, strict compensation of linear radial displacement is not provided, as well as there are no elements that can absorb significant longitudinal axial forces.

The closest technical solution in technical essence to the claimed utility model is an electrical connector (connector) (USSR copyright certificate No. 1112450, H01R 13/62, publ. 07.09.1984). The electrical connector consists of plug and socket parts. The socket part is mounted on the tear-off object and contains a contact in the form of a socket. The male part is mounted on a stationary object and contains a fixed hollow body and a movable body connected by an annular compensator for displacements with an insulator and a contact made in the form of a contact pin that simultaneously performs a centering function. An annular groove is made on the inner surface of the fixed housing, in which a movement compensator and a movable housing are located. The displacement compensator is made in the form of a spring made of a metal strip curved in a wave-like cross section and allows you to compensate for linear radial displacements, and the insulator is made of elastic material, such as rubber, located in the annular gap between the movable body and the pin, and allows you to compensate for axial displacements. However, one of the disadvantages of the known device is the unreliability of work in power electrical installations, since the elastic element is made of insulating material, which at high temperatures loses its elastic properties, which during operation does not allow for self-centering of the plug and socket parts. In addition, in the known device during self-centering, effective compensation of significant longitudinal efforts of the socket and plug parts during closure and opening cannot be provided, which also does not allow for self-centering when docking the plug and socket parts of power electrical installations.

The technical result, which the proposed utility model is aimed at, is to increase the reliability of the docking of the socket and plug parts located on the stationary and tear-off objects of the electrical connector of power electrical installations.

The indicated technical result is achieved in that the electrical connector comprises a male part intended for installation on a tear-off object and having a plug with an axial centering hole, and a female part intended for installation on a stationary object and having a hollow stationary body in the cavity of which a movable body is mounted. The movable housing has a centering pin designed for installation in the centering hole of the plug. The movable housing from the front end part has deaf radial and axial holes arranged uniformly around the circumference. In the radial and axial holes are located one of the ends of the compression springs, and the other ends of the compression springs are installed with the possibility of interaction with the stationary body. A spherical element is mounted between the movable housing and the stationary housing with the possibility of movement in the radial direction, the spherical surface of which is mated with the spherical surface of the recess made in the rear end part of the movable housing. The top of the spherical surface of the recess is located on the same axis (aligned) with the axis of the centering pin.

Due to the implementation in the movable housing of the socket part of the centering pin, designed for installation in the centering hole of the plug, while simultaneously placing between the movable housing and the stationary housing of a spherical element that can be moved in the radial direction and mated with its spherical surface with a spherical surface of the recess made in the rear end parts of the movable body, while the top of the spherical surface of the recess should be on the same axis as the price with the help of a locating pin, an improvement in self-centering and compensation of the longitudinal movements of the outlet part is achieved. Due to the implementation of instead of a spring-curved wave-like cross-sectional spring, the blind radial holes are arranged uniformly around the circumference in the movable housing from the front end part, in which one of the ends of the compression springs is located, the other ends of which can interact with the stationary housing, effective compensation of linear movements of the movable the housing of the outlet. Due to the implementation of instead of an insulator made of rubber, blind axial holes in the movable housing from the front end part, in which one of the ends of the compression springs are located, the other ends of which can interact with the stationary housing, the axial movements are compensated and the dependence of the electrical connector on contact and ambient temperatures. Thanks to this design, the proposed device provides reliable docking of the electrical connector.

In FIG. 1 shows the electrical connector in the docked position, FIG. 2 - electrical connector in undocked position.

The electrical connector includes a receptacle that is mounted on a stationary object, and a male part that is installed on a tear-off object. The socket part has a contact made, for example, in the form of a contact sleeve 1, rigidly fixed in a conductive movable housing 2, made in the form of a glass. The fork part has a contact made in the form of a fork 3, in which there is an axial centering hole 4. The movable housing 2 is mounted in the cavity of the stationary housing 5. In the movable housing 2, blind radial holes are made around the circumference from the front end part (from the fork part). 6 and blind axial holes 7. In the radial holes 6 are located one of the ends of the compression springs 8, and in the axial holes 7 one of the ends of the compression springs 9, the other ends of the springs 8 and 9 are able to interact with the stationary housing 5. The number of radial holes 6 and axial holes 7 for the installation of springs 8 and 9 is determined by calculation, depending on the required mobility, the mass of the movable housing 2 and the contact sleeve 1, as well as the characteristics of the springs 8 and 9. The movable housing 2 has a central part made in the form the centering pin 10 so that in the docked position of the electrical connector, the centering pin 10 and the centering hole 4 of the plug 3 are located on the same axis (were aligned). Between the movable housing 2 and the stationary housing 5 from the side of the rear end part of the movable housing 2 is installed a spherical element 11, for example, made in the form of a washer. To ensure the possibility of movement (mobility) of the element 11 in the radial direction in the considered example, a groove 12 is made in the stationary body 5, into which the element 11 is mounted. The spherical surface 13 of the element 11 is mated with the spherical surface 14 of the recess 15 made in the rear rear part of the movable body 2 The top of the spherical surface 14 of the recess 15 is located on the same axis with the axis of the centering pin 10. Thus, in the docked position of the electrical connector of the top of the spherical surfaces 13 and 14 are located on the same axis with the axis of the centering pin 10. To reduce the coefficient of friction when articulating the centering hole 4 of the yoke 3 with the centering pin 10, a cap 16 can be installed on the pin 10, made of a material having a low coefficient of friction, and fixed with a screw 17.

Self-centering electrical connector operates as follows.

The socket and plug parts are displaced one before the other, due to manufacturing, assembly, and installation errors at different sites.

When docking (jointing) the socket part and the male part, the plug 3 enters the contact sleeve 1 of the movable housing 2. With the further advancement of the plug 3, the centering pin 10 enters the centering hole 4, goes deeper and helps center the movable body 2 relative to the plug 3. In this case, the movable the housing 2 is supported through its spherical surface 14 of the recess 15 on the spherical surface 13 of the element 11 and then on the stationary body 5, while due to the mobility of the spherical element 11 in the radial direction and the limits the basics of 12, the axes of the spherical surfaces 13 and 14 are aligned, and the movable housing 2 is in a stable position, and the axis of the centering pin 10 of the movable housing 2 is aligned with the axis of the centering hole of the fork 3. At the same time, the springs 8 are deformed, located around the circumference in the radial holes 6 , and springs 9 located around the circumference in the axial holes 7, while on one side of the movable housing 2, the springs 8 and 9 are compressed, and on the other hand weaken, due to such deformation of the springs 8 and 9, ekosov and self-centering of the movable body 2 with respect to the plug 3.

When undocking the electrical connector, the plug 3 exits the movable housing 2, while the radial springs 8 and the axial springs 9, deforming, compensate for the skew of the movable housing 2 relative to the stationary housing 5. After undocking, the movable housing 2 returns to its original position.

Thus, by eliminating longitudinal and radial movements, skews and achieving self-centering of the mating parts in the electrical connector, the reliability of the mating of the socket and male parts located on the stationary and tear-off objects of the electrical connector of power electrical installations is ensured.

Claims (1)

An electrical connector, characterized in that it comprises a male part intended for installation on a tear-off object and having a plug with an axial centering hole, and a female part intended for installation on a stationary object and having a hollow stationary body in the cavity of which a movable body having a centering is installed a pin intended to be installed in the centering hole of the plug, while the movable housing on the front end side has a blind evenly spaced around the circumference radial and axial openings in which one of the ends of the compression springs is located, the other ends of the compression springs being installed so as to interact with the fixed body, and between the movable body and the fixed body on the side of the rear end part of the mobile body, spherical an element whose spherical surface is interfaced with the spherical surface of the recess made in the movable housing, while the top of the spherical surface is deep eniya located on the same axis with the axis of the centering pin.

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