RU2076409C1 - Multiterminal electric connector - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: connector has two mating parts; each part has holder 1 for one end of flexible insulating plates carrying current collectors 3 in the form of flat conducting strips; flexible insulating plates of one mating part enter gaps between those of other mating part and current collectors 3 of both mating parts come in contact and are braced on both sides with clamp 4; one mating part is placed in first shroud 5 and other one, in second shroud 6 that has clamp 4 in the form of two levers 7 rigidly fixed with eccentric cams 8; each mating part is made in the form of alternating flexible insulating plates 2 carrying conducting strips and thickness-calibrated spacers 24; plates 2 bearing insulating strips and mentioned spacers are made of flexible insulating foil, such as polyamide or lavsan. EFFECT: improved design. 6 cl, 8 dwg

Description

 The invention relates to the field of electrical engineering and can be used in multi-contact electrical connectors.

Known electrical connector containing two mating parts, each of which contains a metal casing with contact elements in the form of elastic wires and a current collector, while the ends of the contact elements of the mating parts are rotated relative to each other by 180 ^o [1]
A disadvantage of the known device is the use in it of contact elements with a complex three-dimensional shape, which leads to an increase in the distance between adjacent contacts and, accordingly, an increase in the dimensions of the connector.

The closest analogue is an electrical connector, consisting of two mating parts, each of which contains a holder with current collectors with a clip interacting with current collectors [2]
A disadvantage of the known device is the presence of movable elements moving along the guides, which reduces the reliability of the electrical connector, and it is difficult to manufacture,
The objective of the invention is to increase the reliability and manufacturability of the design, reliability.

The specified technical result is achieved due to the fact that in the electric multi-contact connector containing the first and second mating parts, each of which is made in the form of a holder with current collectors, and a clamp installed with the possibility of interaction with current collectors in the direction perpendicular to the planes of the current collectors, the current collectors are made in in the form of flat strips connected to elastic dielectric plates, one end of each of which is fixed in the holder, while the current collectors of the first counterpart mescheny between the current collectors of the second mating Interoperable their respective strips and the distance between the holder and the first mating end of the dielectric plate belonging to the second mating part, chosen from the following relation:
l (2.20) t,
where t is the thickness of the dielectric plate with the current collector due to the fact that the clamp is made in the form of two levers rigidly connected to the eccentric cams, and buffers installed between the respective cams and current collectors with the possibility of interaction with them, and also due to the fact that each reciprocal part the connector is made in the form of sequentially alternating elastic dielectric plates with flat conductive strips deposited on them and calibrated by the thickness of the insulating spacers, while the material for The fabrication of elastic dielectric plates coated with flat conductive strips and the aforementioned gaskets is a foil resilient insulating material.

 In FIG. 1 shows the construction of an electrical multi-pin connector, FIG. 2 mating connector, in FIG. 3 an electrical multiple connector with a cam clamp in operational condition; FIG. 4 an electric non-contact connector with a clamp in the form of plates with spring elements, in FIG. 5 shows an example of a plate with spring elements; FIG. 6 is an example of connecting a multi-pin connector with double row arrangement of contacts to two flat cables, FIG. 7, an example of attaching a multi-pin connector to a flat cable; FIG. 8 - design of the mating connector.

 An electrical multiple connector (Fig. 1, 2) consisting of two mating parts, each of which contains a holder 1, in which elastic dielectric plates 2, current collectors 3, which are made in the form of flat conductive strips and connected to elastic dielectric plates 2, are attached to one end The counterparts are embedded in each other so that the elastic dielectric plates 2 and the current collectors 3 of one counterpart are placed in the spaces between the elastic dielectric plates 2 with the current collectors 3 of the other hydrochloric portion 3 and the current collectors contact both mates together and tightened on both sides in the direction perpendicular to the plane of the current collector 3 a clamp 4.

 In the FIG. 3, one mate is located in the first housing 5, the other mate is housed in a second housing 6 containing a clamp 4 made in the form of two levers 7, rigidly connected to the eccentric cams 8 and placed on the brackets 9.

 The eccentric cams 8 abut against the buffer elements in the form of plates 10 of elastic material mounted on the slats 11. Elastic dielectric plates 2 and current collectors 3 of the first and second mating parts are respectively located in the first and second protective casings 12 and 13, which simultaneously serve as guides and a key when articulating the mating parts of the connector.

 When implementing an electrical multiple connector in the embodiment shown in FIG. 4, each part of the clamp 4 is made in the form of a flexible plate 14 with spring elements 15 made for the right and left sides, and the latch 16 with the pushing protrusions 17 placed on it, the latch 16 has the ability to rotate around the axis 19 fixed on the rack 18.

 The connection of the conductors 20 of the flat cable 21 is made to the rear of the current collectors 3 (Fig. 6, 7). After installation, the flat cable 21 is pressed by the clamping bar 22 to the support posts 23.

 In the manufacture of mating parts (Fig. 8), they are made in the form of sequentially alternating elastic dielectric plates 2 with current collectors 3 and gaskets calibrated by thickness.

 The electrical multi-pin connector operates as follows.

 Elastic electric plates 2 with current collectors 3 of one counterpart of the connector are inserted into the spaces between the elastic dielectric plates 2 with current collectors 3 of the other counterpart. The clamp 4 creates a force in the direction perpendicular to the plane of the current collectors 3. The current collector 3 of both counterparts are in contact with each other in pairs, forming an electrical contact with each other.

 To disconnect the mating parts of the connector, the force generated by the clamp 4 is first removed, then the elastic dielectric plates 2 with the current collectors 3 of one mate are removed from the gap between the elastic dielectric plates 2 with the current collectors 3 of the other mate.

 Multiple electrical connector, an embodiment of which is shown in FIG. 3, works as follows.

 Before articulation of the mating parts of the connector, the levers 7 are turned in the direction of the casing 6, together with them the eccentric cams 8 rotate. The distance between the surfaces of the eccentric cams 8 will be maximum. The counterparts of the connector are inserted into each other in such a way that the elastic dielectric plates 2 with the current collectors 3 of one counterpart enter the gap between the elastic dielectric plates 2 with the current collectors of the other counterpart. The lever 8 is rotated towards the casing 5, while due to the rotation of the eccentric cams 8, the distance between their surfaces decreases and the elastic dielectric plates 2 with current collectors 3 are pressed into each other through the buffer plates 10.

 To damp the experimental pressure that occurs when the maximum of the eccentric cams 8 passes through the compression line and create a compression force of the current collectors 3 between themselves, buffer plates 10 made of an elastic material, for example, an elastomer, are used.

 When turning the eccentric cam 8, it slides along the surface of the bar 11 and transfers force to the buffer plate 10. Due to its elasticity, the buffer plate 10 is compressed and compresses the current collectors 3.

 In this embodiment, by selecting the shape of the buffer plate 10, the connector is sealed easily enough.

 The levers 7 have protrusions that prevent unauthorized disconnection of the connector.

 An electrical multi-pin connector, an embodiment of which is shown in FIG. 4, works as follows.

 In the initial state, the latch 16 opens, i.e., is in the plane perpendicular to the plane of the connector (position A in Fig. 4). The pushing protrusions 17 are offset relative to the spring elements 15. No pressure is applied to the buffer plate 10. The mating parts of the connector are inserted into each other as described above. The latch 16 is rotated to position B. In this case, the pushing protrusions 17 slide on the surface of the plates 14 and abut against the spring elements 15, creating a compressive force on both sides. The magnitude of the compression force depends on the thickness of the plate 14 and the shape of the spring elements 15. In position B, the latch 16 protects the connector from unauthorized separation.

 The embodiments shown in FIG. 3, differ from each other in the design of the clamp, the remaining parts of the connector are the same.

 The contact force between the contacting current collectors 3 determines the magnitude of the transition resistance, the stability of the contact and, accordingly, the reliability of the connection. The minimum force that needs to be applied between two contacting parts to ensure reliable contact is 0.15 0.275 kG, depending on the material of the contacts. The decrease in effort leads to an increase in transition resistance, which is undesirable.

 If one current collector 3 is applied to each elastic dielectric plate 2, then the contact force between the current collectors 3 is determined by the force generated by the clamp 4, taking into account the cost of deformation of the elastic dielectric plates 2. For the case when several current collectors are applied to each elastic dielectric plate 2 3, the force generated by the clamp 4 must be increased in proportion to the number of current collectors 3.

 The distance between the elastic dielectric plates 2 in each counterpart is selected so that the elastic dielectric plates 2 together with the current collectors 3 are included in the gap of the counterpart without significant effort. On the other hand, the distance should not be very large, since this will lead to significant deformations of the end plates 2. These conditions are most satisfied with the distance chosen in accordance with the requirements for sliding landings.

 The gap formed between the two dielectric plates of the 2 mating parts depends on the accuracy of the surface treatment. The manufacturing error for parts for polished surfaces is 1 3 microns. If the gap between the plates of the 2 mating parts is taken to be within 0.5 μm, then for an electrical multiple connector containing, for example, 50 current collectors 3, the displacement of the extreme plates during compression, relative to their initial position, will not exceed 0.06 mm. The portion of the elastic dielectric plate 2 between the holder and the end of the elastic dielectric plate 2 of the counterpart provides this offset. The length of the section is selected based on the expression l Kt, where t is the thickness of the elastic dielectric plate with a current collector.

 The value of the coefficient K depends on the properties of the materials from which the elastic dielectric plate 2 and the current collector 3 are made, the number of plates 2, their geometric dimensions and is selected within 2.20.

 The design of both mating parts is the same, easy to manufacture. The minimum distance between adjacent current collectors 3, the step between the contacts of the connection, reaches a value of 0.3 mm, and the tail parts of the current collectors 3 are fixed, which allows the installation of flat cables directly on the tail parts of the current collectors 3 of the connector. The options for connecting the connector to the flat cables are shown in FIG. 6 and 7.

 In FIG. 6 shows the connection of two flat cables to an electrical connector with a two-row arrangement of current collectors 3. Installation of electric wires 20 of flat cables 21 to the side parts of current collectors 3 is carried out by soldering or welding. The clamping plates 22 press the flat cables to the support rack 23, providing mechanical fastening and electrical protection of the open conductors of the flat cables 21.

 In FIG. Figure 7 shows the connection of a connector to a shared bus interface cable. In the flat cable 21, the insulation section is removed, the conductors 20 are exposed. The installation of conductors 20 to the end surface of the tail of the current collector 3 is carried out by soldering or welding. The clamping strip 22 presses the flat cable 21 to the support drains 23, providing mechanical fastening and electrical protection of the open conductors of the flat cables 21.

 In FIG. Figure 8 shows the design of the mating portion of an electrical multi-pin connector. The counterpart of the connector is assembled in the form of sequentially alternating elastic dielectric plates with current collectors 3 and calibrated by the thickness of the insulating spacers, fastened together by glue, soldering or welding. Moreover, the material for the manufacture of elastic dielectric plates 22 with current collectors 3 and gaskets 24 is a foil elastic insulating material, for example, polyimide or lavsan.

Claims (6)

1. An electrical multi-contact connector comprising two mating parts placed one into another, each of which is made in the form of a holder with current collectors, and a clip placed on the mating parts with the possibility of interacting with the current collectors of the mating parts in a direction perpendicular to the planes of the current collectors of the mating parts, and ensuring contact of the current collectors of one counterpart with the current collectors of the other counterparts, characterized in that the current collectors of the counterparts are made in the form of elastic astin from a dielectric material and flat conductive strips located on two opposite sides of these plates, connected to them and fixed with one of their end parts in the holders of the mating parts, the current collectors of one mating part located between the current collectors of the other mating part with the possibility of contacting their respective flat conductive strips between each other, while the distance between the holder of one mating part and the end part of each elastic dielectric plate material of the other mating part is selected from the following ratio:
l (2 20) t,
where l is the specified distance, m;
t the thickness of the specified plate with flat conductive strips, m  2. The connector according to claim 1, characterized in that the counterparts are provided with housings, the clip is made in the form of two brackets, two levers with eccentric cams rigidly connected to one of their end parts and two buffers in the form of plates, with each counterpart located in the corresponding copus, brackets, buffers and levers with eccentric cams are placed on the housing of one counterpart from its two opposite sides with the possibility of interaction of the eccentric cams with the buffer plates and mechanical contact buffers with current collectors of two counterparts from two opposite sides, respectively.  3. The connector according to claim 1, characterized in that the clamp is made in the form of two counterparts of nodes located on two opposite sides, each of which is made in the form of a flexible plate with spring elements on its two opposite sides, a latch with pushing protrusions on one of its side, racks with an axis fixed to it and buffers in the form of a plate, and the racks with axles and flexible plates with spring elements of the clamp nodes are fixed to the holder of one counterpart from its two opposite sides, respectively, fix Rings with pushing protrusions of the clamping units are mounted on the axes of the struts between the uprights and flexible plates with the possibility of rotation relative to the specified axes and the interaction of their pushing protrusions with the spring elements of the respective flexible plates on the one hand and ensuring the interaction of the pushing protrusions with the spring elements of the flexible plates on the other opposite sides with buffers that are located between the flexible plates of the clamping nodes and the current collectors of the mating parts with the possibility of mechanical contact anija with said two current collectors mates with two opposite sides respectively. 4. An electrical multi-contact connector comprising two mating parts with current collectors arranged in one another and a clamp located on mating parts with the possibility of interacting with mating current collectors in a direction perpendicular to the mating planes of the mating parts and providing contact between the other mating collectors the fact that each mating part with current collectors is made in the form of a package of alternating between each other elastic plates of dielectric material with bilaterally applied flat conductive strips and gaskets made of dielectric material with bilaterally applied flat conductive strips rigidly interconnected to ensure contact between their flat conductive strips, and elastic plates of dielectric material are made longer than gaskets of insulating material, moreover, the elastic plate of a dielectric material with flat conductive strips of one counterpart located between the elastic plates of dielectric ctric material with flat conductive strips of the other counterpart, opposite to its gaskets of insulating material with the possibility of contacting their respective flat conductive strips with each other, while the distance between the ends of the elastic plates of one counterpart and opposite gaskets of insulating material of the other counterpart is selected from the following relation :
l (2 20) t,
where l is the specified distance, m;
t the thickness of the specified plate with flat conductive strips, m  5. The connector according to claim 4, characterized in that foil elastic insulating material is used as the material of the elastic plates and gaskets with flat conductive stripes applied thereon.  6. The connector according to claim 5, characterized in that polyimide or lavsan is used as the insulating material of the base of said foil elastic insulating material.

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