RU2016445C1 - Microconnector - Google Patents

Abstract

FIELD: telephone equipment. SUBSTANCE: microconnector is composed of insert and socket. Insert has insulation body 3 with catch 4, it is produced integral with body of element 5 meant for its pressing into telephone cord 6 with hot punch. Hole 7 intended for positioning of cord 6 passing into stepped holes 8 is made in body 3. Wire contacts 9 pass through holes 8, they are coupled with one end to bushings 10 with current-carrying conductors 11. Socket has insulation body 15 with inner space 16 to house inserts. Insulation body 15 has through holes 17 arranged staggered in two rows. Contacts 14 connected with bushings 19 to current-carrying bundles 20 are located in holes 17. Wire contacts 14 and 9 have bents 21 and 13 correspondingly. Two-point contact is formed for each pair of contacts with interaction of contacts of insert and socket. EFFECT: enhanced contact efficiency. 3 dwg

Description

 The invention relates to telephone equipment, and more specifically to a device for micro-connectors of telephone cords, both linear and spiral, and are intended for use with telephone sets.

 Perhaps their use in other areas of the economy.

 Known micro-connector for telephone cords, which contains an insert consisting of an insulating housing with a latch. A cavity is made in the insert body, in which the cord and conductive wires are placed. At the base of the inner cavity, grooves are made for installing in each of them a corresponding contact element. The contact element contains pointed protrusions, providing cutting through the insulation of the conductive core and the formation of electrical contact. The upper edge of the contact element serves to form electrical contact with the springy wire contacts connected by the bushings, with the wires of the telephone circuits, and installed in the housing of the microsocket and bent into the inner part of the socket, which includes the insert. In this case, the latch protrusion pops up behind the protrusion in the socket housing and fixes the insert in the latter.

 The disadvantage of the analogues is the insufficiently low transition resistance formed between the contact elements of the insert and conductive veins due to their piercing by the pointed protrusions of the contact elements and the point contact formed between the contact elements of the insert and the wire contacts of the socket, which leads to an increase in losses.

 The closest technical solution, selected as a prototype, is the well-known micro-connector [1].

 The micro-connector contains an insert, consisting of an insulating housing with a latch.

 A cavity is provided in the insert body for accommodating the cord, passing into at least two rows of sockets for introducing insulated conductive conductors extending from the round cord.

 The housing has parallel slots, each of which communicates with a corresponding socket.

 Slots are intended for installation in each of them the corresponding contact element.

 The contact element contains pointed protrusions, providing cutting through the insulation of the conductive core and the formation of electrical contact.

 The upper edge of the contact element serves to form electrical contact with the wire contacts of the outlet.

 The socket is an insulating case with an internal cavity made in it, into which the micro-plug insert enters and is fixed in it by the insert latch, which enters with its surfaces over the protrusions of the socket body.

 Through holes are staggered in the socket housing, arranged in two rows in a checkerboard pattern, and grooves located in the same plane with them are made on the end and inner surfaces of the socket housing, on the side of the above holes.

 U-shaped wire contacts are connected by bushes with wires of electrical circuits, each installed in its own through hole and bent into the end and inner surfaces, each in its own groove, with the ability to spring when installing the insert in the socket and due to the spring properties of the wire contacts to provide contact pressing in formed between the wire contacts of the outlet and the surfaces of the contact element of the insert, point contacts.

The disadvantages of the prototype are:
1) the electrical connection of the contact elements with the conductive core due to its piercing with the pointed protrusions of the contact elements cannot provide a low transition resistance, since contact pressing is formed due to the spring properties of the insulation of the conductive core caused by the compaction of the conductive core with the pointed protrusions of the contact elements.

Moreover, the area of direct contact of the pointed protrusions with the conductive core cord is negligible;
2) the electric contact formed when the insert is inserted into the socket between the edge of the contact element of the insert made in radius and the cylindrical surface of the wire contact of the socket is single-point.

 It is well known that small contact pressing forces for point contact do not provide a low transition resistance either.

 The aim of the present invention is to reduce energy losses by reducing the transient resistance both at the junction of the contacts with conductive cores, and with electrical contact between the contacts of the insert and socket.

 This goal is achieved by the fact that in the micro-connector an insert including an insulating housing with a latch and contacts connected to conductive wires and located in one or at least two rows in the openings of the insert housing, a socket including an insulating housing with an internal cavity for placement said insert and U-shaped wire contacts located in the grooves of the socket body, one of the branches of the socket contacts is placed in the through hole of the socket body and connected to the conductive core, the socket is equipped with an additional sleeve, each of the contacts of the insert is made of wire U-shape, and one of the branches of the U-shaped contact of the insert is made loose with a free end and with a bulge near the point of bending, and one of the branches of the wire U-shaped contact of the socket is also made with a free the end and the bulge near its bend, while the other branch of the wire U-shaped contact of the insert is located in the through hole of the insert, the end of the specified branch of the contact of the insert is connected to the conductive th additional sleeve, said bulge contacting one of the branches of U-shaped insert engages the free end of the branch wire contact socket and the contact bump on the branch outlet communicates with the free end of the wire insertion contact, forming a two point contact for each pair.

 In FIG. 1 shows an insert of a microsocket outlet with a partial tear-out of the outlet housing, top view; figure 2 is a cross section of the insert and socket of the micro connector AA in figure 1; figure 3 is a view along arrow B of the micro connector in figure 2.

 The micro connector consists of insert 1 and socket 2.

 The insert 1 contains an insulating casing 3 with a latch 4 and made in one piece with the casing element 5, designed to press it with a hot punch into the telephone cord 6 and thereby securely fasten it in the casing 3.

 A hole 8 is made in the housing 3, designed to accommodate a telephone cord 6 of round or flat shape, turning into isolated through-step openings 8 located at least at two levels in a checkerboard pattern in order to maintain a predetermined step of the location of the contact elements 9.

 The number of wire U-shaped contacts 9 may be different. Through the holes 8 one branch of the wire contacts 9 passes, the end of which is connected by the bushings 10 to the conductive cores 11 stripped from insulation and together with the crimped ones in order to reliably connect the wire contacts 9 to the conductive cores 11, and one end of the bushings 10 abuts against the housing 3.

 Wire U-shaped contacts 9 of the free end of the other branches come out of the holes 8 of the housing 3 and are bent for placement in grooves 12 made on the surfaces of the housing 3 of the insert 1.

 The grooves 12 serve to guide the movement of the free end of the branch of the wire U-shaped contacts 9, to ensure their location in the same plane with the grooves 12 and to separate the current-carrying elements of the micro-connector from each other.

 On the wire U-shaped contacts 9 of the insert 1 in the places of their bending, a convex 13 is made, on which the free end of the branch of the wire U-shaped contacts 14 of the socket 2 is supported with a certain force, forming the first point contact.

 The socket 2 is an insulating housing 15 with an internal cavity 16 made in it, into which the insert 1 enters.

 In the housing 15 of the socket 2, through holes 17 are made, arranged in two rows in a checkerboard pattern. In the holes 17 there is one of the branches of the wire U-shaped contacts 14 connected by the bushings 19 to the conductive cores 20. On the end and inner surfaces of the housing 15, grooves 18 are made, which serve to ensure the direction of the free end of the branch of the wire U-shaped contacts 14 location in the same plane with the grooves 18 and the separation of current-carrying elements from each other.

 A convexity 21 is made on the wire U-shaped contacts 14 of the socket 2 at the places of their bend, on which the free end of the branch of the wire U-shaped contacts 9 of insert 1 rests with a certain force, forming a second point contact.

 A protrusion 22 is made in the housing 15 for engagement with the protrusion 23 of the latch 4. The interaction of the insert 1 and the socket 2 of the micro-connector is as follows.

 When installing the insert 1 into the socket 2, the housing 3 of the insert 1 enters the internal cavity 16 of the housing 15. In this case, as the installation is made, the free end of the branch of the wire U-shaped contacts 14 enters the grooves 12 of the housing 3 of the insert 1 and rests on the bulge 13 of the wire contacts of the 9 insert 1, and the free end of the wire U-shaped contacts 9 enters the grooves 18 of the housing 15 of the socket 2 and rests on the bulge 21 of the wire U-shaped contacts 14 of the socket 2.

 Wire contacts 9 and 14 are installed in the housing 3 and 11 with the ability to spring.

 Subsequently, when the insert 1 is moved into the cavity 16 of the housing 15 of the socket 2, the free end of the branch of the wire U-shaped contacts 9 and 14 will come into contact with the bulges 13 and 21, which under their influence will begin to bend until the latch 4 of the housing 3 the protrusion 23 will not engage with the protrusion 22 of the housing 15 of the socket 2 and will not fix the insert 1 relative to the socket 2.

 In this case, due to the springy properties of the wire contacts 9 and 14, the necessary contact pressure will be created at two points located on their bulges 13 and 21. As a result, when using the same materials of the wire contacts 9 and 14 and the contact pressure values as the prototype , the total transient resistance will decrease due to the point-to-point contact by half, since they are located in parallel in this circuit.

 In the invention, a positive effect is achieved by the formation of a point-to-point contact, which leads to a two-fold reduction of the transition resistance compared to a single-point contact, provided that the same materials of the wire contacts 9 and 14 and the contact pressure values as in the prototype are used, which ultimately leads to a reduction in losses electricity.

 An advantage of the invention in comparison with the prototype is the formation of a point-to-point contact at the points of direct contact of the wire contacts of the insert and socket with the same contact force at each of the two points compared to the prototype. Since both the transition resistance of the point-to-point contact are included in the common electrical circuit in parallel, their total resistance is reduced by half. At the same time, the transition resistance decreases as a result of replacing the electrical contact by piercing the conductive core by connecting the wire contact to the exposed portion of the conductive core with a split sleeve and its running in with the latter with a force much greater than that generated during piercing.

 Therefore, in comparison with the prototype, energy losses will be reduced when using the proposed micro-connector.

Claims (1)

 MICROCONNECTOR containing an insert comprising an insulating housing with a latch and contacts connected to conductive wires and located in one or at least two rows in the openings of the insert housing, a socket including an insulating housing with an internal cavity for accommodating the insert and wire contacts U- shaped in the corresponding grooves of the socket housing, one of the branches of the aforementioned wire contacts is placed in the through hole of the socket housing and connected to the conductive core, exl characterized in that, in order to reduce energy losses, it is equipped with an additional sleeve, each of the contacts of the insert is made of U-shaped wire, and one of the branches of the U-shaped contact of the insert is made loose with a free end and with a bulge near the bend and one of the branches the wire U-shaped contact of the socket is also made with a free end and with a bulge near its bend, while the other branch of the wire U-shaped contact of the insert is located in the through hole of the insert, the end is indicated the second branch of the insert contact is connected to the conductive additional residential sleeve, the indicated bulge on one of the branches of the U-shaped contact of the insert interacts with the free end of the branch of the wire contact of the socket, and the convexity on the branch of the contact contact of the socket interacts with the free end of the wire contact of the insert, forming a two-point contact for each pair.

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