DE19610610A1 - Arrangement for connecting electrical conductor to insulation piercing contact - Google Patents

Abstract

The arrangement has an insulating housing (1) with inner and outer elements (2,3) with through openings (4,5) and relatively movable via a spring element (9) which can be compressed via an opening. One housing element has blades (6,7) for contacting a conductor (10). The conductor can be inserted with the spring in a stretched state in which the openings overlap. A slot (8) in the through opening in one housing element extends in the direction in which the spring force acts. The blades are mounted to left and right of the slot. The spring has a non-tensioned position in which the through opening of one element is over the slot in the other element so that the inserted conductor is held between the blades.

Description

The invention relates to an arrangement for connection of an electrical conductor with an insulation displacement contact, with following features: It is an insulating housing intended; there are at least one in the insulating housing inner element and at least one matching outer one Element arranged; have the inner and outer element Through openings on; has at least one of the elements Cutting for contacting an electrical conductor; the inner and the outer element are by means of one resilient element arranged movable relative to each other; the insulating housing has at least one operator opening through which the resilient element can be compressed is; in a first position in a first cocked The through openings are in the state of the resilient element of the inner and outer elements to each other arranged overlapping that an electrical conductor can be introduced.

From US 5,011,492 is a generic connector known. An elongated insulating housing takes one Variety of pairs and by electrical conductive bridges connected contacts. Openings on the Long side of the insulating housing and openings in one rectangular metallic guide housings match openings in a metal block that is in the guide housing from a Coil spring from a first tensioned state to one second tensioned state is moved. In every contact pair can through openings on two opposite Electrical conductors introduced along the long sides of the housing will. With a separately insertable part, e.g. B. with a Screwdriver is opened through another opening in the insulating housing and through a matching opening  in the guide housing the metal block against the direction in which acts on the spring force of the spiral spring. The Contacting is improved by wedge-shaped designs Edges on the openings in the guide housing and in Metal block. Even in the operating state when the contact is produced, the spring force acts on the metal block. When the spring force diminishes or completely in the event of a defect is missing, it is not guaranteed that the conductor is in contact is held.

Based on this state of the art, it is the task of Invention an arrangement for connection to a contact to specify, which ensures that the leader also at Weakness or lack of spring force safely in contact is held.

This object is achieved by an arrangement for connection an electrical conductor with an insulation displacement contact following features: It is an insulating housing intended; there are at least one in the insulating housing inner element and at least one matching outer one Element arranged; show the inner and outer element Through openings on; has at least one of the elements Cutting for contacting an electrical conductor; the inner and the outer element are by means of one resilient element arranged movable relative to each other, the insulating housing has at least one Operating opening through which the resilient element is compressible; in a first position in a first tensioned state of the resilient element are the Through openings of the inner and outer element arranged so that they overlap each other so that a electrical conductor can be introduced; of the A slot extends through the opening of an element in the direction in which the spring force acts; the cutting  are arranged to the left and right of the slot; in a second position is the resilient element in Essentially in a relaxed state and the passage opening one of the elements is above the slot of the other Element arranged that when electrical Head this is held between the cutting edges.

It is advantageous that as little electrically conductive as possible Parts are used. This is achieved in that the outer element is made of insulating material, and that only an inner element made of electrical conductive material must be produced.

It is also advantageous that when contacting in Insulation displacement contact prevents the conductor end from slipping becomes. This is achieved by having the inner element on the side opposite the slot with the cutting edges has a rear through opening that is elongated is formed and the end of the electrical conductor from first tense state to the second relaxed state can move freely and that a sufficiently long Conductor end beyond the contact area into the rear through opening can be inserted.

It is also advantageous that when contacting a Bending the conductor is avoided. This will do so achieved that the insulating housing a front Has inlet opening that is at least as large and as well is elongated, like the rear through opening of the inner element and the electrical conductor from first tense state to the second relaxed state can move freely.

It is also advantageous that for the compression of the resilient element no conductive parts are touched  have to. This is achieved in that a separate part, for example a screwdriver, by an operator opening that is outside the spring distance and that only the outer isolating Element must be operated.

An embodiment of the invention is based on the Drawings explained. Show it:

Fig. 1 is a perspective view of the preferred embodiment,

Fig. 2 shows a cross section of the arrangement of FIG. 1,

Fig. 3 is a perspective view of three cooperating elements of the assembly prior to installation in the housing,

Fig. 4 3 how they work together, the three elements of Fig. In the housing after the installation,

Fig. 5, the three elements of Fig. 3 in the first stressed state prior to insertion of the conductor,

Fig. 6, the three elements of Fig. 3 tensioned in the first state after the insertion of the conductor,

Fig. 7 shows the three elements from Fig. 3 in the second relaxed state.

In Fig. 1, an arrangement for the connection of electrical conductors is shown with a insulation displacement contact. The arrangement has an insulating housing 1 which receives two insulation displacement contacts. The insulating housing 1 is essentially a rectangular plastic body in which holes are made for each contact. The insulating housing 1 is delimited by an upper wall 13 . In Fig. 1 is the left one of the insulation displacement contacts in the relaxed state without electric conductor 10 is shown. Another insulation displacement contact in the tensioned state with the electrical conductor 10 just inserted is shown on the right.

For a better understanding, FIG. 2 shows a cross section through the housing of FIG. 1 at the location of the insulation displacement contact which is in the tensioned state. Each insulation displacement contact of the arrangement consists of an inner element 2 , an outer element 3 and a resilient element 9 .

The inner element 2 is essentially a conductive metal tube, which is provided with a collar 16 at a lower end 22 . The collar 16 serves to reinforce the metal tube, as a stop for the resilient element 9 and for fastening in the insulating housing 1 . The outer element 3 is essentially a cylindrical insulating plastic body, which is arranged like a cap over the other upper end 21 of the metal tube. The outer element 3 is arranged to move freely with respect to the inner element 2 in the direction in which the spring force of the resilient element 9 acts. The wall of the cylindrical plastic cap protrudes over part of the metal tube, and the lid of the plastic cap is movable between the upper end 21 of the metal tube and the upper wall 13 of the insulating housing 1 . The resilient element 9 is a compressible spiral spring which is arranged on the circumference of the metal tube between the collar 16 and the outer element 3 .

The insulating housing 1 has an entry opening 12 for each insulation displacement contact and an operating opening 11 arranged above it in the direction in which the spring force acts.

The operating opening 11 is located outside the spring path and between the upper end 21 of the metal tube and the upper wall 13 of the insulating housing 1 . A separate part 20 can be inserted through the operating opening 11 . In Fig. 1 and Fig. 2, a screwdriver is shown as a separate part 20 . The screwdriver is inserted into the housing 1 through the operating opening 11 . By inserting the screwdriver, the outer element 3 is moved over the upper end 21 of the metal tube. As a result, the coil spring is brought into a first tensioned state.

An electrical conductor 10 can be inserted in the insulation displacement contact through the inlet opening 12 . The inner element 2 has a front essentially round through opening 4 and an elongated rear through opening 14 . A slot 8 extends from the front through hole 4 in the longitudinal direction of the metal pipe in the direction in which the spring force acts. The two edges of the slot 8 are designed as sharp cutting edges 6 , 7 .

To establish an insulation displacement connection, the plastic cap is moved downward against the spring force with the aid of a screwdriver. The outer element 3 has a through opening 5 , 15 which leads from the front to the rear side of the plastic cap, which is essentially round and at least as large as the front round through opening 4 of the inner element 2 . In the first compressed state of the coil spring, the through openings 4 , 14 of the inner element 2 , the through openings 5 , 15 of the outer element 3 and the inlet opening 12 on the insulating housing 1 are in an overlapping position with one another in such a way that the electrical conductor 10 is inserted through these openings can.

In the following step, the separate part 20 is removed from the operating opening 11 . The resilient element 9 relaxes and the outer element 3 moves up into a second relaxed position. When the screwdriver is removed, the spring presses the electrical conductor 10 at high speed into the slot 8 between the cutting edges 6 , 7 of the insulation displacement contact. The spring force of the resilient element 9 is only required for the introduction of the electrical conductor 10 into the slot 8 with the cutting edges of the insulation displacement contact. If the electrical conductor 10 is fixed in the insulation displacement contact, spring force is no longer necessary. Even if the spring force would decrease over time, the conductor 10 remains fixed in the insulation displacement contact. The elongated rear through opening 14 of the inner element 2 is necessary in order to be able to insert a sufficiently long piece of the electrical conductor 10 into the insulation displacement contact. This ensures that the end of the electrical conductor 10 does not slip when the insulation displacement connection is made.

If the electrical conductor 10 has to be removed from the insulation displacement contact, the separate part 20 is inserted again into the operating opening 11 . As a result, the outer element 3 is moved downward against the direction in which the spring force acts and the electrical conductor 10 is moved out of the slot 8 into the through opening 4 , 14 . The electrical conductor 10 is then removed from the through-opening 4 , 14 from the inner element 2 .

The lower end 22 of the metal tube and the reinforcing collar 16 are used for fastening in the insulating housing 1 . In this area, an electrically conductive bridge can connect two adjacent inner elements 2 , 2 'from one another within the insulating housing 1 . The lower end 22 of the inner element 2 can also be used for contacting on a further electrical conductor, not shown, or on a printed circuit board.

For the proper function, the outer element 3 and the resilient element 9 do not have to be made electrically conductive. The only electrically conductive part of the arrangement is the inner element 2 . This means an additional advantage for the design and manufacture of the arrangement: because the arrangement comprises only one critical component, the requirements for the design and production tolerances of the individual components are low and the tolerance structure of the arrangement is simplified.

In Fig. 3, the three main elements of the assembly are shown prior to installation in the insulating housing 1. Here it can be seen how the inner element 2 has a collar 16 at a lower end 22 . The front essentially round through opening 4 and the slot 8 with the cutting edges 6 , 7 of the inner element 2 are also shown. The round front through opening 5 of the outer element 3 can also be seen, as well as the resilient element 9 , which is attached above the metal tube.

FIG. 4 shows the same elements from FIG. 3, but here how they are in the relaxed state in the housing 1 before the electrical conductor 10 is inserted. The resilient element 9 is in the relaxed state. The outer element 3 lies loosely on the resilient element 9 , which in turn lies loosely on the collar 16 . The round front through opening 4 of the inner element 2 and the round front through opening 5 of the outer element 3 do not overlap. In this state, the electrical conductor 10 cannot be inserted.

In Fig. 5, the resilient member 9 is shown in the second tensioned state. In this position, the through openings 4 , 5 , 14 , 15 of the two inner and outer elements are brought into line with one another and the electrical conductor 10 can be inserted.

In FIG. 6, the electrical conductor has been 10 is inserted. The resilient element 9 is still in the first tensioned state.

In FIG. 7, the resilient element 9 has relaxed from the first tensioned state into the second relaxed state and in this case the electrical conductor 10 inserted has been clamped from the through opening 4 into the slot 8 between the cutting edges 6 , 7 . The electrical conductor 10 is held by the insulation displacement contact. The resilient element is again in the same relaxed state as before in FIG. 4.

Claims (11)

1. Arrangement for connecting an electrical conductor to an insulation displacement contact, with the following features:

• a) an insulating housing ( 1 ) is provided,
• b) at least one inner element ( 2 ) and at least one matching outer element ( 3 ) are arranged in the insulating housing ( 1 ),
• c) the inner and the outer element ( 2 , 3 ) have through openings ( 4 , 5 , 14 , 15 ),
• d) at least one of the elements ( 2 ) has cutting edges ( 6 , 7 ) for contacting an electrical conductor ( 10 ),
• e) the inner and the outer element ( 2 , 3 ) are arranged so as to be movable relative to one another by means of a resilient element ( 9 ),
• f) the insulating housing ( 1 ) has at least one operating opening ( 11 ) through which the resilient element ( 9 ) can be compressed,
• g) in a first position in a first tensioned state of the resilient element ( 9 ), the through openings ( 4 , 5 , 14 , 15 ) of the inner and outer elements ( 2 , 3 ) are arranged so as to overlap one another such that an electrical conductor ( 10 ) can be introduced,

characterized in that

• h) a slot ( 8 ) extends from the through opening ( 4 ) of an element ( 2 ) in the direction in which the spring force acts,
• i) the cutting edges ( 6 , 7 ) are arranged to the left and right of the slot ( 8 ),
• j) in a second position the resilient element ( 9 ) is essentially in the relaxed state and the through opening ( 5 ) of the one element ( 3 ) is above the slot ( 8 ) of the other element. ( 2 ) is arranged so that when the electrical conductor ( 10 ) is inserted, it is held between the cutting edges ( 6 , 7 ).

2. Arrangement according to claim 1, characterized in that the outer element ( 3 ) is made of insulating material, essentially represents a cylindrical plastic body which is freely movable to the inner element ( 2 ) and the front through opening ( 5 ) and has the rear passage opening ( 15 ). 3. Arrangement according to one of claims 1 or 2, characterized in that on the slot ( 8 ) opposite side of the inner element ( 2 ), the rear passage opening ( 14 ) is elongated in such a way that the electrical conductor ( 10 ) of the first position up to the second position is freely movable. 4. Arrangement according to one of claims 1 to 3, characterized in that the insulating housing ( 1 ) on the side of the slot ( 8 ) has an inlet opening ( 12 ) which is at least as large as the elongated rear through opening ( 14th ) of the inner element ( 2 ) and the passage opening ( 14 ) opposite and overlapping this is arranged. 5. Arrangement according to one of claims 1 to 4, characterized in that a separate part ( 20 ) can be introduced through the operating opening ( 11 ) in the insulating housing ( 1 ) for compressing the resilient element ( 9 ). 6. Arrangement according to one of claims 1 to 5, characterized in that the operating opening ( 11 ) in the insulating housing ( 1 ) in the relaxation direction of the resilient element ( 9 ) is arranged outside the spring path. 7. Arrangement according to one of claims 1 to 6, characterized in that the inner element ( 2 ) has a collar ( 16 ). 8. Arrangement according to one of claims 1 to 7, characterized in that the resilient element ( 9 ) is designed as a compressible spiral spring and arranged on the circumference of the inner element ( 2 ) between the collar ( 16 ) and the outer element ( 3 ) is. 9. Arrangement according to one of claims 1 to 8, characterized in that one end of the inner element ( 2 ) can be used for contacting a further electrical conductor or a printed circuit board. 10. Arrangement according to one of claims 1 to 9, characterized in that an electrically conductive bridge is arranged between two adjacent inner elements ( 2 , 2 ').