DE69403652T2 - SPLICE BAR FOR INSULATED TELECOMMUNICATION CABLES - Google Patents

Description

Background of the invention Field of the invention

The invention relates to a splice head for insulated wires of the type used in telecommunications.

State of the art

In telecommunications, connectors are known with which an electrical contact can be made with a large number of conductors. From DE-A-39 20 367 it is known to provide a carrier body with a large number of insulation displacement contacts and to press associated conductors or wires against the insulation displacement contacts with the aid of a milling body. The insulation displacement contacts cut through the insulation and come into contact with the conductors, and then enter the appropriately arranged recesses in the pressing body. The carrier body also has cutting edges that cut off protruding ends of the insulated wires.

In order to insert a large number of insulated wires in the correct position in the carrier body, it is known to use a so-called splice head. The splice head has a receptacle for a connector, namely at least one carrier and one pressing body, as well as a series of spaced fingers on one side of the receptacle. Such a splice head is assigned to the end of a cable harness in which the individual wires are exposed. The wires are arranged in the slots between the fingers and aligned with the individual insulation displacement contacts in the received carrier body. The protruding ends of the insulated wires are then secured in a suitable manner until all of the wires to be accommodated in the connector have been inserted. The pressing body is then pressed against the carrier body using a suitable tool, in particular pliers, in order to bring the large number of insulated wires into engagement with the insulation displacement contacts.

From DE-A-27 48 298 it is known to use a helical spring to fix the ends of the cable cores in the splice head. The insulated wires are inserted between the turns and held therein by the spring tension. It is known to use a single helical spring and to support it on a shoulder of the splice head, while a holding rod is passed through the interior of the spring, which is connected to the splice head at the ends. Such known springs have a diameter of about 10 mm and a predetermined distance between their turns. The spring is held axially on one side by means of a radial bend at the end. If many wires are taken up between the individual turns of the spring during the splicing process, the free end moves axially further outwards from the fixed first end.

When making such connections, the diameter of the insulated wires varies within a relatively large range. The known splicing head, in particular the coil springs, are not able to fix wires of different diameters equally effectively. It is therefore necessary to replace the springs if the diameters are different. Since the spring is fixed on one side, the splicing process must always be started at the fixed end of the spring.

It is also known to use a splice head according to DE-A-27 48 298 with two parallel coil springs that differ in the distance between the turns in order to be able to effectively fix wires of different diameters. However, if wires with a different diameter are to be inserted into the electrical connector during a splicing process, it is necessary to loosen the holder for both coil springs and turn them by 180º and then fix them again. This measure takes a relatively long time. In the known arrangement, the springs are also fixed at both ends. Tolerances in the distance between the fixing points of the springs can lead to a change in the distance between the turns. In addition, the known springs can generally only accommodate a single wire and not several, as would be the case, for example, if several layers of wires arranged one above the other are to be contacted in an electrical connection arrangement.

Summary of the invention

The invention provides a splice head for insulated wires, in particular for telecommunications, on which wires with different diameters can be spliced equally effectively can be determined.

In the splicing head according to the invention, the coil spring is loosely arranged on the rod and can be moved axially on it. By freely selecting the splice start in the spring and by selecting the position of the spring on the rod, wires of different diameters can be fixed in the spring. In addition, splicing can be started at both ends of the spring.

According to one embodiment of the invention, the rod has a circular cross-section so that the spring can easily slide back and forth. According to another embodiment of the invention, a contact surface is provided slightly below the rod and at a short distance from it, on which the spring is supported on the outside, while it is held by the rod on the inside. The distance between the contact surface and the rod is expediently only slightly larger than the thickness of the wire for the coil spring. In this way, a lot of space is left for the wires to be accommodated, so that two or more wires can be effectively secured simultaneously between adjacent turns. This is particularly the case if, according to another embodiment of the invention, the diameter of the coil spring is larger than 12 mm, preferably 15 mm.

In order to ensure that the spring is effectively supported and can provide the largest possible cross-sectional area for securing the wires, the contact surface is shaped and has such a distance from the rod that, in the position of use, the rod engages the spring from the inside at approximately the height of the spring's longitudinal axis. The support surface is preferably partially curved in a circle around the rod.

The rod can be held in a simple manner by a U-shaped holding component, which according to one embodiment of the invention also has the contact surface.

With the splice head according to the invention, the coil spring for securing the wires does not need to be replaced, even if the wires have different diameters. Since the coil spring sits loosely on the support rod and is therefore not fixed, radial projections on the ends of the spring can be omitted. This simplifies the manufacture of the coil springs.

The invention is explained in more detail below with reference to drawings.

Short figure description

Fig. 1 shows a perspective view of a splicing head according to the invention.

Figs. 2 to 4 show the spring of the splice head according to Fig. 1 in different operating positions.

Fig. 5 shows a section through the spring according to Fig. 2 along the line 5-5.

Detailed description of the currently preferred embodiment

In Fig. 1, a splicing head 10 is shown which is held by a holder 12 which is grasped, for example, with one hand or otherwise secured. The splicing head 10 has a receptacle 14 for a connector (not shown) for a plurality of insulated wires or conductors, as described, for example, in DE 39 20 367. The receptacle 14 consists essentially of a support plate 16 and two lateral guide elements 18, 20, between which the carrier body and pressing body of a connector can be secured. On one side of the receptacle 14, two rows of fingers 20 are arranged, between which the insulated wires are guided and by which the wires are kept at a distance. On the other side of the receptacle 14 there is a helical spring 22 which is held by a holder 24. Details of the holder and the spring can be seen in Figures 2 to 5.

The holder 24 consists of a U-shaped holding component 26, on the legs of which a rod 28 with a circular cross-section is held. As can be seen, the spring 22 is shorter than the distance between the legs or the length of the rod 28 and can be moved freely on the rod 28. The diameter of the spring 22 is, for example, 15 mm and the thickness of the wire from which the spring is made is, for example, 1.5 mm. The individual turns 30 of the spring 22 have a predetermined distance from one another. As can be seen from Figures 2 to 4, the ends of the wire are simply cut off and not deformed in any special way.

From Fig. 5 it can be seen that a contact surface 34 with a circular arc in cross section is formed on the web 32 of the U-shaped holding component 26. The narrowest distance between the rod 28 and the contact surface 34 is only slightly larger than the thickness of the wire for the spring 22. Towards the top, the circular contact surface 34 merges into a flat surface 36 which runs parallel to a plane which extends through the axis of the spring 22. The vertical distance of the surface 36 in the rod 28 is greater than that of the contact surface 34. As can be seen, the contact surface 34 is designed and arranged relative to the rod 28 in such a way that the spring 22 engages the rod 28 from the inside approximately at the height of its longitudinal axis.

Figures 2 to 5 also show how a wire 40, 40' or 40" is secured in the spring 22. It is clear from Figures 2 to 4 that the start of a splicing process can be chosen at will, in that the spring 22 can also assume any position between the legs of the U-shaped holding part 26 at the start.

From Fig. 5 it is clear that the largest part of the cross-section of the spring 22 is available for securing a wire 40 or 40' or 40", so that two or more wires can also be secured between two turns 30.

Claims (11)

1. Splice head for insulated conductors (40, 40', 40"), with a receptacle (14) for a connector to be connected to the conductors, a series of spaced fingers (20) on one side of the receptacle (14), an elongated helical spring (22) on the opposite side of the receptacle, the turns (30) of which enable the conductors to be inserted and secured between the turns, and a holder (26) for the helical spring (22), which has a rod (28) extending through the spring (22) and fastened at the ends, characterized in that the helical spring (22) is arranged loosely on the rod (28) and is axially displaceable on the rod (28). 2. Splicing head according to claim 1, characterized in that the rod (28) has a circular cross-section. 3. Splicing head according to claim 1 or 2, characterized in that a contact surface (34) is provided slightly below the rod (28) and at a short distance therefrom, on which the outer surface of the helical spring (22) is supported. while it is held inside by the rod (28). 4. Splicing head according to claim 3, characterized in that the contact surface (34) is shaped and has such a distance from the rod (28) that in the position of use the rod (28) engages the spring approximately at the height of the longitudinal axis of the spring (22). 5. Splicing head according to claim 3 or 4, characterized in that the contact surface (34) is concave in the shape of a circular arc and extends partially around the circumference of the spring (22). 6. Splicing head according to claim 5, characterized in that the contact surface (34) merges upwards into a flat surface (36) whose vertical distance from the rod (28) is greater than that of the contact surface (34). 7. Splicing head according to claim 1, characterized in that the rod (28) is held by the legs of a U-shaped holding component (26). 8. Splice head according to claim 5, characterized in that the contact surface (34) is formed on the web (32) of the U-shaped holding component (26). 9. Splice head according to claim 1, characterized in that the diameter of the helical spring (22) is greater than 12 mm. 10. Splice head according to claim 1, characterized in that the thickness of the spring wire is greater than 1.2 mm. 11. Splicing head according to claim 3, characterized in that for the insertion of the wires, the turns (30) of the helical spring (22) have a predetermined distance from one another.