EP0583700A1 - Crimping sleeve - Google Patents

Abstract

The invention relates to a crimping sleeve for an electrical cable (10) having a screen (14), on the circumferential side, against external electrical and/or magnetic interference influences, the crimping sleeve being constructed in two pieces (18, 20), and to an outer collar (22) for the connection of the cable screen (14) to an earth connection. <IMAGE>

Description

The invention relates to a shield sleeve (hereinafter referred to as crimp sleeve) for electrical cables with a circumferential shield against external electrical and / or magnetic interference and for electrical contact for equipotential bonding.

Such cables are used, for example, on motors, where they are connected to so-called rotary position transmitters, for example. The connection between the cable and the rotary position transmitter is made using appropriate connectors that are positioned at the free end of the cable. It is important to fix the cable in place to ensure a secure positioning of the connector and to prevent tensile loads on the contacts of the connector as much as possible.

It is known to form the free end of the cable sheath (over which the cable strands protrude for connection to the connector) with a ring which tapers conically towards the free end, the ring being coaxial with the cable strands shield is bent around the conical ring around the outside. The conical ring is then guided against a corresponding cone on a housing that also houses the connector, and the cable is finally secured against axial movement by a screw / flange connection.

Such attachment of the cable to a housing is complicated and expensive.

In this respect, the invention is based on the object of providing a possibility for the simplified fixing of an electrical cable with a peripheral shield on a corresponding housing, the shield should have an electrical connection to the housing (to ground).

The invention is based on the consideration that this goal can be achieved by a specially designed crimp sleeve which is formed in two parts and whose outer sleeve has a collar for locking in the housing.

• einer ersten, auf den Kabelmantel aufschiebbaren inneren Hülse
• einer zweiten, koaxial mit Abstand über die innere Hülse aufschiebbaren äußeren Hülse, die einen radial nach außen abstehenden, deformierbaren Kragen aufweist,
• wobei der Abstand von innerer und äußerer Hülse so bemessen ist, daß beide zwischen sich das über die erste Hülse vom Kabelende zurückgeschlagene freie Ende der Kabelabschirmung aufnehmen können und beide Hülsen durch einen Crimpvorgang gegenüber dem Kabel festlegbar sind.

In its most general embodiment, the invention accordingly relates to a crimp sleeve of the type mentioned at the outset with the following features:

• a first inner sleeve which can be pushed onto the cable sheath
• a second outer sleeve which can be pushed on coaxially at a distance over the inner sleeve and which has a radially outwardly projecting, deformable collar,
• the distance between the inner and outer sleeve is dimensioned such that both can accommodate the free end of the cable shield which is pushed back over the first sleeve from the cable end, and both sleeves can be fixed against the cable by a crimping process.

In other words, a first, usually cylindrical sleeve is pushed onto the cable sheath below the stripped (free) cable end at which the cable strands project freely above the cable sheath. The free end of the shield then protruding over the sleeve (in the direction of the free cable end) is then bent (put over the first sleeve), so that it then covers it on the outside. The second, outer sleeve is then pushed onto the first, inner sleeve and the shield arranged thereon, so that the shield now lies between the outer and inner sleeve. The dimensions of the sleeves are preferably chosen so that a certain fixation of the sleeves on the cable sheath or with respect to the shield in between is already ensured by static friction.

This is followed by a crimping process in which the sleeves are deformed together and fixed in place in relation to the cable (cable sheath).

The inner sleeve takes on a "support function". If it were missing, the deformability of the cable (cable sheath) would generally not be sufficient to ensure secure fixation with respect to the cable if the (outer) sleeve was crimped. Only with very rigid cables (outer sheath) could the inner sleeve possibly be omitted.

At the same time, the arrangement described achieves an electrical connection between the shield and the outer sleeve, which is now fixed in a corresponding locking groove of the housing via its radially outwardly projecting collar.

For this purpose, the housing can be designed with a corresponding undercut into which the radial free ends of the collar snap into place.

This eliminates any type of screw connection as is necessary in the prior art.

The collar can be designed in different ways. According to one embodiment, the collar is arranged at the free end of the outer sleeve, both for manufacturing reasons and for reasons of simpler locking.

It can be formed exactly radially (ie at an angle of 90 °) to the sleeve body. According to one embodiment, however, it is provided that the collar is flanged in the direction of the outer sleeve (i.e. bent back), so that there is essentially a U-shape for the collar in section, as will be explained in more detail with reference to the following exemplary embodiments .

In order to enable a simplified deformation of the outer sleeve when it is locked, it is further provided that the collar has radially extending and externally open incisions, so that the collar consists, as it were, of a large number of radially projecting resilient "tabs".

These "tabs", especially if they are statistically distributed over the circumference of the sleeve, enable a constant, light insertion force and at the same time create a large-area contact area with the housing and thus a large-area, secure ground contact for the shield clamped between the outer and inner sleeve.

In this way, interference voltages, which can never occur, for example, in the mentioned application area for a rotary position transmitter on a motor, can be optimally derived.

The material for the inner sleeve can be chosen arbitrarily. It can be made of plastic or metal. A metallic sleeve is preferred because it can be deformed particularly favorably in the crimping process. The outer sleeve must in any case consist of an electrically conductive material in order to ensure the desired ground connection between the shield and the housing. The use of a metal sleeve is particularly useful here.

Further features of the invention result from the remaining application documents, which also includes the following description of an exemplary embodiment.

Figur 1:

einen Schnitt durch eine erfindungsgemäße Crimphülse, die auf ein Kabel aufgecrimpt ist, im Eingriff in ein Gehäuse eines Drehstellungsgebers an einem Motor

Figur 2:

eine perspektivische Ansicht der äußeren Hülse nach Figur 1

Figur 3:

die Anordnung nach Figur 1 im gecrimpten Zustand.

The drawing shows - in a schematic representation - in

Figure 1:

a section through a crimp sleeve according to the invention, which is crimped onto a cable, in engagement in a housing of a rotary position transmitter on a motor

Figure 2:

2 shows a perspective view of the outer sleeve according to FIG. 1

Figure 3:

the arrangement of Figure 1 in the crimped state.

In FIG. 1, reference number 10 describes a cable which consists of a plurality of cable strands 12 which are surrounded by a metallic shield 14 and are assembled in a cable sheath 16.

The cable sheath 16 is cut away at the upper free end.

A first inner metal sleeve 18, which surrounds the cable sheath 16, has then been pushed onto the cable 10 prepared in this way, there being static friction between the two. The upwardly projecting end of the shield 14 is then flanged down around the inner sleeve 18 so that this free end of the shield 14 lies on the outer peripheral surface of the inner sleeve 18.

An outer sleeve 20, the geometric shape of which can be seen in FIG. 2 and will be described in more detail below, was then pushed over the free end of the cable 10, so that the configuration shown in FIG. 1 is established. The inner sleeve 18, the free end of the shield 14 and the outer sleeve 20 run coaxially to one another and the shield 14 lies between the sleeves 18, 20 with static friction.

The outer sleeve 20 has at the upper free end in FIG. 1 an outer, flanged collar 22 which, as shown in FIG. 2, has radially extending incisions 24, so that a total of eight radially extending tabs 22a are formed inside the collar 22.

It can be seen in particular from FIG. 1 that the collar — in section — has an approximately inverted U-shape.

FIG. 3 shows the crimp sleeve formed from the sleeves 18, 20 after the crimping process, that is to say after being fixed by clamping with respect to the cable 10. The connection between the crimp sleeve and the cable 10 is stationary.

After the crimping process, the cable formed with the crimp sleeve is now inserted into a housing 26 which is formed with a circumferential annular groove 28 on its inside, the annular groove 28 here having an undercut section and a surface section 28a extending obliquely inward therefrom.

When the crimp sleeve is pushed forward, the tabs 22a are pressed inwards when the housing projection 28b is reached, and when the annular groove 28 is reached, the tabs 22 jump outward into the annular groove 28 due to their deformability, the tabs 22a simultaneously abutting against the surface section 28a, so that a flat ground connection is achieved from the shield 14 via the outer sleeve 20 to the housing 26.

At the same time, the cable with the crimp sleeve is firmly locked in the housing 26. Further fixation measures can be omitted.

The cable 10 or the cable strands 12 are then connected to a connector. Depending on the area of application, connection to other components / devices is possible.

The two-part crimp sleeve according to the invention is not only of simple construction, but also enables rational and secure attachment of the associated cable 10 to the housing 26, while at the same time ensuring an optimal ground connection between the shield 14 and the housing 26.

Claims (6)

Crimp sleeve for an electrical cable (10) with a peripheral shield (14) against external electrical and / or magnetic interference, consisting of: 1.1 a first inner sleeve (18) which can be pushed onto the cable sheath (16), and 1.2 a second outer sleeve (20) which can be pushed on coaxially at a distance via the inner sleeve (18) and which has a radially outwardly projecting, deformable collar (22), wherein 1.3 the distance between the inner and outer sleeve (18, 20) is dimensioned such that both can accommodate between them the free end of the cable shield (14) knocked back over the first sleeve (18) from the cable end and both sleeves (18, 20) a crimping process against the cable (10) can be determined. Crimp sleeve according to claim 1, wherein the collar (22) is arranged at the free end of the outer sleeve (20). Crimp sleeve according to Claim 1 or 2, in which the collar (22) is flanged in the direction of the outer sleeve (20), so that there is essentially a U-shape in section. Crimp sleeve according to one of claims 1 to 3, in which the collar (22) has radially extending and outwardly open incisions (24). Crimp sleeve according to one of claims 1 to 4, wherein at least the outer sleeve (20) consists of metal. Crimp sleeve according to one of claims 1 to 5, wherein the outwardly projecting, deformable collar (22) of the outer sleeve is engaged in an annular groove (28) on the inner surface of a housing (26) and the electrical contact between the housing, outer sleeve and Manufactures cable shielding.

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