DE102011006848A1 - Cable and sensor arrangement or device comprising a cable - Google Patents

Abstract

Cable (1) and a sensor arrangement and a device comprising such a cable are described, the cable comprising a cable core (2) and a cable sheath (3), a material forming the cable sheath (3) comprising at least a first region (4, 6 ) and at least one second area (5), wherein the material of the first area (4, 6) is cross-linked and wherein the material of the second area (5) is not and / or less cross-linked than the material of the first area (4 , 6).

Description

State of the art

The present invention relates to a cable, and a sensor assembly and apparatus comprising such a cable.

Cables for making a conductive connection are known in the art. Especially in the automotive sector and there again in the engine compartment and chassis, cables are used, which consist of a conductive cable core and an insulating cable sheath. In order to prevent kinking of the cable by its own weight, in particular directly at its connection point, for example at a sensor or a control unit, so-called cable grommets are attached in the corresponding places in the prior art. Cable grommets are usually made of rubber or other plastic material shaped sleeves through which the cable runs and which cause local stabilization of the inner cable in the places where they are provided.

A disadvantage of such cable grommets is that depending on the dimension of the cable a correspondingly shaped cable grommet is necessary. Also, the space required by the cable grommets, depending on the shape and size often considerably, which is precisely in confined spaces, such. B. in the engine compartment of an automobile, is disadvantageous. Furthermore, such cable grommets may slip as long as they are merely pulled loosely over the cable. For example, if the cable grommets are connected to the cable by deformation, the cable may already be damaged during deformation. In addition, the cable is rigid by deforming, so that even here a kinking can occur at the resulting predetermined breaking point. A further disadvantage of cables with cable grommets from the prior art is that the cable grommets must be made separately and thus in addition to the cable, which significantly increases the technical, organizational and economic effort in cable production and processing.

Disclosure of the invention

The cable according to the invention with the features of claim 1 is characterized by a simplified structure, which, however, all known in the prior art disadvantages are overcome. The cable according to the invention comprises a cable core, which is formed from a conductive material and a cable sheath or a cable sheath, advantageously made of an insulating material. Further, the material of this cable sheath at least a first region and at least a second region, wherein the material of the first region is cross-linked and wherein the material of the second region is not and / or less strongly cross-linked than the material of the first region. Such cross-linked regions are created by a targeted cross-linking reaction of the sheath material. For this purpose, the cable sheath is formed of a material whose molecules z. B. functional, ie reactive groups, which can enter into a chemical compound with each other, for example, with just such groups of adjacent molecules directly, or via a coupling agent. By means of this crosslinking reaction or crosslinking reaction, the so-called "cross-linking", additional connections are created between the molecules of the cable sheath material, forming a more or less close-meshed braid. The cross-linking reaction can be selectively controlled so that the material can have more strongly cross-linked regions, ie regions with a high degree of cross-linking, and less strongly cross-linked regions, ie regions with a lower degree of cross-linking. Due to this cross-linking reaction, the material is stabilized at the correspondingly cross-linked regions in relation to regions with no or less cross-linked material, so that the cable according to the invention is more resistant to heat, chemicals or solvents, as well as to mechanical influences. By this cross-linking of the cable sheath, the cable can be stabilized and supported at predetermined locations. The higher the degree of crosslinking of the material, the more stable the material is at this point. By correspondingly varying the degree of crosslinking along different regions of the cable according to the invention and / or by enforcing the crosslinked regions with non-crosslinked regions, the stability or elasticity of the cable can be adjusted variably at intended locations, so that even during winding or bending, the cable and thus the cable core is protected from kinking or breaking. Also, the abrasion resistance of the cable is increased at the cross-linked areas, which can be dispensed with additional protective hoses. By forming cross-linked and non-and / or less strongly cross-linked regions along the inventive cable, additional cable grommets and protective tubes formed of separate materials become unnecessary. The stabilization of the cable takes place through the cable sheath itself, preferably without the cross section has to be changed or even increased. This saves weight and space and is therefore particularly advantageous in the automotive sector. Furthermore, thereby the processing of the cable, so z. For example, the installation of such a cable according to the invention facilitates, since both the manufacture and the provision of a suitable cable grommet, as well as the step of slipping the cable grommet, as well as their adequate Attachment to the cable, with the disadvantages mentioned, omitted.

The cable according to the invention thus has cross-linked and non-cross-linked and / or less strongly cross-linked regions. If the material of the cable is formed only from more strongly cross-linked and less strongly cross-linked regions, this results in a further advantage, in particular if the cable end is to be connected to a sensor or control unit. At such a connection point, it is particularly important to provide a cable reinforcement, since the cable tends otherwise by its own weight for kinking or breaking off. If the cable now has only weakly cross-linked and more strongly cross-linked areas, then the cable can be cut at any point, for B. to be connected to a sensor. In any case, the cable is significantly better stabilized by at least one less strongly formed crosslinking, that is, by a lower degree of crosslinking of the material, than in the case of a non-crosslinked region. Thus, the cable according to the invention is variable in use and unnecessary cable waste is avoided, which reduces the overall cost of the cable.

A significant increase in the stability of the cable material can already be achieved by cross-linking a corresponding region to a degree of crosslinking of preferably about 25%. Preferably, the degree of cross-linking of the more highly cross-linked region is at least 50% since the stabilizing effect of the cross-linked material is particularly pronounced.

Suitable materials that can be crosslinked z. For example, polymeric materials such as polyurethanes, polyacrylates, polysilicones, kukschuk compounds, epoxies and others. Depending on the location of the cable and depending on the required physical, chemical and mechanical stability of the cable, the person skilled in the art can easily find out suitable crosslinkable materials for the cable sheath. The cable according to the invention is characterized by a simplified structure, extraordinary physical, chemical and mechanical stability, or a variably adjustable according to the requirements of mechanical stability, as well as a reduced technical, organizational and economic effort in cable production and its processing.

The dependent claims show preferred developments of the invention.

The cable according to the invention is preferably characterized in that the more strongly crosslinked region of the cable sheath is provided at at least one end of the cable. Since the cable end is usually provided for connection to any plugs, devices, sensors, etc., a stabilization of the cable end is advantageous to prevent kinking of the cable or a cancel thereof by its own weight just at the junction or prevent.

The cross-linked areas of the cable sheath can be provided at any points of the cable. Thus, the stabilization of the cable can be made flexibly at designated locations and be tailored according to the purpose of use. It is preferred, however, if several cross-linked regions are equally spaced along the cable. This has the advantage that the force exerted by the weight of the cable, as well as any torsional forces evenly over the entire cable length, which causes a very good stabilization of the cable and also allows a uniform winding or curving of the cable.

It is further preferred if the cable sheath comprises at least one inner layer and one outer layer, wherein the material comprising the crosslinked region and the non-crosslinked and / or less strongly crosslinked region forms the outer layer. Such a multi-layer structure of the cable according to the invention is advantageous, since thus in particular the physical and chemical properties, such as the elasticity or bendability or chemical or solvent resistance of the cable, but also its mechanical stability, can be adjusted. The individual layers of the cable sheath can be formed from the same or different materials. Since, in particular, the resistance of the outer layer of the cable sheath is decisive for the mechanical stability of the cable, it is also advantageous if this outer layer, ie the layer facing away from the cable core, has the stabilizing, cross-linked and non-and / or less strongly cross-linked regions. This also makes it possible to form the inner and outer layers of different materials. In this case, it is advantageous to form the less heavily stressed inner layer, ie the layer facing the cable core, from a less expensive and possibly less resistant material, and the outer layer from a higher quality material, since the outer layer is cross-linked by the formation of and not and / or less strongly cross-linked areas contributes significantly to the stabilization of the cable material and in this way also a sufficient stability of the cable is achieved. This brings a significant cost savings of the cable according to the invention.

It is also advantageous if the cable sheath in a boundary region in which the stronger cross-linked region in the less strong, and in particular in the non-crosslinked region merges, having an additional reinforcing element. Such additional reinforcing elements stabilize the boundary region of the stabilized, more strongly crosslinked region of the cable sheath and of the region of the cable sheath that is not stabilized by reduced cross-linking. This is particularly advantageous if the cable should have a curvature in the boundary region or should be bent, since it additionally stabilizes the cable. Furthermore, the attachment of an additional reinforcement element is advantageous if the cable is to be additionally protected against acting forces against kinking or breaking off. Additional reinforcing elements are, for example, clip elements, shrink-on elements or clamping elements.

The cable sheath material can be cross-linked in the radial direction of the cable at designated locations at any depth. Often a uniformly deep cross-linking and in this case a complete cross-linking of the cable sheath material at the intended locations is desired. This ensures a very high, homogeneous stabilization of the cable around the cable. It is advantageous if the material forming the cable sheath is cross-linked in the radial direction at different depths. As a result, z. B. in a terminal region of the cable whose stability are promoted by particularly deep cross-linking of the cable sheath material in the radial direction, while at some distance to this connection area a middle stabilization, ie a lower cross-linking depth is sufficient, which also allows a certain turn of the cable. If the material forming the cable sheath has cross-linked regions which are cross-linked at different depths in the radial direction, then the mechanical stability of the cable can be controlled specifically both locally and with respect to its size. Thus, a cable is obtained, the defined, flexible, that is not stabilized and thus not cross-linked areas and / or less stabilized, ie partially cross-linked in the radial direction areas or highly stabilized, ie in the radial direction completely cross-linked areas includes that on the local Conditions and requirements are coordinated.

It is further advantageous if a cross-linked region of the cable sheath of the cable according to the invention is provided at least along part of the circumference, preferably at least along half the circumference of the cable sheath, and more preferably completely along the circumference of the cable sheath. Complete cross-linking of the cable sheath material along the entire circumference in the cross-linked area will result in uniform stabilization of the cable. This is especially in places of the cable act on the torsional forces or other mechanical forces, advantage, since these points are thus sufficiently stabilized and the cable is protected from kinking or cable breakage. Alternatively, if the cable sheath of the cable according to the invention z. B. be cross-linked only in one half of the cable sheath surface in a designated area. As a result, a winding or bending of the cable according to the invention at its underside at least partially possible, which facilitates the winding or winding of the cable. Also by this formation of cross-linked areas of the cable sheath of the cable according to the invention, the mechanical stability of the cable can be selectively controlled both locally and in terms of their size.

Furthermore, the invention relates to a sensor arrangement comprising a sensor and a cable as described above. Such a sensor arrangement is used for example in an automobile, and here preferably in the engine compartment or chassis. The cable according to the invention thus serves as a link between the sensor on one side and, for example, a control device or read-out device on the other side. By the cross-linked areas of the cable sheath of the cable according to the invention a stable, durable and reliable connection between any components is achieved. For this purpose, the cable according to the invention advantageously has a cross-linked region directly at the connection point to the sensor or to the control unit, that is to say directly at at least one end of the cable. This effectively prevents kinking or breaking of the cable at its junction.

The cable according to the invention can be provided for any devices in which hitherto conventional cables produce a conductive connection. Due to its design with cross-linked and non-cross-linked areas of the cable sheath, the stability of the cable is specifically increased in a simple manner, whereby a cable with a simplified structure, high physical, chemical and mechanical stability is obtained, the uncomplicated, without high technical complexity to produce and to process.

Brief description of the drawings

Hereinafter, embodiments of the invention will be described in detail with reference to the accompanying drawings. In the drawings:

1 a schematic representation of a first embodiment of the invention

2 a schematic representation of a second embodiment of the invention

3 a cross-section through a cable according to a third embodiment of the invention

4 a cross-section through a cable according to a fourth embodiment of the invention and

5 a schematic representation of the method for producing the cable according to the invention

Embodiments of the invention

In the figures functionally identical components are represented by the same reference numerals.

1 shows a sensor arrangement according to a first embodiment of the invention. The sensor arrangement has a sensor 9 and one directly with the sensor 9 connected cable 1 on. The cable 1 points in his cable sheath 3 cross-linked areas 4 and 6 on, with the cross-linked area 4 at the end 7 of the cable 1 directly with the sensor 9 communicates and wherein the crosslinked area 6 along the cable 1 is further spaced apart. The cable points in its cable sheath 3 furthermore not and / or less strongly cross-linked areas 5 on. The cross-linked area 4 is also more cross-linked than the cross-linked region 6 wherein the crosslinking degree of the crosslinked region 4 further in the direction of the sensor 9 rises and at the connection area to the sensor 9 ie at the end 7 of the cable 1 , maximum is. This is through in the direction of the sensor 9 increasing arrows are shown, which schematize the increase of the modulus of elasticity. Through this training of the cross-linked area 4 is guaranteed that the cable 1 permanent and sufficiently strong with the sensor 9 is connected and also not kinked or broken off by its own weight, since the force due to the weight of the cable 1 over the entire cross-linked area 4 distributed. The additional crosslinked area 6 also promotes the stability of the cable 1 , By the spacing of the crosslinked area 6 from the cross-linked area 4 , or through the enforcement of the cross-linked areas 4 . 6 with the non-crosslinked and / or less strongly crosslinked area 5 , there will be some flexibility of the cable 1 and thus a bend of the same allows and promoted, which is also a kinking or breaking the cable 1 prevents and increases its abrasion resistance just at the cross-linked areas.

The second embodiment of the invention in 2 has a cable 1 with three non and / or less strongly cross-linked areas 5 on, with the cable sheath 3 in a border area 8th in which the crosslinked area 6 on the left side in the not and / or less strongly cross-linked area 5 goes over, an additional reinforcement element 10 having. This stabilizes the border area 8th additionally, creating a permanent, stable connection between the cross-linked area 6 and the non-crosslinked and / or less heavily crosslinked area 5 of the cable according to the invention 1 , causing a kinking or breaking of the cable 1 prevented and a fixation of the cable is achieved.

3 shows a cross section through a cable 1 according to a third embodiment of the invention. Here's the cable core 2 from an inner layer 3a of the cable sheath 3 surrounded, in turn, by an outer layer 3b of the cable sheath 3 is surrounded. The outer layer 3b is completely cross-linked at the intended locations along its entire circumference and in the radial direction. This two-layer structure allows a particularly good coordination of the physical, chemical and mechanical properties of the cable according to the invention 1 , So can the outer layer 3b sufficient stability of the cable according to the invention 1 deploy while the inner layer 3a For example, an additional solvent resistance or temperature resistance brings. This is important when the cable 1 z. B. in a range of elevated temperature such. B. in the combustion chamber of an automobile, is provided. Alternatively, the desired stability can be predominantly or exclusively through the outer layer 3b be provided, which consists of a, corresponding to the requirements, higher quality material, while the less stressed inner layer 3a of the cable 1 can be formed from a less high quality material, which causes a huge cost savings.

4 shows a cross section through a cable 1 according to a fourth embodiment of the invention. Again, there is again a two-layered construction of the cable sheath 3 to see. The outer layer of the cable sheath 3 also has a first area 3c and a second area 3d on. Only the area 3c the outer layer of the cable sheath 3 is strongly cross-linked. This promotes on the one hand the stability of the cable 1 and on the other hand gets a partial flexibility of the cable 1 so the cable 1 Overall, more bendable remains, causing a kinking or breaking off of the cable 1 , even when winding or winding the same, prevents.

5 is a schematic representation of the method for producing the cable according to the invention 1 , The device shown here 11 shows a cable 1 on certain designated areas 4 . 6 . 13 , between crosslinking units 12 is performed. These crosslinking units 12 are provided to the jacket material of the cable 1 at the designated areas 4 . 6 . 13 cross-linking. Examples of such crosslinking units 12 are z. B. exposure devices or heaters. In addition, shading devices (not shown) may also be provided to protect certain areas from exposure, allowing targeted formation of crosslinked and non-crosslinked or less heavily crosslinked areas. The choice of crosslinking unit 12 depends on the cross-linking material of the cable sheath 3 , The cable material is therefore at the querzuvernetzenden points 4 . 6 . 13 , designed so that the action of the crosslinking units 12 cross-linking the material directly or with the aid of a coupling agent causes. Suitable crosslinking materials are, for example, polysilicones or polyurethanes, wherein as coupling agent for a polyurethane z. B. a polyalcohol can be provided.

Claims (10)

Cable comprising a cable core ( 2 ) and a cable sheath ( 3 ), wherein a cable sheath ( 3 ) forming material at least a first area ( 4 . 6 ) and at least one second area ( 5 ), wherein the material of the first area ( 4 . 6 ) and wherein the material of the second region ( 5 ) is not and / or less strongly cross-linked than the material of the first area ( 4 . 6 ). Cable according to claim 1, characterized in that the cross-linked region ( 4 ) of the cable sheath ( 3 ) at least one end ( 7 ) of the cable is provided. Cable according to claim 1 or 2, characterized in that several cross-linked regions ( 4 . 6 ) are equally spaced along the cable. Cable according to one of the preceding claims, characterized in that the cable sheath ( 3 ) at least one inner layer ( 3a ) and an outer layer ( 3b ), the cross-linked region ( 4 . 6 ) and the non-crosslinked area ( 5 ) comprehensive material the outer layer ( 3b ). Cable according to one of the preceding claims, characterized in that the cable sheath ( 3 ) in a border area ( 8th ) in which the crosslinked area ( 4 . 6 ) into the uncrosslinked area ( 5 ), an auxiliary reinforcement element ( 10 ) having. Cable according to one of the preceding claims, characterized in that the cable sheath ( 3 ) forming material is cross-linked in the radial direction at different depths. Cable according to one of the preceding claims, characterized in that the cross-linked region ( 4 . 6 ) at least along a part of the cable sheath ( 3 ), preferably at least along half the circumference of the cable sheath ( 3 ), more preferably completely along the circumference of the cable sheath ( 3 ), is provided. Sensor arrangement comprising a sensor ( 9 ) and a cable ( 1 ) according to any one of the preceding claims. Sensor arrangement according to claim 8, characterized in that the sensor ( 9 ) immediately at the first cross-linked area ( 4 ) of the cable sheath ( 3 ) is arranged. Device comprising a control device and a cable ( 1 ) according to one of claims 1 to 7.

Images