TECHNICAL FIELD The present invention relates to a cable protection and a method of fitting a cable protection according to the preamble of the attached claims 1 and 5 respectively.

STATE OF THE ART Cables, such as electric wires, which are liable to shaking and vibration, and to moisture and drenching with liquid, are usually laid in corrugated flexible protective tubing. A previously known practice in this respect is to provide some form of spacing means as protection against wear caused by rubbing against the inside wall of the tubing, see for example WO 200036614. The spacing means according to this publication takes the form of expansible foam material which is expanded to at least partly fill the space in the tubing. Foam material is mechanically sensitive and highly flexible in response to powerful stresses.

SUMMARY OF THE INVENTION The object of the present invention is to provide a cable protection and a method for fitting a cable protection which ensures a desired holding in position of a cable portion and is easy to fit.

Said object is achieved by means of the cable protection and the method according to the present invention, the characteristics of which are indicated by the attached claims 1 and 5 respectively.

SUMMARY OF THE DRAWINGS The invention is described below in more detail on the basis of an example of an embodiment with reference to the attached drawings, in which Fig. 1 is a perspective view of the cable protection according to the invention, fitted on a cable portion inside a flexible protective tube, Fig. 2 is longitudinal section through the cable protection, the cable portion and the protective tube along the line II-II in Fig. 3, and Fig. 3 is a cross-section through the cable portion and the protective tube, situated in front of the cable protection, along the line IH-III in Fig. 2.

PREFERRED EMBODIMENT The construction of the cable protection will be described with reference to all of the drawings. The cable protection according to the invention takes the form of spacing means situated between a cable portion 2 and a protective cover 3 in the form of a flexible corrugated tube whose smallest inside diameter considerably exceeds the outside diameter of the cable portion, with the result that an intermediate space is formed between the latter and the inside wall 4 of the protective cover. The cable portion takes the form, in the example depicted, of an electric cabling comprising in this example four wires each surrounded by an electrical isolation which needs protection against wear and abrasion. The cabling may itself be provided with a surrounding electrically isolating and mechanically protective cover which needs protection against wear and abrasion against the inside wall 4 of the protective tube. The cable portion may be intended to convey something other than electric current and may take the form of optical fibre, but may also alternatively be a fluid line whose cover needs protection against wear.

To this end, a heat-shrinkable tubing 5 which surrounds the cable portion 2 along at least parts of the latter' s length forms part of the cable protection. In addition to the heat-shrinkable tubing, the cable protection also comprises support means 6 extending between the cable portion 2 and the inside wall 4 of the outer tube 3. The support means take the form of at least two annular portions or ring portions 7, 8, which surround the cable portion 2 peripherally round the outside of the heat- shrinkable tubing 5, and a plurality, at least two in number, of spacing means 9-16 which constitute bridging portions between, on the one hand, the two annular portions 7, 8 and, on the other hand, the inside wall 4 of the outer tube 3. The number of spacing means may vary greatly and Fig. 1 depicts seven spacing means, whereas Figs. 2 and 3 depict eight spacing means. The number of spacing means and the width of each spacing means depend on the application concerned. In the case of two spacing means, relatively large segments of a circle need to be covered in order to provide sufficient support in all directions, but two spacing means may be sufficient in the case of small diameters, whereas three, four or five spacing means may be sufficient in many cases.

As may be seen in Figs. 1 and 3, the annular portions 7, 8 in the example depicted are entirely circular but exhibit small humps between the spacing means 9-16, thereby increasing the contact pressure and providing some resilience in the annular portions. At the same time, it is essential that the contact between the heat- shrinkable tubing 5 and the annular portion is firm, and it may be strengthened, for example, by some form of bonding means or undepicted protrusions so as to provide assured engagement with the heat-shrinkable tubing. The shape and consequent elasticity of the annular portions 7, 8 also cater for flexible adaptation to various diameters of cable. It is also a given prerequisite that the heat-shrinkable tubing is elastic. The annular portions 7, 8 may in their simplest form be closed ring portions with suitably adapted diameter, but they may alternatively be broken and closable, i.e. lockable, at two meeting and possibly overlapping ends 26, 27 to form closed rings by means of a lock 28, e.g. of the cable tie type, so that the ring portions can be adapted to different diameters of the cable 2.

At each support means, the two annular portions 7, 8 are situated at a suitably adapted axial distance from one another which is of at least the same order of magnitude as the outer diameter of the cable portion or preferably exceeds the same. The spacing means 9-16 each have two end portions 18, 19 firmly attached to or fully integrated with each of the annular portions, and have two intermediate portions 20, 21 connected articulately to the respective end portion and extending to a common bending joint 22 adapted to bearing against the inside wall 4 of the outer tube 3. In the example depicted, the intermediate portions 20, 21 are relatively straight, while the bending joint 22 may preferably have a rounded convex support surface 23 which abuts against a concave surface 23 in the form of a wave trough in the wavelike corrugation of the outer tube. The support also functions in the case of an entirely smooth or cylindrical outer tube, although the axial engagement will not be as firm.

A complete length of cable protection takes the form of a number of support means disposed as shown for example in Fig. 2 and situated at suitable spacing which may be a multiple of the axial extent of each support means. The heat-shrinkable tubing 5 extends with advantage in portions which are divided, whereby each portion of the heat-shrinkable tubing extends continuously over the length of each spacing means, i.e. from the outside of one annular portion to the outside of another annular portion. The heat-shrinkable tubing has a shrink direction which according to the invention runs axially, whereby the heat-shrinkable tubing contracts in an axial direction in response to a specific influence such as heat treatment exceeding a predetermined number of degrees but remaining below a maximum temperature, e.g. applying at the time of shrinking a temperature range of the order of 60-80 0C. An example of suitable material is cross-linked polyolefin.

According to an advantageous embodiment, the fitting of the cable protection is performed as follows.

In practice, the cable protection takes the form of a number of separate complete prefabricated units whereby each unit comprises a heat-shrinkable film portion 5 in tubular form or in the form of a rectangular piece, and the support means 6 which are connected to the heat-shrinkable film and take the form of the two ring portions 3 and the intermediate spacing means 9, 10. In the version with closed ring portions 3, the cable protection is applied by each unit of tubular heat-shrinkable film (with diameter exceeding the transverse dimension of the cable) being threaded on the cable from the latter' s end and moved in a longitudinal direction to a desired fitting position. In the version with broken, i.e. lockable, ring portions with free ends, as depicted in Fig. 3, and the heat-shrinkable film 5 in the form of a rectangular piece, the units in an open state are placed from the side directly on the intended location along the cable, followed by the ring portions 7, 8 and the heat-shrinkable film portion 5 being closed to form rings and tube respectively and being locked. In the fitted position, the support means have a stable internal position with a mutual intermediate space between the annular portions such that the spacing means 9-16 are situated in a radially inner position with the bending joint 22 and its support surface 23 with a diametrically inside dimension which is clearly less than the smallest inside diameter of the inside wall 4 of the outer tube 3. This fitting position is represented by chain-dotted lines in Figs. 2 and 3. Thus the two portions 9, 10 are at an obtuse and relatively large angle v. Each support means with its annular portions 7, 8 is firmly attached by suitable means to the heat-shrinkable tubing, but the latter is not firmly connected to the shell surface 25 of the cable portion and is therefore able to move somewhat in an axial direction.

When the support means are fitted, the cable portion 2 with the attached support means is drawn through the outer tube 3 to its desired functional position in the axial direction, i.e. with the ends of the cable portion normally protruding from the ends of the outer cover to cater for subsequent connection to desired components, e.g. in a motor vehicle. When the axial position has been assumed, the heat- shrinkable tubing or, in practice, the whole cable with support means and outer tube, is heated to, for example, 60-800C, i.e. exceeding the shrink temperature of the heat-shrinkable tubing. The result is that the tubing shrinks, i.e. contracts axially, carrying with it the two annular portions 7, 8 which are drawn towards one another so that the distance between them is reduced to about 75% of the original distance. This means that the spacing means 9-16 expand radially outwards, i.e. the two legs 20, 21 in each spacing means become angled at a smaller angle u, causing the bending joint 22 to move radially outwards to supportive contact of its support surface 23 with the inside wall 4 of the outer tube 3. Upon reduction of temperature the heat-shrinkable tubing remains in its shrunk state and hence the support means remain in their fully tensioned position depicted in Figs. 2 and 3.

The heating described above may be effected in various ways, e.g. in a prefabrication process whereby the cable with the outer cover continuously passes a heating station or prefabricated lengths are heated at said station. Heating may alternatively be effected by passing through the cable portion an electric current of such magnitude that the desired temperature rise is achieved by electrical resistance without any damage to insulating portions.

Suitable material for the spacing means of the cable protection was mentioned above. Suitable material is any form of polymer which withstands the temperature rise concerned without deformation, is of suitably designed rigidity and has some elasticity so that the jointing functions can be built into the material and the spacing means can to some extent absorb vibrations in order thereby also to protect the cable portion against vibration damage. The elasticity also provides a resilience which means that radial expansion will not be rigid and critical and that the two legs 9, 10 can assume a bent position if the annular portions move together more than is required for abutment of the support surface 23 against the outer tube.

The invention is not limited to the example of the embodiment described above and depicted in the drawings. It is for example conceivable that the cable protection is of different design and construction. It is conceivable that the number of annular portions is greater, e.g. three, resulting in twice as many spacing means per unit. The spacing means may take a different form, e.g. an arcuate shape, in which case the bending joint 22 may be omitted. This may be an advantageous shape if in the case of an outer tube with smooth inside wall it is desirable to allow axial movement of the cable portion and the spacing means. Instead of the ring portions taking the form of closed rings, they may be made open or divisible. This would make it possible for the support means to be fitted on the cable portion from the side. Any broken ring portions 7, 8 used may be divided so that each unit comprises two halves which are locked together or are fastened on the cable portion.