SE505160C2 - Highly flexible electrical cable with extensible casings of insulating material and process for making such a cable - Google Patents

Abstract

In a highly flexible cable with stretchable coverings (7; 10) made of insulating materials, at least the inner surface of a covering (10) is covered by a longitudinally-extending stretched and sintered film (11) made of a fluoropolymer e.g. PTFE. This improves the mobility and flexibility of the cable whilst reducing the stretchability of the covering. The film (11) is preferably stretched in one direction only up to 20 times its length before being sintered. This increases the porosity of the film which may be made more porous by perforating with needles. The outer conductor of the co-axial cable is made of wires (8) and glass-fibre threads (9). In another embodiment, a multiplicity of wires (1) are covered by a strip (2), netting (3), a sintered and stretched film of PTFE (5) and a cross-linked silicone rubber sheath (4). <IMAGE>

Description

The invention therefore has for its object to design cables and wires of the type described in such a way that they allow the required mobility in all directions but at the same time are sufficiently tensile resistant.

According to the invention, this object is achieved in that at least the inner surface of a casing is covered by a stretched and sintered foil of a fluoropolymer, the foil being designed as a strip with longitudinal edges and being connected to the casing. This measure gives the casing almost free rotation, for example over the cable core, over the conductor, the insulation, etc. Movements in the axial direction during simultaneous rotation can handle the cables or wires according to the invention without problems.

At the same time, for example, due to the required flexibility of a rubber material made and therefore inherently stretchable, the sheath of a cable according to the invention has increased tensile strength. These are properties which, for example, also in the field of handling equipment (robots) with where normally occurring long operating times and constantly changing movements make the cables or wires according to the invention advantageous to use.

Most of the motive forces transmitted axially and radially on the sheath of a cable according to the invention, for example, are immediately captured by the sheath, and the enclosed core or also a sensitive conductor is substantially relieved with respect to external forces.

However, the measure proposed according to the invention entails further advantages. Using a film of fluoropolymer, ie a material for use in a high temperature range, means at the same time increased protection, for example for a sensitive core, against temperature influences from outside and against chemically aggressive media. This has its special significance, for example for connection lines in surgical medicine, where the instruments after use as well as the connection lines must be sterilized at elevated temperatures, and these are subsequently expected to provide full operational readiness again. Normally present pipes meet all these requirements only for a short time or under certain conditions, as for example the sterilization process each time leads to adjacent elements in the pipe's layer construction being glued together, whereby the mobility and flexibility required for the use of this pipe is significantly affected. .

The longitudinal strip-shaped foil can be arranged on the inner surface of the cover in such a way that the strip edges abut each other. However, it is particularly advantageous in a further development of the invention if the longitudinal band edges overlap each other.

This provides extra safety in the manufacturing process and guarantees complete coverage of the inner surface of the housing and thus free movement. The strip-shaped foil used according to the invention expediently consists of only one fluoropolymer processed by paste extrusion and connecting rolling, for example fluoroethylene plastic, or a mixed polymer.

In order to achieve the required tensile strength in the longitudinal direction of the foil arranged in the layer construction of the cable or cable, it has proved advantageous to stretch this up to 2000%, preferably to between 300 and 10%. In addition, stretching can also take place across the strip direction. A corresponding one if this should prove expedient for carrying out the invention, for example to increase the porosity of the foil and thereby improve the mechanical connection with the casing.

The specific gravity of the film used according to the invention suitably amounts in the stretched or stretched and sintered state to 0.2 to 0.7 g / cm 3. if the stretching, which is particularly advantageous, has only taken place in the strip direction, then the ratio between the tensile strengths in the stretching direction of the strip-shaped foil and transversely in relation thereto is 10 - 15: 1.

In a further development of the invention, the thickness of the stretched and subsequently sintered strip-shaped foil amounts to 15 to 250 μm, preferably 30 to 100 μm. Compared with known elements for increasing the tensile strength, such as threads or fabric, this means a completely imperceptible measure in the layer construction of the cable or cable. Thus, for example, the required external dimensions with simultaneous significant improvement of the operating properties can be contained without difficulty.

In addition to a further stretching in the transverse direction to increase the porosity, the foil stretched and sintered in the strip direction can also be perforated, for example in such a way that the foil is passed through a needle roller before insertion.

The strip-shaped foil according to the invention is usable everywhere in a layer construction of a cable or a wire, as required. If, for example, the cable consists of a plurality of in turn flexible thin wires and if this core is covered by an extensible sheath, the band-shaped, stretched and sintered foil is suitably arranged on the sheath surface facing the core. In addition to the tensile strength of the per se stretchable and flexible sheath produced by the foil, the sheath is to a large extent freely rotatable over the core by this measure.

If the conduit has a coaxial arrangement of inner conductors and outer conductors, the strip-shaped foil is suitably arranged between the outer conductor and the final insulation. For the manufacture of a cable or wire according to the invention, such a method has proved expedient where the stretched and sintered strip-shaped foil before the application of the extensible casing is laid continuously on the length around the substrate in question, which may be 10 15 20 25 30 35 505 160 a cable core, a conductor and the like, and the insulating cover is formed directly on the foil. In connection with this, the material is cross-linked in the housing, whereby with the formation of the housing and / or with the connecting cross-bonding the strip-shaped foil arranged on the inside of the housing is glued or welded together with the housing. If, as in the case of silicone rubber, the rubber material is applied cold to the strip-shaped foil and only in connection with this a temperature treatment takes place to effect cross-linking, it can sometimes be advantageous to carry out a preheating of the already applied strip-shaped foil.

The invention will be described below in detail with reference to the cable and cable constructions shown in Figures 1 and 2 as exemplary embodiments.

Fig. 1 shows a multi-wire electric cable, whose wires 1, twisted or in bundle form, are held together by the band 2. nat, for example as a mechanical protection or because over this wire connection a net 3 is provided to provide shielding, when such a cable is to be used as a flexible connection cable for measuring or control devices. The sheath 4, for example consisting of a cross-linked silicone rubber, is due to the necessary flexibility designed in a corresponding manner and is from the ground also stretchable in the thread direction. This extensibility of the jacket is a disadvantage, as soon as the cable is subjected to tensile stresses during operation and the core enclosed by the jacket is not able to follow the strains of the jacket.

Admittedly, the extensibility of the jacket could be reduced by the corresponding addition of fillers to the jacket mixture, but this measure also results in changed material properties, which are absolutely impossible to dispense with, for example also due to the necessary high flexibility.

Here the invention is remedied in that the stretched and sintered foil 5, for example of a fluoroethylene polymer, is arranged between the jacket 4 and the net 3. foil 5 functions as an excellent sliding or releasing foil, 505 160 10 15 20 25 30 So that the jacket 4 is practically freely rotatable over the net 3; due to its mechanical connection with the inner surface of the jacket 4, it simultaneously takes over the function of a traction element in the cable construction, which means a significant restriction of the extensibility of the jacket 4. When the jacket 4 is applied, the jacket material cannot be pushed into the net 3 either. in order to have a negative effect on the flexibility of the cable.

The foil 5 has been stretched before sintering or at the same time as this temperature treatment. Such a foil, apart from the high tensile strength achieved, is therefore porous so that the solid connection with the jacket is thereby obtained during the application of the jacket material or during its crosslinking during temperature treatment. In addition, since the foil 5 extends over the entire inner surface of the casing 4 and in this way a plurality of fastening points distributed over the circumference of the cable secures the connection between the casing 4 and the foil 5, considerable tensile forces can be applied to the casing 4 supported according to the invention. is captured by this and the cable core is thus relieved with respect to tensile stresses. Despite the largely free movement of the jacket 4 over the net 3, the force bond between the jacket 4 and the core underlying it does not disappear.

Fig. 2 shows an electrical supply line in coaxial design. The inner conductor 6 designed as a cable conductor is enclosed by the flexible insulation 7, on which the outer conductor wires 8 and glass silk wires 9, for example for fixing on the surface, are arranged, for example, alternately next to each other. Above this core the flexible jacket 10 is arranged as an outer casing, the foil 11 taking over the task as a sliding or releasing foil between as proposed according to the invention, also here the jacket 10 and the outer conductors 8 and at the same time as a pulling element , which is mechanically firmly connected to the inner surface of the jacket over the entire circumference.

In other words, l2 denotes the overlapping point for the strip edges of the foil 11. This arises from the fact that for the arrangement of the longitudinally extending foil around the outer conductor 8, 9, for example by means of a tool which runs out in the shape of a strut, a bandwidth is chosen which is greater at this point than the circumference of the conduit.

In addition, the foil 11 applied with overlapping band edges has the task of protecting the coaxial conductor structure from increased temperature exposure, which, for example, as in connection with disinfection of medical devices, can lead to the outer conductor being glued to the jacket and / or the insulation the inner conductor and thus prevents the wire from becoming flexible and possible to reset.

To achieve flexibility, the electrical conductors shown in Figures 1 and 2 are suitably metal cable conductors. However, light waveguides can also be suitably used for cables or wires designed according to the invention. The stretched and sintered foil, which relieves the core with regard to mechanical stresses, constitutes an essential protection for the sensitive light waveguide.

Claims (14)

sos 160 8 10 15 20 25 30 35 PATENTKRAV Highly flexible electrical cable or equivalent cable with stretchable covers (4, 10) of insulating material arranged in the cable or cable structure, characterized in that at least the inner surface of a cover (4) (5, 11) has longitudinal bands edges and are connected to the housing. is covered by a stretched and sintered film of a fluoropolymer, which film is formed as Cable or cable according to claim 1, characterized in that the longitudinal band edges overlap each other. Cable or cable according to claim 1 or 2, characterized in that the strip-shaped foil (5, 11) consists of only one fluoropolymer or a mixed polymer processed by paste extrusion and connecting rolling. A cable or cable according to claim 1 or any one of the following claims, characterized in that the strip-shaped foil (5, 11) is stretched in the strip direction. Cable or wire according to claim 4, characterized in that the strip-shaped foil (5, 11) is stretched up to 2000%, and 1000%. Cable or cable according to claim 1 or one of preferably to between 300 subsequent claims, characterized in that the strip-shaped foil (5, 11) is stretched in the strip direction and across it. Cable or cable according to Claim 1 or one of the following claims, characterized in that the specific gravity of the strip-shaped foil (5, 11) in stretched and sintered condition amounts to 0.2 to 0.7 g / cm 3. . Cable or cable according to claim 1 or any of the following claims, characterized in that the ratio between the tensile strength in the strip-shaped direction of the strip-shaped film (5, 11) and the tensile strength across this direction amounts to 10-15: 1. Cable or wire according to claim 1 or any of the following claims, characterized in that the stretched and sintered foil (5, 11) has a thickness of 15 to 250 μm, preferably 100 μm. 10. A cable or wire according to claim 1 or any one of the following claims, characterized in that the stretched sintered strip-shaped foil (5, 11) is further perforated. Cable or wire according to claim 1 or any of the following claims, with a plurality of wires (1) joined to a core and an extensible (4) arranged thereon, that the band-shaped, arranged sheath is characterized therefrom, stretched and sintered foil (5) on the core-facing side of the mantle surface. Cable or wire according to claim 1 or any of the following claims, in the form of a coaxial design of inner and outer conductors (6, 8), characterized in that the insulation of the outer conductor (10) faces the outer conductor inner surface is provided with the stretched and sintered foil (11). A method of manufacturing a highly flexible cable or conduit according to claim 1 or any one of the following claims, with stretchable casings (4, 10) of insulating material arranged in the cable or conduit construction, wherein at least the inner surface of a casing (4) is covered of a stretched and sintered foil (5, 11) of a fluoropolymer, which foil is formed as a strip with longitudinal edges and is connected to the casing, characterized in that before the application of the extensible casing the stretched and sintered strip-shaped foil is laid longitudinally around the substrate - core, conductor - that the insulating casing is formed directly on the foil and in connection therewith its material is cross-linked, whereby with the formation of the casing and / or with the connecting cross-bonding "G65 10 505 160 is glued or the band existing on the inside miga the foil together with the cover. 14. A method according to claim 13, characterized in that the foil is heated before the cover is applied.