DE102017207656B4 - Cable and use of same as medical cable - Google Patents

Abstract

Cable (2) with an outer sheath (10) made of silicone and a cable core (4), with an intermediate sheath (8) made of a fluoropolymer being arranged as a barrier layer between the cable core (4) and the outer sheath (10), characterized in that between a heat-resistant film (6) is arranged between the line core (4) and the intermediate jacket (8) as a heat shield and has at least one metal layer, that the line core (4) has a number of individual elements (12) which are surrounded by an inner jacket (18). , which fills the gaps between the individual elements (12), with the intermediate jacket (8) surrounding the inner jacket (18) with the interposition of the foil (6) and that the cable (2) has a structure with the following components in direct succession: cable core (4th ) - inner jacket (18) - heat-resistant foil (6) - intermediate jacket (8) - outer jacket (10).

Description

The invention relates to a cable and its use as a medical cable.

Electrical cables in the medical field often have to be repeatedly sterilizable in order to meet medical hygiene requirements. For sterilization, the cables are typically placed in an autoclave in which the cable to be sterilized is exposed to steam at elevated pressure and a temperature of typically over 130° Celsius for a longer period of time.

Such cables for use in the medical field typically have a silicone outer jacket. The problem with this is that moisture can penetrate into and through the jacket during sterilization.

Proceeding from this, the invention is based on the object of specifying a cable, in particular for use in the medical field, which can be sterilized several times without moisture penetrating the interior of the cable.

From the DE 10 2005 006 332 A1 discloses a medical cable according to the preamble of claim 1, in which a PFE intermediate sheath is provided, which is surrounded by a braid and finally by a silicone outer sheath.

The DE 10 2006 025 269 A1 describes a flexible electrical cable that also has a braid of highly abrasion-resistant threads.

U.S. 2015/0 075 838 A1 describes a data cable with shielded twisted pairs of wires.

The object is achieved according to the invention by a cable with the features of claim 1. The cable has an outer sheath made of silicone and a cable core, with an intermediate sheath made of a fluoropolymer being arranged as a barrier layer between the cable core and the outer sheath.

The cable is intended in particular for medical applications.

The intermediate layer of the fluoropolymer jacket ensures that any moisture that penetrates through the silicone outer jacket during sterilization does not reach the inner core of the cable. The intermediate jacket therefore forms a vapor barrier.

Silicone outer casing is understood here to mean that the outer casing consists of a silicone polymer or at least largely (>50% by weight, especially >90% by weight). Correspondingly, the term fluoropolymer intermediate jacket is understood to mean that it consists of a fluoropolymer or at least largely (>50% by weight, especially >90% by weight).

In addition, the use of a fluoropolymer for the intermediate jacket also achieves sufficient heat resistance of the intermediate jacket. When the silicone outer sheath is applied, heat treatment (vulcanization) of the silicone outer sheath usually takes place. The temperatures here are typically > 110° C. and reach up to about 500° C. By choosing a fluoropolymer, the intermediate jacket can also withstand these high temperature stresses during the application of the outer jacket. The intermediate jacket can therefore withstand a temperature load of typically more than 200° C., preferably more than 250° C. or more than 300° C., at least for the time when the outer jacket is applied. In particular, a softening point, a melting temperature or a decomposition temperature of the fluoropolymer is above these indicated temperatures.

In addition, a heat-resistant foil is arranged as a heat shield between the cable core and the intermediate sheath. The configuration is based on the consideration that very high temperatures also occur for the application of the intermediate jacket made of the fluoropolymer. The intermediate jacket - as is usually the case with the silicone outer jacket - is typically applied by extrusion. A so-called hot extrusion is required to form the intermediate jacket, in which temperatures, for example, in the range of over 300° C., especially temperatures in the range of 380° to 400° C., occur. Heat-resistant film is now understood to mean that the film withstands such a temperature load at least during the application of the intermediate jacket during extrusion.

The heat-resistant film acts as a heat shield in that it at least partially shields the interior of the cable, which is surrounded by the film, from the heat when the intermediate sheath is applied. Depending on the use of the materials that are used inside the cable, for example for conductor insulation etc., undesirable reactions or outgassing of the materials can occur at such high temperatures. Such outgassing could undesirably lead to bubbles forming under the intermediate jacket, which locally bulge the intermediate jacket to the outside len, whereby a desired roundness of the cable would no longer be guaranteed.

The heat-resistant foil has at least one metal layer. According to a first embodiment variant, the foil itself is designed as a metal foil.

In a preferred embodiment, the film is a metal-coated polymer film that has a carrier layer made of a preferably heat-resistant polymer, on which a metal coating is applied.

The carrier layer is in particular a polyimide layer. Such a metal-clad polyimide film is particularly advantageously suitable as a heat shield.

If the term foil is used here, it is understood to mean that it has a thickness of typically 10 to 100 μm or up to several 100 μm. The film is also attached either helically or longitudinally around the cable interior.

The line core usually has individual elements that are specially designed as wires. Each individual element therefore has a central conductor, for example a stranded conductor, which is surrounded by wire insulation. In order to achieve a configuration of the cable that is as circular as possible, the individual elements are surrounded by an inner jacket, which preferably fills the gaps between the individual elements. The inner jacket is further surrounded by the fluoropolymer intermediate jacket under the intermediate layer of heat resistant foil.

The inner casing preferably consists in turn of a polymer which is heat-resistant up to at least 100° Celsius and preferably up to at least 200° Celsius. This ensures that the inner jacket withstands the temperatures when the intermediate jacket and the outer jacket are applied. The plastic does not soften, melt or decompose up to the specified temperatures.

A silicone polymer is expediently used for the inner jacket. For example, the same silicone polymer is used for the inner jacket as for the outer jacket. The inner jacket is therefore a silicone inner jacket. Silicone inner jacket is understood to mean that the inner jacket consists for the most part of a silicone polymer. In particular, the inner jacket consists of at least 50% by weight, preferably at least 90% by weight, of a silicone polymer. In particular, the inner jacket consists of 100% silicone polymer.

Alternatively, the inner jacket consists of a pressure-extruded fluoropolymer, in particular an ETFE or FEP. The fluoropolymer known under the trade name Fluon AR-8018A is preferably used.

• PFA (Perfluoralkoxy-Polymer),
• PTFE (Polytetrafluorethylen),
• FEP (Tetrafluorethylen-Hexafluorpropylen-Copolymer),
• ETFE (Ethylen-Tetrafluorethylen),
• MFA (Perfluoralkoxy-Polymer)

One or more of the following fluoropolymers is preferably selected as the fluoropolymer for the intermediate jacket:

• PFA (perfluoroalkoxy polymer),
• PTFE (polytetrafluoroethylene),
• FEP (Tetrafluoroethylene-hexafluoropropylene copolymer),
• ETFE (ethylene tetrafluoroethylene),
• MFA (perfluoroalkoxy polymer)

A compound made from one of the fluoropolymers mentioned, in particular from ETFE with a fluoroelastomer, is preferably used as the material for the intermediate jacket. Good (bending) flexibility is obtained by adding a fluoroelastomer. The proportion of the fluoroelastomer is preferably in a range from 40 to 50% by weight

The cable is expediently also finally formed by the components line core, inner sheath, heat-resistant film, intermediate sheath and outer sheath, which are built on top of one another in the order given and each surround one another concentrically.

The line core in turn preferably consists of only a number of wires. If necessary, additional filling strands can be provided if necessary. In this case in particular, the inner jacket can be ring-shaped without filling up the gaps between the individual elements.

The cores are optionally signal cores for the transmission of data signals and/or supply cores for electrical power transmission, ie for supplying electrical components with electrical energy. In principle, there is also the possibility that light-guiding elements (optical fibers) or hoses, etc., for example, are arranged as further individual elements in addition to these cores.

The diameter of such cables, specifically for use in the medical field, is typically in the range from a few mm to a maximum of a few 10 mm. For example, the outer diameter of the outer jacket is 2mm to 30mm mm. However, the structure of the cable described here is not limited to such diameter ranges.

Overall, the structure of the cable described here provides a cable which can be repeatedly treated in an autoclave for sterilization purposes at temperatures of at least 130° Celsius and increased pressure without the cable being damaged. In particular, the penetration of moisture to the cable core is reliably prevented by the fluoropolymer intermediate sheath.

An embodiment of the invention is explained in more detail below with reference to the single figure. This shows a cross section of a cable.

The cable 2 shown in the figure has a line core 4 which is initially surrounded by a heat-resistant foil 6 , then by an intermediate jacket 8 and finally by an outer jacket 10 . The line core 4 in turn has a plurality of individual elements 12 designed as wires, which are stranded together, for example. Each individual element 12 is formed by a central conductor 14, in particular a stranded conductor, and wire insulation 16 surrounding it.

An inner jacket 18 is arranged around these individual elements 12 and fills individual intermediate regions 20 between the individual elements 12 . A central gusset area between the individual elements 12 is usually free of material or a central (filling) strand is arranged. The inner casing 18 is therefore in this respect designed as a solid casing. The inner sheath 18 has a circular circumference and thus ensures that the cross section of the cable 2 is as circular as possible. The inner sheath 18 preferably consists of a silicone polymer.

The outer jacket 10 also consists of a silicone polymer.

The intermediate jacket 8 is arranged between the inner jacket 18 and the outer jacket 10 and consists of a fluoropolymer or at least has a fluoropolymer.

A compound made from one of the fluoropolymers mentioned, in particular from ETFE with a fluoroelastomer, is preferably used as the material for the intermediate jacket. Good (bending) flexibility is obtained by adding a fluoroelastomer. As a result, a high level of bending flexibility of the cable 2 is obtained overall. Fluorinated elastomers, which are also known under the term fluorinated rubber, are generally referred to as fluoroelastomers. As the material for the intermediate cladding 8, for example, that under the trade name of Fluon AR-8018A (Fluon is a trademark of Asahi Glass Company, Ltd.) is used.

The heat-resistant film 6 is designed in particular as a metal-laminated film which has a carrier layer 6a specifically made of a polyimide and a metal layer 6b applied thereto, in particular made of aluminum. The metal layer 6b is in particular oriented outwards in the direction of the intermediate casing 8 .

The outer diameter of the cable 2 and thus of the outer sheath 10 is usually in a range between 2 mm and 30 mm. The outer jacket 10 has a wall thickness that is typically greater than that of the intermediate jacket 8. The wall thickness of the outer jacket 10 is usually a multiple of the wall thickness of the intermediate jacket 8. The wall thickness of the outer jacket 10 is, for example, typically in a range from 0.3 mm to 2 mm, the wall thickness of the intermediate shell 8 is typically in the range from 0.3 mm to 2 mm. Furthermore, the line core 4 has a diameter which is formed in particular by the inner jacket 18 and which is preferably in the range from 1 mm to 30 mm.

The cable 2 is expediently used in the medical field, for example for supplying power to electrical devices in operating theaters, medical practices, etc. The devices supplied with the cable 2 are typically small devices that are regularly sterilized together with the cable 2 . Alternatively, the cable 2 is a connecting cable that is regularly sterilized. For sterilization, the cable 2 is placed in a so-called autoclave and exposed to steam there for a predetermined period of time under increased pressure and at a temperature of typically more than 130° Celsius. With this treatment, moisture can penetrate through the outer shell 10, but not through the intermediate shell 8, which forms a vapor barrier.

In the manufacture of the cable 2, the inner sheath 18 is first applied specifically by extrusion to the individual elements 12 that have previously been stranded together, for example. The foil 6 is then placed around the inner jacket 18, for example by winding it or also arranged longitudinally. Subsequently, the intermediate jacket 8 made of the fluoropolymer is also applied by extrusion, typically by means of a hot extrusion at 380° to 400 degrees Celsius. Finally, the outer jacket 10 is extruded onto this intermediate jacket 8 . The applied silicone outer jacket 10 becomes more typical after extrusion wise still exposed to a temperature treatment at temperatures of >110° Celsius to about 500° Celsius for vulcanization/crosslinking.

Claims (8)

Cable (2) with an outer sheath (10) made of silicone and a cable core (4), with an intermediate sheath (8) made of a fluoropolymer being arranged as a barrier layer between the cable core (4) and the outer sheath (10), characterized in that between a heat-resistant film (6) is arranged between the line core (4) and the intermediate jacket (8) as a heat shield and has at least one metal layer, that the line core (4) has a number of individual elements (12) which are surrounded by an inner jacket (18). , which fills the gaps between the individual elements (12), with the intermediate jacket (8) surrounding the inner jacket (18) with the interposition of the foil (6) and that the cable (2) has a structure with the following components in direct succession: cable core (4th ) - inner jacket (18) - heat-resistant foil (6) - intermediate jacket (8) - outer jacket (10). cable (2) after claim 1 In which the film (6) is designed as a metal-clad polymer film with a carrier layer on a heat-resistant polymer. cable (2) after claim 2 , in which the carrier layer is formed from a polyimide. Cable (2) according to one of the preceding claims, in which the inner sheath (18) consists of a heat-resistant polymer which is heat-resistant up to at least 100°C. cable (2) after claim 4 , in which the inner casing (18) consists of a silicone. Cable (2) according to one of Claims 1 until 5 wherein the fluoropolymer uses PFA (perfluoroalkoxy polymer), PTFE (polytetrafluoroethylene), FEP (tetrafluoroethylene-hexafluoropropylene copolymer), ETFE (ethylene-tetrafluoroethylene), or MFA (perfluoroalkoxy polymer). cable (2) after claim 6 , in which a compound made of one of said fluoropolymers and a fluoroelastomer is used for the intermediate jacket (8). Use of a cable (2) according to one of the preceding claims as a medical cable (2) which is intended for regular sterilization in an autoclave.

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