EP0151904B1 - Insulated electric cord - Google Patents

Description

The invention relates to an electrical line with halogen-free, heat-resistant and flame-retardant insulation, which has improved resistance to liquid media and mechanical stress.

For the production of insulated, electrical cables that release as little smoke as possible and no corrosive and toxic gases in the event of fire, halogen-free insulation materials, e.g. Polyethylene or ethylene-propylene terpolymer used. It is also known that the solvent resistance and also the short-term temperature resistance of these materials can be improved by crosslinking. As is also known, the flame resistance of halogen-free insulation materials is at least largely achieved by adding metal hydrates (e.g. aluminum oxytrihydrate, magnesium hydroxide).

However, electrical lines with halogen-free insulation containing such hydrates have the disadvantage of reduced resistance to certain liquid media, e.g. liquid hydrocarbons such as gasoline, mineral oil and solvents. This means that after long periods of storage in mineral oils, e.g. Oil ASTM No. 2 or fuels, e.g. Gasoline, swell more than hydrate-free materials and its mechanical strength is reduced more. When stored in water for a long time, hydrated insulation materials also tend to absorb more water. This leads to a deterioration in their electrical properties, namely a reduction in the insulation resistance and an increase in the dielectric constant, which is very undesirable.

GB-A-1 583 956 describes insulated lines, the insulation of which is flame-retardant, halogen-free and two-layer. The inner insulation layer consists of crosslinked olefin polymer filled with Al (OH ₃₎ , while the outer insulation layer is made of nylon 6, among other things. However, nylon 6 is not flame-retardant and has a high moisture absorption, so it is not very suitable for the present purpose.

It is also known to produce lines with a first insulation layer made of thermoplastic polyvinyl chloride and a second layer made of polyamide or with a first layer made of olefin polymer and a second layer made of a crosslinked vinylidene fluoride copolymer. However, these two-layer insulation materials also contain halogens, which form corrosive gases in the event of a fire.

Furthermore, two-layer insulation, the outer layer of which has a protective effect, is known, e.g. from DE-A-3 012 745 and DE-B-2 807 406. The former describes moisture-resistant, lubricious insulation for electromagnetic applications, a polyamide, for. B. polylaurin lactam, is used as a top layer on a thermosetting base layer. The latter relates to an improved outer protective layer in the insulation of the electrical connection line in household appliances and recommends unsaturated polyesters (vialkyd lacquer) or polyimides as plastics.

The aim of the present invention is to eliminate the disadvantages mentioned of the previously known heat-resistant, flame-retardant, halogen-free, insulated lines. This is achieved in that a first halogen-free insulation material through a second insulation material made of polyamide 6.6, ie polyhexamethylene adipamide or polyamide 12, ie polylaurine lactam, a thermoplastic, halogen-free polyester elastomer, e.g. B. Hytrel ^R 4056 from DuPont, or an aromatic, halogen-free polyether, such as PEEK ^R from ICI, is additionally protected. If the material for the outer protective layer is selected more favorably, the abrasion resistance and the lubricity of the electrical line insulated in this way in two layers can also be improved.

The first insulation layer is advantageously produced in a thickness of approximately 0.2 to 2 mm, while the outer protective layer can be relatively thin and is generally approximately 0.1 to 0.5 mm.

example 1

A copper strand made of 50 individual wires with a diameter of 0.25 mm and a total cross section of 2.5 mm ² and a diameter of 2.1 mm was made in the usual way with a first insulation layer made of «Radox filled with up to 50% aluminum oxytrihydrate -125 »copolymer (Radox ^R 125 is the registered trademark for polyolefin copolymers from Huber & Suhner AG), so that the outside diameter of the line was 3.6 mm. The insulation layer was then crosslinked by exposure to high energy electron beams at a dose of 50 to 200 kGy (5 to 20 Mrad). A 0.1 mm thick protective layer made of polyamide 6.6 (eg type Zytel ^R BK 157, supplier DuPont) was placed on the electrical line thus obtained, so that a double-insulated electrical line with an outer diameter of 3.8 mm was generated.

The double layer insulated line was stored in ASTM No. 2 mineral oil at a temperature of 100 ° C for 72 hours and in diesel oil at a temperature of 70 ° C for 168 hours. Immediately afterwards, the line was subjected to a winding test around a metal mandrel, the diameter of which corresponds to three times the line diameter, without the samples showing any change.

The abrasion test according to the German standard VG 95218, with a 0.3 mm thick blade, loaded with 0.6 kg, showed a maximum abrasion depth of 0.2 mm for 1000 abrasion strokes, compared to 0.5 mm for the unprotected insulation layer.

The flame retardancy test according to the publication IEC 332-1 was optimally fulfilled by the double-layer insulated cable.

Example 2

A copper strand made of 50 individual wires with a diameter of 0.25 mm and a total cross section of 2.5 mm ² and a diameter of 2.1 mm was coated in the usual way with a first insulation layer made of «Radox- filled with up to 50% aluminum oxytrihydrate. 125 »copolymer, so that the outer diameter of the line was 3.2 mm. The isolation layer was then crosslinked by exposure to high energy electron beams at a dose of 50 to 200 kGy (5 to 20 Mrad). A 0.3 mm thick protective layer made of L20H polyamide from Ems-Chemie AG was placed on the electrical line thus obtained, so that a double-layer insulated electrical line with an outer diameter of 3.8 mm was produced.

The double-layer cable was tested for its resistance to the effects of water at a temperature of 75 ° C according to the publication ICEA-S-68 (ICEA = Insulated Cable Engineers Association USA), whereby all required electrical property values were observed.

After storage in mineral oil and diesel oil, as described in Example 1, the lines according to Example 2 showed no changes.

The abrasion test was carried out with the same results as in Example 1.

The flame retardancy test according to the publication IEC 332-1 was surely fulfilled.

Lines according to Examples 1 and 2 are also resistant to refrigerants (eg Freon ^R from DuPont.

Lines according to Example 2 are resistant to termite damage.

Example 3

A copper strand made of 50 individual wires of 0.25 mm diameter with a total cross section of 2.5 mm ² and a diameter of 2.1 mm was made in the usual way with a first insulation layer with up to approx. 50% Radox ^R- 125 filled with aluminum oxytrihydrate -Copolymer provided so that the outer diameter of the line was 3.2 to 3.4 mm. A 0.2 to 0.3 mm thick protective layer made of thermoplastic polyester elastomer (eg type Hyrel ^R 4056 from DuPont) was placed on the electrical line thus obtained, so that a double-layer insulated electrical line with a Outside diameter of 3.6 to 3.8 mm was generated.

The double-layer line is water-resistant in accordance with the requirements of the publication ICEA-S-68 and resistant to mineral oil and diesel oil, which - as described in Example 1 - was examined.

The requirements of the abrasion test, as described in example 1, are also met.

The permanent heat resistance of the line is 125 ° C.

Example 4

A copper strand made of 50 individual wires with a diameter of 0.25 mm and a total cross section of 2.5 mm ² with a diameter of 2.1 mm was made in the usual way with a first insulation layer made of Radox ^R 125 filled with up to 50% aluminum oxytrihydrate -Copolymer provided so that the outer diameter of the line was 3.6 mm. A 0.1 mm thick protective layer of aromatic polyether of the PEEK ^R type (from ICI) was placed on the electrical line thus obtained, so that a double-layer insulated electrical line with an outer diameter of 3.8 mm was produced.

The double-layer line is water-resistant in accordance with the requirements of publication ICEA-S-68 and resistant to mineral oil and diesel oil and gasoline (test as described in example 1).

The abrasion test requirements as described in Example 1 were also met. Likewise those of the flame test according to the publication IEC 332-1.

The permanent heat resistance of the line is 125 ° C.

Claims (3)

1. Insulated electric conductor with flame-resistant, halogen-free insulation, characterised in that it comprises an inner insulation layer of halogen-free, cross-linked polyolefin-copolymer and an outer protective layer of polyamide 6.6 or polyamide 12, a thermoplastic, halogen-free polyester elastomer or a halogen-free aromatic polyether.

2. Insulated electric conductor according to Patent Claim 1, characterised in that the outer layer consists of a thermoplastic, halogen-free polyester elastomer.

3. Insulated electric conductor according to Patent Claim 1, characterised in that the outer layer consists of a halogen-free aromatic polyether.