NO141675B - FLAME-RESISTANT ELECTRICAL CABLE. - Google Patents

Description

The present invention relates to a flame-resistant electric cable with one or more electric conductors, with conductor insulation surrounding them, with an outer cable insulation of silicone rubber and with an outer metal layer to hold the powder-shaped axis formed by burning the silicone rubber.

The reason why silicone rubber has been proposed as insulation for electrical cables that must be flame resistant, i.e. that they must be able to function during and for some time after the flame is exposed, is that silicone rubber has the property

that its combustion products are insulating. However, they are also in powder form. It is also known to surround the silicone rubber with a metal sheath to hold this powder.

However, it has been found that such known flame-resistant electric cables are prone to short-circuiting between the conductors or to the outer metal layer.

The purpose of the invention is to provide a _flame-resistant electric cable which does not suffer from these disadvantages, and the invention is based on the recognition that the cause of these disadvantages in the aforementioned, known cables is to be seen in the fact that the powdered axis of silicone rubber has a significantly larger volume than the silicone rubber before the incineration.

In accordance with this, the invention assumes that between the cable insulation and the outer metal layer there is a shrinkage layer which has the property that, at the latest when heated to the temperature at which the silicone rubber insulation burns to ash, it decreases in volume essentially as much as the ash of the silicone rubber insulation fills up more than that

unburnt silicone rubber insulation.

It has been shown that cables manufactured in accordance with the present invention have far less tendency to form a short circuit between the Reders or to the outer metal layer which is to hold the ash of the silicone rubber, than the known cables.

It has also been shown, as stated in claim 2, that a shrink layer of the specified character can be achieved by the shrink layer consisting of crepe paper. Other materials can also be used in the present context. Thus, as stated in claim 3, a cotton wrap can be used.

The invention will be described in more detail below

in connection with the drawing showing a piece of a cable according to the invention seen from the side and partially peeled.

In the drawing, reference numeral 1 denotes a pair of copper conductors. They can be solid or be composed of a number of cords to make the cable more flexible. The cable according to the invention can be produced with any number of conductors and can be produced both for communication and for power supply.

Each conductor is surrounded by a separate layer of insulation material 2 and the thus designed conductors are again surrounded by a layer of cable insulation 3. Both the conductor insulation 2 and the cable insulation 3 are made of silicone rubber. Outside the cable insulation 3 lies a metal layer which, in the embodiment shown, is produced as a copper braid, with the intention of making the cable flexible. However, the metal layer can instead consist of: a foil of aluminum or copper, and the foil can have a wrap around or it can only overlap without interlocking. Around this metal layer H is a protective layer 6 of PVC or of another suitable material. The cable can further be reinforced in a known manner.

Between the metal layer 4 and the cable insulation 3, according to the invention, a shrinkage layer 5 is placed. This must consist of a material which, when heated to the flame temperature, changes in such a way that it occupies a smaller volume than before the flame exposure, thereby making room for the volume expansion that the ashing The insulation layers 2 and 3 give* the opportunity to. The shrink layer 5 can consist of crepe paper of a suitable weight in relation to the amount of silicone rubber. It has e.g. proved that with an outer diameter for the silicone rubber of 8 mm, a layer of crepe paper of 50 g per m 2 give rise to a loss which mainly compensates for the expansion of the silicone rubber during this ashing.

Instead of crepe paper, a cotton wrap can be used, but its dimensioning is a little more difficult to do because the cotton threads can be slightly unevenly twisted, but by trial and error a suitable pitch for a given cotton thread can easily be found.

Claims (3)

1. Flame-resistant electrical cable with one or more electrical conductors (1), with conductor insulation surrounding them (2) , preferably of silicone rubber, with an outer cable insulation (3) of silicone rubber and with an outer metal layer (4) to hold the powdery ash formed by burning the silicone rubber, characterized in that between the cable insulation (3) and the outer metal layer (4) there is a shrinkage layer (5) which has the property that, at the latest when heated to the temperature at which the silicone rubber insulation burns to ash, it decreases in volume essentially as much as the ash of the silicone rubber insulation fills more than the unburned insulation of silicone rubber (2) and (3). 2. Flame-resistant electric cable according to claim 1, characterized in that the shrink layer (5) consists of crepe paper. 3. Flame-resistant electric cable according to claim 1, characterized in that the shrink layer (5) consists of a cotton wrap.