Cable insulation materials
* Rubber*
cable insulation materials rubber |
For many years, wiring cables were insulated with vulcanised
natural rubber (VIR). Much cable of this type is still in service, although it
is many years since it was last manufactured. Since the insulation is organic,
it is subject to the normal ageing process, becoming hard and brittle. In this condition,
it will continue to give satisfactory service unless it is disturbed, when the
rubber cracks and loses its insulating properties. It is advisable that wiring
of this type which is still in service should be replaced by a more modern
cable. Synthetic rubber compounds are used widely for insulation and sheathing
of cables for flexible and for heavy-duty applications. Many variations are
possible, with conductor temperature ratings from 60°C to 180°C, as well as
resistance to oil, ozone and ultra-violet radiation depending on the
formulation.
*Paper*
cable insulation materials paper |
Dry paper is an excellent insulator but loses its insulating properties if it becomes
wet. Dry paper is hygroscopic, that is, it absorbs moisture from the air. It
must be sealed to ensure that there is no contact with the air. Because of
this, paper insulated cables are sheathed with impervious materials, lead being
the most common. PILC (paper insulated lead covered) is traditionally used for
heavy power work. The paper insulation is impregnated with oil or non-draining
compound to improve its long-term performance. Cables of this kind need special
jointing methods to ensure that the insulation remains sealed. This difficulty,
as well as the weight of the cable, has led to the widespread use of p.v.c. and
XLPE (thermosetting) insulated cables in place of paper insulated types.
*P.V.C.*
cable insulation materials p.v.c |
Polyvinyl chloride (p.v.c.) is now the most usual low voltage
cable insulation. It is clean to handle and is reasonably resistant to oils and
other chemicals. When p.v.c. burns, it emits dense smoke and corrosive hydrogen
chloride gas. The physical characteristics of the material change with
temperature: when cold it becomes hard and difficult to strip, and so BS 7671
specifies that it should not be worked at temperatures below 5°C. However a
special p.v.c. is available which remains flexible at temperatures down to
-20°C.
At high temperatures the material becomes soft so that
conductors which are pressing on the insulation (eg at bends) will
'migrate' through it, sometimes moving to the edge of the insulation. Because
of this property the temperature of general purpose P.V.C. must not be allowed
to exceed 70°C, although versions which will operate safely at temperatures up
to 85°C are also available. If p.v.c. is exposed to sunlight it may be degraded
by ultra-violet radiation. If it is in contact with absorbent materials, the
plasticiser may be 'leached out' making the p.v.c. hard and brittle.
LSF (Low smoke and fume)*
LSF (Low smoke and fume)*
cable LSF |
Materials which have reduced smoke and corrosive gas emissions
in fire compared with p.v.c. have been available for some years. They are
normally used as sheathing compounds over XLPE or LSF insulation, and can give
considerable safety advantages in situations where numbers of people may have
to be evacuated in the event of fire.
*Thermosetting
(XLPE)*
cable insulation materials Thermosetting |
Gross-linked polyethylene (XLPE) is a thermosetting compound
which has better electrical properties than p.v.c. and is therefore used for
medium- and high-voltage applications. It has more resistance to deformation at
higher temperatures than p.v.c., which it is gradually replacing. It is also
replacing PILC in some applications. Thermosetting insulation may be used
safely with conductor temperatures up to 90°C thus increasing the useful
current rating, especially when ambient temperature is high. A LSF (low smoke
and fume) type of thermosetting cable is available.
*Mineral*
cable insulation materials Mineral |
Provided that it is kept dry, a mineral insulation such as
magnesium oxide is an excellent insulator. Since it is hygroscopic (it absorbs
moisture from the air) this insulation is kept sealed within a copper sheath.
The resulting cable is totally fireproof and will operate at temperatures of up
to 250°C. It is also entirely inorganic and thus non-ageing. These cables have
small diameters compared with alternatives, great mechanical strength, are
waterproof, resistant to radiation and electromagnetic pulses, are pliable and
corrosion resistant. In cases where the copper sheath may corrode, the cable is
used with an overall LSF covering, which reduces the temperature at which the
cable may be allowed to operate. Since it is necessary to prevent the ingress of
moisture, special seals are used to terminate cables. Special mineral-insulated
cables with twisted cores to reduce the effect of electromagnetic interference
are available.
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