The Phenomena of Moisture in Transformer Oil
Water in oil appears as an unwanted substance, it is
generally accepted that water in microscopic amounts - not gallons- is the
cause of more electrical breakdowns than any other impurity. Moisture constitutes a hazard not only to the
insulating qualities of the oil but also to the insulations that are immersed
in the oil.
Water may be introduced to the oil by leaking gaskets, poor
handling techniques or from the product of natural insulating paper and oil degradation. As the paper degrades, it produces Carbon
Dioxide and Water and as the insulating oil ages, water, acids, sludge and
other polar compounds are formed. So its
presence is inevitable during the normal service life of a transformer.
Water is a polar liquid having a high permittivity or
dielectric constant it is therefore attracted to areas of strong electric fields. This sees the internal moisture distributed
not uniformly, but in fact potentially concentrating in the most dangerous
parts of the system.
It is important to note that water is in a continuous state
of movement between the oil and paper insulating system, caused by internal
temperature variations due to load and ambient conditions.
Water may be present in four possible forms, they are:
• Free water – That is water that has settled
out of the oil in a separate layer. It
is this water which is indicated by a low dielectric breakdown voltage.
• Emulsified water – Or water that is suspended
and has not yet settled out into free water (indicated by “caramel” coloured
oil).
Nb: A high Power Factor value indicates the possible
presence of this suspended water trapped in oil decay products.
• Water in solution – or dissolved in the oil.
• Chemically bound water – Water which is chemically
attached to the insulating paper and which is released when oxidized.
The destructive effects of water include:
• Expansion of the paper insulation, altering
the mechanical pressure of the transformer clamping system.
• Loss of insulating ability (Dielectric
Breakdown Voltage)
• Accelerating paper aging ie triggering
decomposition of the fibres in the paper
• Increased corrosion of the core and tank
• Progressive consumption of oil additives
The most dangerous and destructive of these effects is the
loss of the oils insulating ability.
This may occur from the following events:
• During periods of high load and at high
ambient temperatures, dielectric breakdowns can result from the reduced oil
strength with high absolute amounts of water.
• With sudden high loads, water can boil off
conductor surfaces and the vapour bubbles can cause dielectric failures as they
rise to the top.
• During the cool-down period after high load,
the relative saturation of oil will increase.
At its extreme at 100% relative saturation, water will precipitate out
and greatly reduce the dielectric strength of the oil.
If oil is oxidized to any extent, any water coming into the
transformer will partially be absorbed into the oil decay products (It is this
fact which causes old or highly oxidised oil to dissolve more water than new
oil). As the decay products build up in
the oil, the surface tension of the water or the interfacial tension between
the oil and the water is lowered dramatically.
This heavier decay molecule will then recirculate throughout the entire
transformer and will find its way into the paper insulation, or into areas of
high electrical intensity thus reducing the insulation resistance. The water
saturated oil decay molecule has a preference for the coolest part of the
transformer (bottom and fins, leading to corrosion) and areas of highest
electrical stress (leading to arcing).
It has been proven that insulating
paper with 2% moisture content ages three times faster than one with 1%
moisture and thirty times faster with 3% moisture.
It is thus easy to see the importance of maintaining low
moisture levels within a transformer to ensure a long and trouble free service
life.
No comments:
Post a Comment