On-site regeneration of transformer oil
Regeneration of transformer oil at the transformer’s location is an important preventive measure of transformer servicing.
Transformer life time is, in essence, the
life time of its insulation system. The most widely used insulation is
liquid insulation (transformer oils) and solid insulation (paper, i.e.
cellulose insulation). The oil provides for at least 80% of the electric
strength in a transformer. Almost 85% of transformer failures are
caused by damaged insulation.
Transformer oil is a good insulator when
insulation paper is will impregnated: the oil increases the breakdown
voltage of the insulation which it saturates. Low viscosity of the oil
allows it to permeate solid insulation and dissipate heat by
transferring it to the cooling system. Therefore, liquid insulation is
also a cooling liquid. Oxidation stability of the oil allows it to
endure high temperatures and prevent significant damage to the
insulation system.
Aging or degradation of transformer oil
is usually related to oxidation. As oxygen and water appear in the oil,
the oil oxidizes even of other conditions are perfect. Contaminants
generated by solid insulations also affect the quality of transformer
oil. Reactions which occur in the oil between unstable hydrocarbons,
oxygen and other catalyst, such as moisture, with such accelerators as
heat, lead to oil decomposition (oxidation).
Heat and moisture, along with oxidation,
act as primary accelerators of this process and are the largest threat
to solid insulation. If the cooling and insulation system is serviced
right, insulation system’s life time can be extended from 40 to 60
years. Unfortunately, oil oxidation cannot be entirely eliminated,
however, it can be controlled and slowed by oil treatment. One of the
most important transformer maintenance procedures is oil analysis
scheduled at least annually. Oil analysis is indicative of the overall
insulation condition.
Moisture is a combination of free water,
water solved in the products of oil degradation, solved and chemically
bound water (it is a part of glucose molecules and is necessary for
maintaining the mechanical strength of cellulose). It is impossible to
completely dehydrate cellulose insulation.
Transformer oil solves more water at
higher temperatures. If the mixture of oil and water is cooled, water
will settle out of the oil. The oil will permeate solid insulation, or
become bound to oil degradation products. Moisture will distribute
itself between the oil and the paper. However, this distribution will be
uneven: paper absorbs water from the oil and retains it, in the areas
of highest voltage.
Contaminants are formed in the process of
transformer operation. Oil decay products are acidic, and they attack
cellulose and metals; the acids also create soaps, aldehyde and alcohol,
which settle on the insulation, tank walls, breathing and cooling
systems in the form of sludge. Sludge forms faster in a heavily loaded,
hot transformer operated incorrectly. Sludge increases oil viscosity
thus reducing its cooling ability, which has further negative effect on
transformer life time.
Contamination also causes insulation to
shrink, destroys varnish and cellulose material. It is a conductor for
discharges and currents; being hygroscopic, it absorbs moisture and
leads to insulation overheating. Sediment forms on the core, which
increases transformer temperature.
Cellulose material is the weakest link in
the insulation system. Since transformer life time is in essence the
life time of its cellulose insulation, and since cellulose degradation
is irreversible, contaminants must be removed immediately, until they
damage the cellulose. A good maintenance program extends its life time
significantly.
Normal servicing of power transformer
should attain a practical life time of 50 – 75 years. However, the
actual condition of insulation defines the difference of real time
operation between 20 – 50 years plus the transformer life time.
Experience shows that the most common cause for transformer failure is
inadequate servicing and incorrect operation.
Transformer oil can be completely regenerated and made as good as new.
Insulation oil can be used indefinitely, if it is processed regularly.
The prospect of regenerating a batch of very poor quality oil should be
balanced against the relatively high cost of acquiring new oil.
Removal of water and keeping the
insulation dry is of utmost importance. Moisture accelerates aging. 1%
of moisture in cellulose accelerates aging by one order of magnitude in
comparison to 0.1% moisture content.
So, what are the main guidelines for preventive maintenance?
Purification of transformer oil, including regeneration, is a method of extending transformer life time.
The objective of this process is to
remove aging product from solid insulation and oil before they damage
the insulation system (insulation damage may be determined by furan
compounds).
A well planned maintenance strategy aims
to avoid accumulation of moisture in insulation and make sure that the
transformer always operates in a clean environment.
To stop or slow the aging process of
transformer insulation, the oil must be kept in the best possible
condition. The following measures will help:
- Constant control of oil condition;
- Silica gel in the breather must be in good condition (blue). Never allow more than one third of the silica gel volume to change color to pink;
- Repair oil leaks as soon as one is detected;
- Start using an oil purification system for dehydration of oil to 10 ppm at most;
- Do not add oil contaminated with moisture (if the oil was kept in an open vessel);
- Start drying the oil as soon as moisture content exceeds 20 ppm or the breakdown voltage drops to below 50 kV;
- Keep a close eye on the oil’s acidity and regenerate the oil when it reaches the critical level of 0.2 mg KOH/g. Best use a Fuller’s earth system with renewable sorbent (Globecore CMM-R is a good choice);
Sometimes oil should be changed
(filtered, rinsed, and refilled). This procedure is best performed on
site. Oil is drained form the transformer. The interior of transformer
tank is rinsed with hot naphthene or regenerated oil to remove sediment
concentrations; then the transformer is filled with regenerated oil.
If the transformer is rinsed only through
inspection opening, only approximately 10% of the interior surface will
be cleaned. In this case, a film of contaminated oil remains on most of
the winding surface and the tank’s interior. Keep in mind that up to
10% of the oil in the transformer permeates cellulose insulation. The
oil remaining in the insulation and the transformer contains polarized
structures and can poison a large amount of new or regenerated oil.
If the top lid is removed for rinsing,
approximately 60% of the interior can be cleaned. Better results can be
achieved by using a Fuller’s earth regeneration system, such as
GlobeCore’s CMM-R, on a live transformer.
A simple replacement of oil does not
remove all sediment, which accumulates in the cooling system and between
the windings. This sediment will dissolve in new oil and cause
oxidation.
How to regenerate and remove contamination on site
Oil may be regenerated directly in
working transformer (prior analysis indicates if such possibility
exists, especially the DGA test). The oil is pumped from the tank’s
lower valve to the regeneration system, where it is purified,
regenerated and degassed before going back to the transformer through
the transformer expansion tank. The process continues until the oil is
restored and complies with standards or other specifications. If CMM-R
unit is used, hot oil is regenerated by percolation through fuller’s
earth, then filtration and vacuum degassing and dehydration.
The difference between regeneration and
purification is that regular purification cannot remove such things as
acids, aldehydes, cetones etc, solved in the oil. Therefore, simple
purification cannot change the oil color from dark to light clear
yellow. Regeneration, however, incorporates filtration and dehydration.
When regenerating oil, the following results may be expected:
- Moisture content less than 10 ppm;
- Acidity below 0.02 mg KOH/g oil;
- Breakdown voltage of at least 70 kV;
- IFT at least 40 dynes/cm;
- Tan delta less than 0.003;
- Contaminants solved or suspended in the oil are removed;
- Oxidation stability restored;
- Oil color changed to clear light yellow;
- Solid insulation breakdown voltage improved.
Despite the removal of solved or
suspended solid contaminants, regular regeneration cannot remove
sediment. It is necessary to remove sediment if acidity of the oil is
above 0.15 mg KOH/g and IFT is less than 24 dynes/cm. Sludge removal
involves circulating hot oil through the transformer. The oil is heated
to the point when it becomes a solvent for the sludge. If the
transformer is operating, vibrations of the windings enhance the
process.
Next to consider is shrinking of insulation and dehydration of transformer oil.
Solid insulation may shrink as a result
of motion of loaded coil, specifically, under shock loads; shrinking may
become a source of premature failure. Shrinking also comes as a result
of cellulose degradation. On-site regeneration of transformer oil does
not cause insulation shrinking.
Experience shows that if the transformer
insulation is super-dry (up to +2% of dry weight), shrinking does not
occur. The regeneration process does not aim to dry transformer
insulation. It is impossible to dry the insulation within the time of
regeneration. High level of dehydration requires significant time.
Moving moisture from insulation by
thermal diffusion is a natural process of restoring the balance between
the winding insulation and the oil. The process rate depends on the
level of water diffusion through solid insulation.
Removal of sediment from transformer core
Insulation forms and accumulates in
cellulose fibers. During purification, the oil is heated to the point
when sediment becomes soluble in oil. The process guarantees that the
solved contaminants will be removed by regeneration and oil will become
clean.
Obviously, regeneration and purification is broader than simple oil restoration.
Loss of furan values
Restoration (regeneration or
purification) or replacement of transformer oil destroys furan
compounds, which are used to measure the degree of polymerization
(insulation condition and life time). Furan analysis should be done
before the process.
If transformer oil is allowed to degrade
beyond salvaging without regeneration or purification, transformer life
time decreases significantly. After purification, a new base line for
furan compounds control is established. Future furan test must be
referenced against this new base line.
Removal of aromatic compounds
Some types of aromatic compounds may have
anti-oxidation properties. Most specifications require that the content
of polyaromatic hydrocarbonate be equal or less than 3%. Too much
aromatic compounds reduce dielectric or impulse strength and imcrease
the oil’s ability to solve most of the solid insulation submerged in
oil. Oxidation stability of regenerated oil (after 164 hours at 100
degrees C) was 0.006% by weight, which is lower than the highest
allowable level of 0.1% by weight.
Before regeneration is started, the whole
system, including the hoses, is filled with oil. Old oil and suspended
contaminants accumulated in the bottom of the transformer tank are
removed from the lower part of the tank. Regenerated, filtered and pure
oil enters the transformer via the expansion tank above. This is done to
ensure the level of oil in the transformer is unchanged. The oil freely
circulates and the contaminants do not reenter the tank. Only the
clean, dehydrated, degassed oil returns to the transformer.
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