The
correct design and operation of the cooling system of a power transformer is
very important to maintain the health of the transformer. The design and type
of cooling is usually governed by the application of the power transformer and
is influenced by power output, location and environmental conditions. The
cooling system thus in turn affects the design of the transformer. The primary purpose of the cooling system is
for the efficient removal or transfer of energy created by the heating
effect of losses within the power transformer (components like windings, core
and structures), out into the environment.
Sometimes
when maintenance work is carried out on the coolers it is possible for the fans being replaced to be connected in the wrong direction
resulting in inefficient cooling due to recirculation of warm air causing elevated
oil temperatures.
The environmental cooling medium is usually air and/or water. The following are the different types of cooling configurations that may
be used in oil filled transformers [1, 2]:
ON
|
Oil Natural
|
ONAN
|
Oil Natural Air Natural
|
ONWF
|
Oil Natural Water Forced
|
OFAN
|
Oil Forced Air Natural
|
OFAF
|
Oil Forced Air Forced
|
OFWF
|
Oil Forced Water Forced
|
ODAN
|
Oil Directed Air Natural
|
ODAF
|
Oil Directed Air Forced
|
ODWF
|
Oil Directed Water Forced
|
Naturally oil cooled method is usually used on
smaller rated transformers and generally within 30 MVA, where the heat
generated from the core and windings are large enough to allow for natural
convection circulation of oil to cool the transformer. The principle of natural convection arises when hot oil rises and the cold falls in an
enclosed area resulting in organic circulation of oil. The cooling surface area
can be increased by providing the cooling tubes or fins to improve the
efficiency of cooling.
Transformers may also have forced air cooling by
means of fans to allow for external air circulation. As the rating of transformers increase (usually
greater than 60 MVA) the internal oil circulation becomes more of a requirement
to allow for quicker transfer and removal of heat generated allowing the
transformer to operate within the designed temperature rise. In this case
forced oil circulation is used by means of oil pumps in the oil flow circuit.
Water cooling is usually used in Hydro plant
applications where the transformers are located underground. The water cooling
forms an open loop system with the oil circulation being closed loop. To
prevent contamination of the oil with water the coolers are usually designed
with either double finned or having and intermediate closed loop low pressure
water circulation. Leak detection is usually provided. These configurations are presented in the diagrams below.
Failure Modes in the Cooling System
Cigre A2.49 [3] has highlighted the following Failure
modes for the cooling systems. These are predominantly due to the wearing out
of cooling system components. Other problems may be due to installation
problems especially after maintenance activities. When this happen the two
basic functions of the cooling system i.e. oil circulation and heat exchange
are affected.
The failure
of cooling fans usually affects the load of the transformer. Usually there
are spare fans but if more than one fan is out of service there may be a need
to reduce load so as to maintain the designed temperature rise of the
transformer.
The failure of cooling pumps is another
major problem especially of forced oil systems. This affects the flow and
circulation of oil in the transformer windings and core resulting in ineffective
heat transfer to the external environment. Pump failure usually results in elevated
oil temperatures.
Again it
can happen that after maintenance work pumps
are connected in the wrong direction resulting in reduced heat transfer efficiency
which affects the general cooling of the transformer.
Failure of
the control circuit of the cooling
system plays can affect the operation of the cooling systems where insufficient
fans and pumps from the coolers are activated for the relevant loading. This
will cause elevated oil temperatures.
In cooler
radiators high level of particles and sludge formation may block cooling ducts,
piping and flow paths. This affects the oil flow and which reduces the cooling
efficiency. Oil-water heat exchangers can also be blocked on the water side due
to deposits or corrosion causing decreased cooling efficiency.
Another
common problem is when radiator valves are
left in the closed position. This prevents oil from circulating within the
radiators causing major heating within the transformer.
The low viscosity of oil can also affect oil
movement in the convection process especially through the winding cooling
ducts. The viscosity of oil is affected by dissolved particles and oil ageing
by-products and is dependent on oil temperature.
Leaks are a significant problem in
cooling systems usually at the interface points to the tank and ancillary
components. These may be due to the effects of corrosion or aging of the
insulation material like gaskets.
With the
changing environmental conditions becoming more prevalent, elevated ambient temperatures may affect the heat transfer from the
transformer to the environment. This is also a major problem with transformers
located in enclosed areas (buildings) when the HVAC system fails. Also, very
low temperatures (at zero degrees Celsius or below) can affect water cooling
where the water can freeze.
Sometimes,
in summer months, high inlet cooling
water temperature can affect the cooling capability of the coolers. This
may occurs if the transformer was not properly designed for the environmental
conditions.
Inspections and Maintenance
It is very important have an intense inspection and
maintenance program to identify failures beforehand so that these can be
proactively resolved without affecting the performance.
Infrared
scanning is an important and simple tool that can be used to provide a
relative difference in surface temperature enabling areas of elevated
temperature to be easily identified. Infrared scanning is usually done when the
transformer is on load. It is usually most effective when done on a transformer
that has been returned to service where problems like a closed radiator valve
being left closed.
Temperature
monitoring is a standard monitoring that is provided on most transformers.
The prime purpose is to measure the energy within the transformer and any
abnormal conditions can be easily picked up especially with regards to the
cooling system as it easily affects the average temperature of the transformer.
The top oil temperature is usually represents the inlet temperature of the
coolers and when compared to the outlet temperature a differential can be
established. This can then be compared between coolers.
Cigre Working group A2.27 recommendations for
Condition Monitoring Facilities recommended that the following temperatures
should be available for condition monitoring [4]:
- Top oil – measure of the temperature of
the oil at the top of the tank
- Bottom oil – measure of the temperature
representing oil entering the bottom of the windings usually the cooler outlet temperature
- Cooler inlet oil – can be taken same as Top oil temperature
- Cooler outlet oil – measurement taken from the cooler outlet oil. In some transformer designs the bottom oil measurement can be used
- Cooling medium at inlet to coolers – a measurement representative of the temperature of the cooling medium (normally air or water) at the inlet to the coolers. In the case of an air temperature measurement, the sensor should be mounted in the shade. Air ambient temperature can be used if this measurement is not available. For water cooling medium a sensor or thermometer pocket should be included at both the cooler inlet and outlet
- Ambient temperature – Monitor the ambient temperature if the transformer is located in an enclosed area (building). This temperature must be alarmed for immediate investigation when the alarm value is triggered.
The Cooler Performance Index: D Temp (Inlet – Outlet) can then be derived by finding the difference between the Inlet and
Outlet temperatures. The difference (delta) can then be compared between
coolers or designed values, if available. Temperature deltas more than 30% of between
coolers should be investigated further.
Oil flow
is another important monitoring parameter. Forced oil (OF, OD) cooling systems
have designed flow rates to provide the accepted temperature rise. Modern
transformers usually have oil flow indicators or switches confirming oil flow. Analogue
oil flow meters provide actual flow rates which can be trended. These can also
be compared between coolers and any flow anomalies can be easily identified. Oil
flow provided pumps can be compared with about 80% of oil pump nameplate or in
pump manual (considering 20% oil flow reduction due to oil path hydraulic
resistance).
Routine
visual inspection of the transformer
oil-cooling loop components should be performed as regularly as prudent but
should not exceed 12 month frequency. All abnormal conditions must be rectified
as soon as possible. This can be a non-expensive way of proactively picking up
problems. Fans must routinely energised to verify proper operation, especially
standby fans.
Sludge building
up especially on older transformers can affect the flow of oil in the windings
and piping. This must be monitored routinely by doing oil tests such as
colour/appearance, acidity, dielectric dissipation factor (DDF), acidity and
interfacial tension (IFT), which can provide indications of sludge components
before visible sludge occurs.
References:
1.
|
IEC 60076-2
|
Power transformers - Part 2:
Temperature rise for liquid-immersed transformers
|
2.
|
C57.12.00-2015
|
General Requirements for
Liquid-Immersed Distribution, Power, and Regulating Transformers
|
3.
|
Cigre WG A2.49
|
Condition Assessment of Power Transformers
|
4.
|
CIGRE, Technical Brochure 343
|
Recommendations for Condition
Monitoring and Condition Assessment Facilities for Transformers
|