OIL FILLED TRANSFORMER - MAINTENANCE - I

DRYING OUT OF TRANSFORMER

Deterioration of insulation resistance value of transformer is mainly due to ingress of moisture into the windings and insulating materials. In order to improve the insulation resistance at site, following methods are available:

(i) Hot Oil Spraying: In this method about 7% of quantity of oil is heated up to 90-95º C separately and the hot oil is sprayed on to core and windings by means of nozzles in the form of fine spray and simultaneously the transformer is subjected to a high degree of vacuum say less than 5 m bar. The hot oil is collected at the bottom sent through a filter and reheated and sprayed. This process removes moisture from the core and windings. The oil used for spraying should be discarded.

(ii) Flushing Method: In this method, the transformer is put under hot oil circulation up to 60º C. After reaching steady temperature, the entire oil is drained quickly into a separate tank. Immediately after draining the oil, the transformer is subjected to a vacuum as per the guidelines of the manufacturer for 12 hours. During this period of application of vacuum, the transformer oil drained can be filtered to improve the quality. After 12 hours of vacuuming of the transformer, break the vacuum by means of dry nitrogen. Fill the transformer with filtered oil under vacuum. Now the oil in the transformer can be again circulated to raise the temperature of oil to 60º C. Again drain the oil, apply vacuum and repeat the process till you get a good IR value.

Precautions

The diverter switch tank and the main tank should be inter-connected before the above works to equalize the pressure. Otherwise the diverter switch tank may be damaged when the vacuum is applied.

BUCHHOLZ RELAY FUNCTIONAL TEST

Tools and materials required:

Cycle pump or Nitrogen cylinder with 4 kg/cm2 pressure and connecting tubes.

Procedure:

 Transformer shall be isolated.

 Connect Nitrogen cylinder or cycle pump to the top petcock of Buchholz relay

 Open the other petcock

 Allow gas to enter the relay

 Check and confirm alarm signal is received

 Close petcock on gas supply side and release all gases trapped in relay casing

 Increase the gas pressure to approx. 2 kg/cm2

 Open the test petcock and allow full surge of gas to enter the relay casing

 Check and confirm in control room that the Trip signal has been received

 Close Buchholz relay petcocks and normalize


BUCHHOLZ GAS ANALYSIS

This is to be done only when the transformer has tripped on account of Buchholz fault or Buchholz alarm has been initiated.

The following procedure should be adopted for testing of gas accumulated in Buchholz relay of power transformers.-

(i) Switch off the transformer when the Buchholz relay alarm rings, indicating the development of an internal fault in the transformer.

(ii) Through the lateral sight hole of the Buchholz relay, the colour and quantity of the gas may be determined.

(iii) Collect a portion of the gas in the test tube and apply a lighted match stick to the test tube to test the combustibility of the gas.

If gas is not combustible, it is mere air.

(iv) Then proceed to carry out the chemical test with a simple gas tester as follows:

The gas tester consists of two glass tubes containing two different silver nitrate solutions which through passage of decomposed gases form two distinguishable precipitates. The tubes must be assembled as indicated in the sketch and tube 1 should be filled with solution prepared by dissolving 5 grams of silver nitrate (Ag NO3) in 100 cc of distilled water.

Tube 2 should be filled with solution prepared by dissolving five grams of silver nitrate (Ag NO3) in 100 cc of watery ammonia solution.

Use of the gas tester is quite simple. Each of the two glass tubes should be filled with corresponding solutions upto the marks. They should be closed by corks fitted with the connecting tubes. Then the gas tester should be screwed on to the test cock of the Buchholz relay. After opening the test cock the collected gas would flow through the solution which would indicate the nature of the fault.

If the gas causes a white precipitate in tube 1 which turns brown under the influence of light, it means the oil has decomposed. Probably a flashover has occurred between bare conductors or between one bare conductor and an earthed part of the transformer.

If the gas causes a dark brown precipitate in the solution in tube 2 it means that solid insulating material like wood, paper, cotton, etc., had decomposed producing carbon monoxide (CO). In this case a leakage in the winding causing an internal short has occurred.

If there is no sedimentation at all the gas is mere air.

MAINTENANCE OF OIL FILLED POWER TRANSFORMERS

GENERAL

As is generally known, a transformer consists essentially of the magnetic core built-up of insulated silicon steel lamination upon which are wound two distinct sets of coils suitably located with respect to each other and termed as primary and secondary windings. Such a combination may be used to step up or step down the voltage. The techniques used in the design and construction of high voltage transformers vary from supplier to supplier. The active parts of a transformer consist of core and windings.

CORE

Core is made from lamination of cold rolled grain oriented silicon steel. The specific loss at operating flux densities in silicon steel is very low.

WINDINGS

Paper insulated copper conductor is used for windings. The conductors are transposed at regular intervals for ensuring equal flux linkage and current distribution.

COOLING

Core and windings are immersed in an oil filled tank. Normally, oil flows through winding and enter cooler or radiator by thermosyphonic effect.

Depending upon the rating, the transformer employs ONAN, ONAF, OFAF and OFWF types of cooling.

ONAN - Oil Natural Air Natural

ONAF - Oil Natural Air Forced

OFAF - Oil Forced Air Forced

OFWF - Oil Forced Water Forced

 
TANK AND COVER

Steel plates are used for fabricating transformer tanks and covers. They are designed to withstand full vacuum and a positive pressure of 0.3 kg/cm2 above the normal oil head.


CONSERVATOR

Conservator takes care of the expansion and contraction of transformer oil, which takes place due to loading and releasing of load. Modern transformers are provided with separate air shell in the conservator which prevents direct air contact with the transformer oil.

A separate conservator is provided for the on-load top changer diverter switch. Magnetic oil level gauges are provided in the conservator tanks which can give alarm to the operators and isolate the transformer in the event of oil level falling below a preset value.


PRESSURE RELIEF DEVICE
 
A pressure relief device is provided with an alarm and trip contacts. When excessive pressure is built inside the transformer in the event of severe fault, the pressure relief device releases the excess pressure.

For smaller transformers, an explosion vent is provided with a lighter diaphragm which breaks in the event of increasing internal pressure.

BUCHHOLZ RELAY

This gas and oil actuated relay is provided in the oil pipe which connects the conservator and the main tank. For any internal fault inside the transformer, this relay is actuated. This relay operates on the well-known fact that every type of electric fault in an oil-filled transformer gives rise to gas. This gas is collected in the relay to actuate the alarm and trip contacts.

SILICA GEL BREATHER

Expansion and contraction of oil due to loading causes breathing. External air gets in during the time of contraction. Silica gel absorbs the moisture in the air and prevents moisture entry into the oil.

TEMPERATURE INDICATORS

For continuous measurement of oil and winding temperatures, separate meters are used. These meters have alarm and trip contacts.

BUSHINGS

High voltage connections from the windings pass to the terminal bushings. These bushings are hermitically sealed and filled with oil for EHV transformers. This oil does not communicate with the main transformer oil. A separate oil level gauge is provided for monitoring the oil level in the bushings.

TAP CHANGER

There are two types of tap changers viz., on load and off load. In on load tap changer, tap position changes, when the transformer is energized either through manual mode or auto mode. The OLTC diverter switch has separate oil which needs periodical changing as some amount of arcing takes place during tap changing operations. This has a separate conservator and a Buchholz relay.


PROTECTIONS FOR TRANSFORMER

The following protections are provided normally for a transformer.

(i) Over current protection

(ii) Restricted Earth fault protection

(iii) Over voltage protection alarm

(iv) Over fluxing ( generator transformers )

(v) Surge protection

(vi) Differential protection ( above 5 MVA )

(vii) Oil temperature high protection

(viii) Winding temperature high protection

(ix) Oil level low protection

(x) Buchholz protection

(xi) Pressure relief device

The relays checking and calibration procedures are not covered in this document.

 
MAINTENANCE

It is essential to carry out regular and careful inspection on the transformer and associated components/equipment and carry out maintenance activities to provide long life to the equipment and achieve trouble-free service.

IN ORDER TO CARRY OUT THE NECESSARY INSPECTION AND MAINTENANCE WORKS, NECESSARY SAFETY PROCEDURES SUCH AS LINE CLEARANCE/EQUIPMENT SHUTDOWN ETC., WILL BE STRICTLY ADHERED TO, WHEREVER NECESSARY.

The frequency of inspection depends on climate, environment, load conditions and also the age of the transformer. The inspection cum maintenance schedule starts with every hour and continues as given below.


HOURLY

The following parameters are to be checked every hour and recorded. If the observed value exceeds the value given by the supplier, immediate remedial action should be taken.

(i) winding temperature

(ii) oil temperature

(iii) load current

(iv) terminal voltage

Normally, maximum allowed winding temperature is 55º C above ambient and oil temperature is 45º C above ambient (actual allowed value may vary from supplier to supplier).

DAILY

(i) Oil level in main conservator

(ii) Oil level in OLTC

(iii) Oil level in bushing

(iv) Leakage of water into cooler (OFWF)

(v) Water temperature (OFWF)

(vi) Water flow (OFWF)

(vii) Colour of silica gel


QUARTERLY CHECKING/ REPLACEMENT

Reconditioning of silica gel breather.

Checking of water cooler functioning

Checking of cooling fans functioning

Gear oil for tap changer mechanism

Checking of cooling pumps and motor functioning

HALF YEARLY

(i) Inspection of all gaskets and joints

ANNUALLY

(i) Protective relays, alarms, meters and circuits to be checked and calibrated

(ii) IR value and Polarisation Index

(iii) Tan delta and capacitance of bushings

(iv) BDV of transformer oil.

(v) Oil resistivity

(vi) Power factor of oil

(vii) Interfacial tension of oil

(viii) Acidity and sludge of oil

(ix) Flash point of oil

(x) Water content of oil

(xi) Dissolved gas analysis

(xii) Replacing of OLTC oil

(xiii) Thermo vision scanning

(xiv) Earthing measurements

(xv) Tan delta and capacitance of winding

ONCE IN FIVE YEARS

(i) Furan analysis (Once in a year after the first 5 years)

(ii) Overhauling of OLTC diverter switch (once in 5 years or after completion of 50,000 operations whichever is earlier)

ONCE IN TEN YEARS

Overhaul, inspection including lifting of core and winding.