A fundamental approach to transformer thermal modeling. II. Field verification

For pt.I see ibid., vol.16, no.2, p.171-5 (2001). This paper has two main objectives. One is to show that the top oil rise thermal model proposed in part I is valid, for a large power transformer in service. The second is to show that there is a convenient way of estimating the parameters without re...

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Published in:IEEE transactions on power delivery 2001-04, Vol.16 (2), p.176-180
Main Authors: Swift, G., Molinski, T.S., Bray, R., Menzies, R.
Format: Article
Language:English
Subjects:
Estimating
Exponents
Instruments
Mathematical models
Nonlinearity
Oil insulation
Parameter estimation
Performance evaluation
Petroleum
Power transformers
Production facilities
Relays
Symbols
Temperature sensors
Testing
Transformers
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cited_by cdi_FETCH-LOGICAL-c1832-f58e7f01f8d42d7280ed1d651ded822574f5ce2647fbbe7ee22fe713a9be9b453
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description For pt.I see ibid., vol.16, no.2, p.171-5 (2001). This paper has two main objectives. One is to show that the top oil rise thermal model proposed in part I is valid, for a large power transformer in service. The second is to show that there is a convenient way of estimating the parameters without removing the transformer from service. A Manitoba Hydro 250 MVA OFAF transformer was chosen and instrumented with data-gathering equipment. Two twenty-four hour test runs were performed, one in February of 1999 and the other in July of 1999. The most basic parameter to be determined was the rated top oil rise but also found were the top oil line constant and the nonlinearity exponent, commonly given the symbol n. The results are very positive.
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source IEEE Electronic Library (IEL) Journals
subjects Estimating
Exponents
Instruments
Mathematical models
Nonlinearity
Oil insulation
Parameter estimation
Performance evaluation
Petroleum
Power transformers
Production facilities
Relays
Symbols
Temperature sensors
Testing
Transformers
title A fundamental approach to transformer thermal modeling. II. Field verification
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