Study on thermal model for calculating transformer hot Spot temperature
A power transformer is a static piece of apparatus with two or more windings which, by electromagnetic induction, transforms a system of alternating voltage and current into another system of voltage and current usually of different values and at same frequency for the purpose of transmitting ele...
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| Format: | Thesis |
| Language: | English English English |
| Published: |
2011
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| Subjects: | |
| Online Access: | http://eprints.uthm.edu.my/2631/1/24p%20JAMAL%20ALI%20RAMADAN%20DOFAN.pdf http://eprints.uthm.edu.my/2631/2/JAMAL%20ALI%20RAMADAN%20DOFAN%20COPYRIGHT%20DECLARATION.pdf http://eprints.uthm.edu.my/2631/3/JAMAL%20ALI%20RAMADAN%20DOFAN%20WATERMARK.pdf http://eprints.uthm.edu.my/2631/ |
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| Institution: | Universiti Tun Hussein Onn Malaysia |
| Language: | English English English |
| Summary: | A power transformer is a static piece of apparatus with two or more windings which, by
electromagnetic induction, transforms a system of alternating voltage and current into another
system of voltage and current usually of different values and at same frequency for the purpose
of transmitting electrical power.
The hot spot temperature depends on instantaneous load and ambient temperature,
winding design and also cooling model. There are two possible methods for hotspot temperature
determination. The first method is to measure the hot spot temperature using a fiber optic, and
other is to calculation the hotspot temperature using transformer thermal models. It was noticed
that the hot spot temperature rise over top oil temperature due to load changes is a function
depending on time as well as the transformer loading (overshoot time dependent function). It has
also been noticed that the top oil temperature time constant is shorter than the time constant
suggested by the present IEC loading guide, especially in cases where the oil is guided through
the windings in a zigzag pattern for the ONAN and ONAF cooling modes. This results in winding
hottest spot temperatures higher than those predicted by the loading guides during transient states
after the load current increases, before the corresponding steady states have been reached.
This thesis presents more accurate temperature calculation methods taking into account
the findings mentioned above. The models are based on heat transfer theory, application of the
lumped capacitance method, the thermal-electrical analogy and definition of nonlinear thermal
resistances at different locations within a power transformer. The methods presented in this
thesis take into account all oil physical parameters change and loss variation with temperature.
In addition, the proposed equations are used to estimate the equivalent thermal capacitances of
the transformer oil for different transformer designs and winding-oil circulations. The models are
validated using experimental results, which have been obtained from the normal heat run test
performed by the transformer manufacturer at varying load current on a 250-MVA-ONAFcooled
unit, a 400-MVA-ONAF-cooled
unit and a 2500-KVA-ONAN-cooled
unit. The results
are also compared with the IEC 60076-7:2005 loading guide method.
Keywords: power transformers, hot spot temperature, top oil temperature, non-linear thermal |
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