A Simplified Top-Oil Temperature Model for Transformers Based on the Pathway of Energy Transfer Concept and the Thermal-Electrical Analogy

This paper presents an alternative approach to determine the simplified top-oil temperature (TOT) based on the pathway of energy transfer and thermal-electrical analogy concepts. The main contribution of this study is the redefinition of the nonlinear thermal resistance based on these concepts. An a...

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Bibliographic Details
Published inEnergies (Basel) Vol. 10; no. 11; p. 1843
Main Authors Roslan, Muhammad, Azis, Norhafiz, Kadir, Mohd, Jasni, Jasronita, Ibrahim, Zulkifli, Ahmad, Azalan
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.11.2017
Subjects
Air temperature
Approximation
Capacitance
Case studies
Convection
Cooling
Differential equations
Energy transfer
Heat transfer
nonlinear oil thermal resistance
Oil
pathway of energy transfer
Temperature
Temperature effects
Thermal analysis
Thermal energy
Thermal resistance
thermal-electrical analogy
top-oil temperature thermal model
transformers
Viscosity
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Summary:This paper presents an alternative approach to determine the simplified top-oil temperature (TOT) based on the pathway of energy transfer and thermal-electrical analogy concepts. The main contribution of this study is the redefinition of the nonlinear thermal resistance based on these concepts. An alternative approximation of convection coefficient, h, based on heat transfer theory was proposed which eliminated the requirement of viscosity. In addition, the lumped capacitance method was applied to the thermal-electrical analogy to derive the TOT thermal equivalent equation in differential form. The TOT thermal model was evaluated based on the measured TOT of seven transformers with either oil natural air natural (ONAN) or oil natural air forced (ONAF) cooling modes obtained from temperature rise tests. In addition, the performance of the TOT thermal model was tested on step-loading of a transformer with an ONAF cooling mode obtained from previous studies. A comparison between the TOT thermal model and the existing TOT Thermal-Electrical, Exponential (IEC 60076-7), and Clause 7 (IEEE C57.91-1995) models was also carried out. It was found that the measured TOT of seven transformers are well represented by the TOT thermal model where the highest maximum and root mean square (RMS) errors are 6.66 °C and 2.76 °C, respectively. Based on the maximum and RMS errors, the TOT thermal model performs better than Exponential and Clause 7 models and it is comparable with the Thermal-Electrical 1 (TE1) and Thermal-Electrical 2 (TE2) models. The same pattern is found for the TOT thermal model under step-loading where the maximum and RMS errors are 5.77 °C and 2.02 °C.
ISSN:1996-1073
1996-1073
DOI:10.3390/en10111843