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American Journal of Electrical and Electronic Engineering. 2017, 5(2), 64-68
DOI: 10.12691/AJEEE-5-2-5
Original Research

Presenting New Idea for Circumstance Monitoring of Transformers in Power Lines

Hossein Soleymani1,

1Qom Electricity Power Distribution Company, Qom, Iran

Pub. Date: May 02, 2017
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Cite this paper

Hossein Soleymani. Presenting New Idea for Circumstance Monitoring of Transformers in Power Lines. American Journal of Electrical and Electronic Engineering. 2017; 5(2):64-68. doi: 10.12691/AJEEE-5-2-5

Abstract

Transformers is one of the key equipment of the power system. Power rating of the transformers varies from KVA to several hundreds of MVA. The transformer is expensive equipment of the power system. Failures of transformer usually lead to substantial profit loss to the utility, potential environmental damage, explosion and fire hazards and expensive repairing or replacement costs, thus, it is desirable that the maximum service life of transformer is required. Condition monitoring of transformer can help to increase the life of the transformer and reduce the maintenance cost. Online monitoring is the record of significant data of a transformer and analysis of data and including the history of the transformer. In this paper percent the different techniques adopted for condition monitoring of transformer.

Keywords

power system, transformers, preventing transformer failure

Copyright

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References

[1]  Dhingra Arvind, Singh Khushdeep, Kumar Deepak “Condition Monitoring of Power Transformer: A Review” IEEE, 2008.
 
[2]  Metwally IA “Failures, monitoring, and new trends of power transformers.” IEEE 2011 Potentials 30: 36-43.
 
[3]  Kogan VI, Fleeman JA, Provanzana JH, Shih CH “Failure analysis of EHV transformers” IEEE Trans Power Delivery, 1988, 3 (2): 672-683.
 
[4]  CIGRE Working Group “An international survey on failures in large power transformers” Electra, No. 88, 1983.
 
[5]  International Electro technical Commission “IEC60559: interpretation of the analysis of gases in transformers and other oil-filled electrical equipment in service” International Electro technical Commission Standard, Geneva, Switzerland, 1978.
 
[6]  The Institute of Electrical and Electronics Engineers “Transformers Committee of the IEEE Power Engineering Society, IEEE guide for the interpretation of gases generated in oil immersed transformers IEEE Std. C57.104-1991” The Institute of Electrical and Electronics Engineers, Inc., New York, 1994.
 
[7]  Mollmann A, Pahlavanpour B “new guidelines for interpretation of dissolved gas analysis in oil-filled transformers” Electra CIGRE France 186: 30-51, 1999.
 
[8]  Bureau of Standards for the P.R.China”GB7252-87: Guide for the analysis and diagnosis of gases dissolved in transformer oil” National Technical Committee 44 on Transformer of Standardization Administration of China 1987.
 
[9]  Yew JH, Pradhan MK, Saha TK “Effects of moisture and temperature on the frequency domain spectroscopy analysis of power transformer insulation” Proceedings of IEEE power and energy society general meeting, Pittsburgh, USA, 20-24 July 2008.
 
[10]  Jaya M, Helmlinger O, Leibfried T “Novel method to determine insulation temperature during dielectric measurements on power transformers” Proceedings of 20th Australasian universities power engineering conference (AUPEC), Christchurch, Dec 2010.
 
[11]  IEEE Standards C57. 104-1991 IEEE “Guide for the Interpretation of gases generated in Oil-Immersed Transformers”, 1991.
 
[12]  Rogers R. R. 1978, “IEEE and IEC code to interpret incipient faults in transformers using gas in oil analysis”, IEEE transaction electrical Insulation, Vo.13, No.5, 1978.
 
[13]  A. Wilson and P. N. Jarman, “Long term performance of transformer insulation,” in Proc. INSUCON/ISOTEC 8thBEAME Int. EI Conf., 1998.
 
[14]  Shroff DH, Stannett AW “A review of paper aging in power transformers” IEE Proc, Part C 132:312-319, 1985.
 
[15]  Zaengl WS “Dielectric spectroscopy in time and frequency domain for HV power equipment, part i: theoretical considerations” IEEE Electr Insul Mag 19(5): 6-19, 2003.
 
[16]  Yao ZT, Saha TK, Darveniza M “Effects of moisture on the recovery voltage measurement for aged transformer” Proceedings of International Conference on Power Engineering, Vol. 1. pp. 349-353, 1999.
 
[17]  Gafvert U, Frimpong G, Fuhr J “Modeling of dielectric measurements on power transformers” Proceedings of CIGRE, Paris, 1998, Paper no. 15/103.
 
[18]  Griffin PJ, S Sokolov V, Vanin B “Moisture equilibrium and moisture migration within transformer insulation system” CIGRE SC12 transformer colloquium, Budapeste. (Julho), 1999.
 
[19]  Saha TK “Review of time-domain polarization measurements for assessing insulation condition in aged transformers” IEEE Trans Power Delivery 18(4):1293-1301, 2003.
 
[20]  Sivaji Chakravorti, Debangshu DeyBiswendu Chatterjee “Recent Trends in the Condition Monitoring of Transformers Theory, Implementation and Analysis” Springer-Verlag London 2013.
 
[21]  W. H. Tang Q.H.Wu “condition monitoring and assessment of power transformers using computational intelligence” Springer-Verlag London 2011.
 
[22]  Tony McGrail and Charles Sweetser, “Experience with SFRA for transformer diagnostics”, Double Engineering Company, Doble Conference 2003.
 
[23]  CIGRE Working Group A2.26, “Mechanical Condition Assessmentof Transfonner Windings Using Frequency Response Analysis (FRA)”, Brochure 343, Paris, April 2008.
 
[24]  Akshay A. Pandya, Dr. B. R. Parekh “Sweep Frequency Response Analysis (SFRA) as a Diagnostic Tool To Detect Core & LV “V” Phase Winding Short and Core & HV “V” Phase Winding Short Faults which are Practically Simulated Separately on 10 KV A Power Transformer” IEEE International Conference on Recent Advances and Innovations in Engineering (ICRAIE-2014, Jaipur, 2014.
 
[25]  Jashandeep Singh, Yog Raj Sood, Piush Verma, Raj Kumar Jarial “Novel method for detection of transformer winding faults using Sweep Frequency Response Analysis” IEEE.
 
[26]  A. P. Pumomoadi, D. Fransisco “Modeling and Diagnostic Transformer Condition Using Sweep Frequency Response Analysis” IEEE 2009.
 
[27]  F. H. Wang, J. Xu, Z. J. Jin, and S. S. Gui. “Experimental Research of Vibration Sweep Frequency Response Analysis to Detect the Winding Deformation of Power Transformer” IEEE 2010.
 
[28]  Esam Al Murawwi, Braham Barkat. “A New Technique for a Better Sweep Frequency Response Analysis Interpretation” International Symposium on Electrical Insulations, IEEE, 2012.
 
[29]  Esam Al Murawwi, Braham Barkat, Redy Mardiana. “Statistical Evaluation of a New Technique for Sweep Frequency Response Analysis” IEEE 2012.
 
[30]  Amit Kumar Mehta, R.N. Sharma, Sushil Chauhan, S.D. Agnihotri “Study and Diagnosis the Failure of Power Transformers by Sweep Frequency Response Analysis.” IEEE, 2013.
 
[31]  Abeywickrama N, Serdyuk YV, and Gubanski SM. “Effect of core magnetization on frequency response analysis (FRA) of power transformers IEEE Trans Power Deliv23 (3):1432-1438, 2008.
 
[32]  Wang M “Winding movement and condition monitoring of power transformers in-service” Ph.D. Dissertation, University of British Columbia, Vancouver, 2003.