Dielectric Strength And Viscosity Of Palm Oil Based Nanofluids For Liquid Insulation In Power Transformer

The liquid insulation system of high voltage oil-immersed transformers is involved in this thesis. Until now, mineral insulation (MI) oils are typically used in high voltage oilimmersed transformers because of their excellence in dielectric strength and cooling performance. However, MI oils are non-...

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Main Author: Mohamad, Mohd Safwan
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Language:English
English
Published: 2018
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advisor Zainuddin, Hidayat

topic TK Electrical engineering
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Electronics Nuclear engineering
Mohamad, Mohd Safwan
Dielectric Strength And Viscosity Of Palm Oil Based Nanofluids For Liquid Insulation In Power Transformer
description The liquid insulation system of high voltage oil-immersed transformers is involved in this thesis. Until now, mineral insulation (MI) oils are typically used in high voltage oilimmersed transformers because of their excellence in dielectric strength and cooling performance. However, MI oils are non-renewable and non-sustainable sources. This has led scientists and researchers to formulate alternative insulation liquids such as natural ester insulation (NEI) oils to replace MI oils. Palm fatty acid ester (PFAE) is one of the ester types of insulation oil and the alternative oil to replace MI oils. This PFAE oil was developed in 2006 by Lion Corporation as insulation oil for transformer applications which have several advantages compared to MI oils i.e. good biodegrability, excellent performance in insulation and cooling medium. Nowadays, nanotechnology is one of the most important research fields especially in electrical insulation system due to the increasing demand for the electrical power in the world. Therefore, adding the nanoparticles is one of the approaches used by researchers to improve the performance of liquid insulation also known as nanofluids. The use of nanofluids in insulation system give more benefit in terms of insulation performance, design and power capacity of transformer. Based on this premise, the objectives of this research is to formulate PFAE oil-based nanofluids by dispersing three types of nanoparticles (i.e. conductive, semi-conductive and insulating nanoparticles) into PFAE oil. The potential of these nanofluids as insulation liquids is validated based on its Alternating Current (AC) breakdown voltage and viscosity. In sample preparation of PFAE oil-based nanofluids, four specific procedures must be followed i.e. weighing, homogenizer treatment, vacuum oven and moisture removal treatment process. The AC breakdown voltage was measured which complies with the specifications of the ASTM D1816 and the viscosity of the oil samples was measured according to ASTM D445 and ASTM D2983. The findings from the AC breakdown voltage suggested that the PFAE oil-based conductive nanofluid has the highest dielectric strength enchancement at weibull probability of 63.2 % with a value of 50.57 % relative to that for virgin PFAE oil. Besides that, the histogram for this nanofluids is skewed to the left, whereby most of the data fall within a range of 45 – 49 kV. In terms of heat transfer, the PFAE oil-based insulating nanofluid has the lowest viscosity compared to the other oil samples, particularly at 60 oC, based on viscosity values. Both of these parameters (AC breakdown voltage and viscosity) are crucial to designers of high voltage equipment and systems. In conclusion, the effects on breakdown voltage is more significant compared to the viscosity when nanoparticles are added into the PFAE oil.
format Thesis
qualification_name Master of Philosophy (M.Phil.)
qualification_level Master's degree
author Mohamad, Mohd Safwan
author_facet Mohamad, Mohd Safwan
author_sort Mohamad, Mohd Safwan
title Dielectric Strength And Viscosity Of Palm Oil Based Nanofluids For Liquid Insulation In Power Transformer
title_short Dielectric Strength And Viscosity Of Palm Oil Based Nanofluids For Liquid Insulation In Power Transformer
title_full Dielectric Strength And Viscosity Of Palm Oil Based Nanofluids For Liquid Insulation In Power Transformer
title_fullStr Dielectric Strength And Viscosity Of Palm Oil Based Nanofluids For Liquid Insulation In Power Transformer
title_full_unstemmed Dielectric Strength And Viscosity Of Palm Oil Based Nanofluids For Liquid Insulation In Power Transformer
title_sort dielectric strength and viscosity of palm oil based nanofluids for liquid insulation in power transformer
granting_institution Universiti Teknikal Malaysia Melaka
granting_department Faculty of Electrical Engineering
publishDate 2018
url http://eprints.utem.edu.my/id/eprint/24723/1/Dielectric%20Strength%20And%20Viscosity%20Of%20Palm%20Oil%20Based%20Nanofluids%20For%20Liquid%20Insulation%20In%20Power%20Transformer.pdf
http://eprints.utem.edu.my/id/eprint/24723/2/Dielectric%20Strength%20And%20Viscosity%20Of%20Palm%20Oil%20Based%20Nanofluids%20For%20Liquid%20Insulation%20In%20Power%20Transformer.pdf
_version_ 1747834096045785088
spelling my-utem-ep.247232021-10-05T12:32:25Z Dielectric Strength And Viscosity Of Palm Oil Based Nanofluids For Liquid Insulation In Power Transformer 2018 Mohamad, Mohd Safwan TK Electrical engineering. Electronics Nuclear engineering The liquid insulation system of high voltage oil-immersed transformers is involved in this thesis. Until now, mineral insulation (MI) oils are typically used in high voltage oilimmersed transformers because of their excellence in dielectric strength and cooling performance. However, MI oils are non-renewable and non-sustainable sources. This has led scientists and researchers to formulate alternative insulation liquids such as natural ester insulation (NEI) oils to replace MI oils. Palm fatty acid ester (PFAE) is one of the ester types of insulation oil and the alternative oil to replace MI oils. This PFAE oil was developed in 2006 by Lion Corporation as insulation oil for transformer applications which have several advantages compared to MI oils i.e. good biodegrability, excellent performance in insulation and cooling medium. Nowadays, nanotechnology is one of the most important research fields especially in electrical insulation system due to the increasing demand for the electrical power in the world. Therefore, adding the nanoparticles is one of the approaches used by researchers to improve the performance of liquid insulation also known as nanofluids. The use of nanofluids in insulation system give more benefit in terms of insulation performance, design and power capacity of transformer. Based on this premise, the objectives of this research is to formulate PFAE oil-based nanofluids by dispersing three types of nanoparticles (i.e. conductive, semi-conductive and insulating nanoparticles) into PFAE oil. The potential of these nanofluids as insulation liquids is validated based on its Alternating Current (AC) breakdown voltage and viscosity. In sample preparation of PFAE oil-based nanofluids, four specific procedures must be followed i.e. weighing, homogenizer treatment, vacuum oven and moisture removal treatment process. The AC breakdown voltage was measured which complies with the specifications of the ASTM D1816 and the viscosity of the oil samples was measured according to ASTM D445 and ASTM D2983. The findings from the AC breakdown voltage suggested that the PFAE oil-based conductive nanofluid has the highest dielectric strength enchancement at weibull probability of 63.2 % with a value of 50.57 % relative to that for virgin PFAE oil. Besides that, the histogram for this nanofluids is skewed to the left, whereby most of the data fall within a range of 45 – 49 kV. In terms of heat transfer, the PFAE oil-based insulating nanofluid has the lowest viscosity compared to the other oil samples, particularly at 60 oC, based on viscosity values. Both of these parameters (AC breakdown voltage and viscosity) are crucial to designers of high voltage equipment and systems. In conclusion, the effects on breakdown voltage is more significant compared to the viscosity when nanoparticles are added into the PFAE oil. 2018 Thesis http://eprints.utem.edu.my/id/eprint/24723/ http://eprints.utem.edu.my/id/eprint/24723/1/Dielectric%20Strength%20And%20Viscosity%20Of%20Palm%20Oil%20Based%20Nanofluids%20For%20Liquid%20Insulation%20In%20Power%20Transformer.pdf text en public http://eprints.utem.edu.my/id/eprint/24723/2/Dielectric%20Strength%20And%20Viscosity%20Of%20Palm%20Oil%20Based%20Nanofluids%20For%20Liquid%20Insulation%20In%20Power%20Transformer.pdf text en validuser https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=116866 mphil masters Universiti Teknikal Malaysia Melaka Faculty of Electrical Engineering Zainuddin, Hidayat 1. Agrawal, K.C., 2007. Electrical Power Engineering Reference and Application Handbook, CRC Press Handbook, United Kindom, pp.1-1125. 2. Arief, Y.Z., Ahmad, M.H, Lau, K.Y, Muhamad, N.A., Bashir, N., Mohd, N.K., Huey, L.W., Kiat, Y.S. and Azli, S.A., 2014. A Comparative Study on the Effect of Electrical Ageing on Electrical Properties of Palm Fatty Acid Ester ( PFAE ) and FR3 as Dielectric Materials. IEEE International Conference on Power and Energy (PECon), Kuching, 2014, pp.128-133. 3. ASTM International, 2017. ASTM D2983-17: Standard Test Method for Low-Temperature Viscosity of Automatic Transmission Fluids, Hydraulic Fluids, and Lubricants using a Rotational Viscometer. 4. ASTM International, 2017. ASTM D6871-17: Standard Specification for Natural (Vegetable Oil) Ester Fluids Used in Electrical Apparatus. 5. ASTM International, 2017. ASTM D1816-12: Standard Test Method for Dielectric Breakdown Voltage of Insulating Liquids Using VDE Electrodes. 6. ASTM International, 2017. ASTM D445-17a: Standard Test Method for Kinematic Viscosity of Transparent and Opaque Liquids (and Calculation of Dynamic Viscosity). 7. Azis, N., 2012. Ageing Assessment Of Insulation Paper With Consideration Of In-Service Ageing And Natural Ester Application. PhD Thesis. University of Manchester. 8. Azis, N., Jasni, J., Kadir, M.Z.A.A. and Mohtar, M.H., 2014. Suitability of Palm Based Oil as Dielectric Insulating Fluid in Transformers. Journal of Electrical Engineering and Technology, Korea, pp.662–669. 9. Azli, S.A., Arief, Y.Z., Muhamad, N.A. and Bashir, N., 2013. The Effect of Electrical Ageing on Electrical Properties of Palm Fatty Acid Ester (PFAE) and FR3 as Dielectrical Materials. IEEE Student Conference on Research and Development, Putrajaya, pp.16–17. 10. Chandra, P., Sayantan, M., Nayak, S.K. and Panda, A., 2014. A brief review on viscosity of nanofluids. International Nano Letters, Springer, Volume 4 , pp.109–120. 11. Choi, S.U.S. and Eastman, J.A., 1995. Enhancing Thermal Conductivity of Fluids with Nanoparticles, ASME International Mechanical Engineering Congress & Exposition, USA, pp. 1-8. 12. Cigre Working Group, 2010. Cigre Working Group A2.35: Experience in Service with New Insulating Liquids. 13. Corporation, Reliasoft., 2015. Life Data Analysis Reference books. USA, pp1-438. 14. Darwin, A., Christophe. and Folliot, P., 2007. The Use Of Natural Ester Fluids In Transformers. Mat Post 07 - 3rd European Conference On Hv & Mv Substation Equipment, pp.1–6. 15. Das, S.K., Putra, N. and Roetzel, W., 2003. Pool boiling characteristics of nano-fluids. International Journal of Heat and Mass Transfer, Volume 46, Issue 5, pp.851–862. 16. Du, B., Li. J., Wang, B.M. and Zhang, Z.T., 2012. Preparation and Breakdown Strength of Fe3O4 Nanofluid Based on Transformer Oil. International Conference on High Voltage Engineering and Application, Shanghai, pp.399–401. 17. Dung, V.N., 2013. Experimental Studies of Streamer Phenomena in Long Oil Gaps. PhD Thesis, Norwegian University of Science and Technology, pp. 1-176. 18. Eastman, J.A., Choi, U.S., Li, S., Thompson, L.J., and Lee, S., 2001. Enhanced thermal conductivity through the development of nanofluids, Journal of Colloid Interface Science, Vol. 277, pp.100-103. 19. Eklund, M., 2004. Transformer Oil Handbook - Nynas First edit. Nynas, ed., Sweeden: Nynas. 20. Farhadi, M., Jamshidi, N., Ganji, D.D. and Sedighi, K., 2012. Experimental Investogation on the Viscosity of Nanoluids. International Journal of Engineering, Transactions B: Application, Volume 25, No. 3, pp.201–209. 21. Grzybowski, S. and Zahn, M., 2012. Preparation of a Vegetable Oil-Based Nanofluid and Investigation of Its Breakdown and Dielectric Properties. IEEE Transactions on Dielectrics and Electrical Insulation, 28(5), pp.43–50. 22. Guoqiang, X.I.A. and Guangning, W.U., 2016. Quantitative Assessment of moisture content in Transformer Oil-paper Insulation Based on Extended Debye model and PDC. China International Conference on Electricity Distribution (CIECD 2016), pp.1–5. 23. He, Y., Jin, Y., Chen, H., Ding, Y., Cang, D. and Lu, H., 2007. Heat transfer and flow behaviour of aqueous suspensions of TiO 2 nanoparticles ( nanofluids ) flowing upward through a vertical pipe. International Journal of Heat and Mass Transfer, Volume 50, issues 11-12, pp.2272–2281. 24. Hough, G.A. and Merlyn., 2015. Implementing EPA’s Clean Power Plan: A Menu of Options. National Association of Clean Air Agencies, pp.1-465. 25. Hwang, J.G., Zhan, M., O'Sullivan, M., Pettersson, L.A.A, Hjortstam, O. and Liu, r., 2009. Electron Scavenging by Conductive Nanoparticles in Oil Insulated Power Transformers. Electrostatics Joint Conference, pp.1–12. 26. International Electrotechnical Commission, 2013. IEC 60422: Mineral Insulating oils in electrical equipment - Supervision and maintenance guidance. 27. Jin, H., 2015. Dielectric Strength and Thermal Conductivity of Mineral Oil based Nanofluids. Phd Thesis. Delft University of Technology. 28. Karthik, R., Negri, F. and Cavallini, A., 2016. Influence of Ageing on Dielectric characteristics of silicone di oxide , tin oxide and ferro nanofluids based mineral oil. International Conference on Advances in Electrical, Electronic, Information, Communication and Bio-Informatics (AEEICB), Chennai, pp. 40-43. 29. Krishna, K.P., Senthil K.S. and Ravindran, M., 2014. Investigation on mixed insulating fluids with nano fluids and antioxidants. Advances in Electrical Engineering (ICAEE), 2014 International Conference on, pp.1–4. 30. Lesaint, O., Gournay, P., Saker, A., Tobazeon, R., Aubin, J. and Mailhot, M., 1996. Streamer Propagation and Breakdown under AC in Mineral oil for Gaps up to 80 cm. International Conference on Conduction and Breakdown in Dielectric Liquids, pp. 251- 254. 31. Lv, Y.Z., Zhou, Y., Li, C.R., Wang, Q. and Qi, B., 2014. Recent Progress in Nanofluids Based on Transformer Oil : Preparation and Electrical Insulation Properties. IEEE Transactions on Dielectrics and Electrical Insulation, 30(5), pp.23–32. 32. Mahbubul, I.M., Saidur, R., and Amalina, M.A., 2012. International Journal of Heat and Mass Transfer Latest developments on the viscosity of nanofluids. International Journal of Heat and Mass Transfer, 55(4), pp.874–885. 33. Mansoor Taha Yaqoob., 2013. Transformer Thermal Model of the Disk Coils with Non Directed Oil Flow. Master Thesis. Universiti Tun Hussein Onn Malaysia. 34. Mansour, D.A. and Elsaeed, A.M., 2014. Heat transfer properties of transformer oil-based nanofluids filled with Al2O3 Nanoparticles. IEEE International Conference o Power and Energy (Pecon), Kuching, pp.123–127. 35. Mantin J. H., 1998. The J and P Transformer Book, Newnes, pp.1-957. 36. Martin, D. and Wang, Z.D., 2008. Statistical analysis of the AC breakdown voltages of ester based transformer oils. IEEE Transactions on Dielectrics and Electrical Insulation, Volume 15, pp.1044–1050. 37. Megger, 2017. Oil Test Set - User Guide, Ebook at www.megger.com, pp.1-27. 38. Mike, R., 2014. Vegetable oil as insulating fluid for transformers. Transmission and Distribution enegize, pp.37-40. 39. Michel, C., 2013, Chapter 16 - Atomic Structure and Chemical Bonds. E-Books 8th Grade, pp.462-489. 40. Murad, N.S., Muhamad, N.A., Suleiman, A.A. and Jamail, N.A.M, 2013. A Study on Palm Oil Moisture Absorption Level and Voltage Breakdown. Annual Report Conference on Electrical Insulation and Dielectric Phenomena, Shenzhen, pp.925–928. 41. Naidu M. S., and Kamaraju, V., 2013. High-Voltage Engineering 5e, India: McGraw Hill Education. 42. Nguyen, C.T., Boucher, S. and Mintsa, H.A., 2007. Temperature and particle-size dependent viscosity data for water-based nanofluids – Hysteresis phenomenon. International Journal Heat and Fluid Flow, 28, pp.1492–1506. 43. NovaScientific, 2014. NovaScientific - nanoparticles datasheet. Product/Material Safety datasheet book. 44. OECD Guideline, 1992. OECD for Testing of Chemicals OECD/OECD Guide line, pp.1- 65. 45. Ohki, Y., 2011. Development of High Performance Enviromentally Friendly Palm Fatty Acids Ester Insulating Oil for Transformers. News From Japan, 27(3), pp.55–57. 46. Plantation, S.D., 2014. Palm Oil Facts & Figures, Sime Darby Plantations, pp.1-8. 47. Ramasamy, R. and Murugan, R., 2015. Failure analysis of power transformer for effective maintenance planning in electric utilities. Engineering Failure Analysis, Volume 55, pp.182 – 192. 48. Rudyak, V.Y., 2013. Viscosity of Nanofluids — Why It Is Not Described by the Classical Theories. Advances in Nanoparticles, Volume 2, pp.266–279. 49. Senthilraja, S., Karthikeyan, M. and Gangadevi, R., 2010. Nanofluid Applications in Future Automobiles: Comprehensive Review of Existing Data. Nano-Micro Letters, Volume 2, pp.306-310. 50. Sabau, J., Fofana, I., Bouaicha, A., Hadjadj, Y. and Farzaneh, M., 2010. An environmentally friendly dissolved oxygen and moisture removal system for freely breathing transformers. IEEE Electrical Insulation Magazine, pp.35–43. 51. Sarit, K.D., Stephen U.S., Choi and Wenhua Y., 2007. Nanofluids Science and Technology, Canada: A John Wiley & Sons, INC. 52. Schroeder, S.P. and Morris, G.K., 2010. Nanofluids in a Forced-Convection Liquid Cooling System – Benefits and Design Challenges –. IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electrinic Systems, Las Vegas, pp.1–5. 53. Sima, W.X., Cao, X.F., Yang, Q., Song, H. and Shi, J., 2014. Preparation of Three Transformer Oil-Based Nanofluids and Comparison of Their Impulse Breakdown Characteristics. Nanoscience and Nanotechnology Letters, pp.250–256. 54. Sindhuja, K., Srinivasan, M. and Niveditha, N., 2018. Natural Esters as an Altenative to Mineral Oil in Transformer Applications. International Journal of Pure and Applied Mathematics, Volume 118, No. 20, pp.723-732. 55. Stoian, F.D., Holotescu, S. and Taculescu, A., 2013. Characteristic Properties of a Magnetic Nanofluid Used as Cooling and Insulating Medium in a Power Transformer. 8th International Symposium on Advanced Topic in Electrical Engineering (ATEE), Bucharest, pp.23–26. 56. Talib, M.A., Saedi, N.A., and Munim, W.N.W.A., 2013. Diagnosis of Winding Displacement in Power Transformer Using Frequency Response Analysis Technique. IEEE 7th International Power Engineering and Optimization Conference (PEOCO), Langkawi, pp.315–318. 57. Tenbohlen, S., Coenen, S., Djamali, M., Muller, A., Samimi, M.H. and Siegel, M., 2016. Diagnostic Measurements for Power Transformers. Energies 2016, 9(5), p.347. 58. Thomas, S., Balakrishna, C. and Sobhan, P., 2011. A review of experimental investigations on thermal phenomena in nanofluids. Nanoscale Research Letters, pp.1-21. 59. Timofeeva, E.V., 2011. Nanofluids for Heat Transfer – Potential and Engineering Strategies. Two Phase Flow, Phase Change and Numerical Modeling books, pp.435-450. 60. Tokunaga, J., Koide, H., Mogami, K. and Hikosaka, T., 2015. Comparative Studies on the Aging of Thermally Upgraded Paper Insulation in Palm Fatty Acid Ester , Mineral Oil , and Natural Ester. IEEE Transactions on Dielectrics and Electrical Insulation, Volume 23, pp.258–265. 61. Toumey, 2008. Reading Feynmann Into Nanotechnology; A text for a New Science. Techne: Research in Philosophy and Technology, pp.133-168. 62. Vishal, 2011. Transformer’s History and its Insulating Oil. Proceeding of the 5th National Conference: INDIACom 2011, pp.1–4. 63. Wakimoto, K., 2015. Features of Eco-Friendly Transformers Using Palm Fatty Acid Ester ( PFAE ), a New Vegetable-Based Insulation Oil. Meiden Reivew, 1(163), pp.39–45. 100 64. Wong, K.V. and Leon, O.D., 2010. Applications of Nanofluids: Current and Future. Advances in Mechanical Engineering, pp. 1-11. 65. Yanisko, P., Carlson, B., Dumoit, J. and Zheng, S., 2011. Nitrogen: A security blanket for the chemical industry. Chemical Engineering Progress, 107(11), pp.50–55. 66. Ye, X., Veeramachaneni, K., Yan, Y. and Osadciw, A. 2009. Unsupervised Learning and Fusion for Failure Detection in Wind Turbines. 12th International Conference on Information Fusion, Seattle, WA, pp.1497-1503. 67. Yue-fan, D., Wang, F., LV, Y., Li, X. and Li, C., 2010. Effect of TiO 2 Nanoparticles on the Breakdown Strength of Transformer Oil. IEEE International Symposium on Electrical Insulation, San Diego, 2, pp.1–3. 68. Yuliastuti, E., 2010. Analysis of Dielectric Properties: Comparision between Mineral Oil and Synthetic Ester Oil. Master Thesis. Delft University of Technology. 69. Zhong, Y., Lv, Y. and Li, C., 2013. Insulating Properties and Charge Characteristics of Natural Ester Fluid Modified by TiO 2 Semiconductive Nanoparticles. IEEE Transactions on Dielectrics and Electrical Insulation, 20(1), pp.135–140. 70. Ziomek, W., Vijayan, K., Boyd, D., Kuby, K. and Franchek, M., 2011. High Voltage Power Transformer Insulation Design. Electrical Insulation Conference (EIC), pp.211– 215. 71. Ziomek, W., 2012. Transformer electrical insulation. IEEE Transactions on Dielectrics and Electrical Insulation, 19(6), pp.1841–1842.