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Stefan cel Mare
University of Suceava
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Computer Science
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ROMANIA

Print ISSN: 1582-7445
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WorldCat: 643243560
doi: 10.4316/AECE


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  2/2023 - 8

Breakdown Probability, Reliability and Streamer Dynamics in Transformer Oil based Hybrid Nanofluid

BHATT, M. See more information about BHATT, M. on SCOPUS See more information about BHATT, M. on IEEExplore See more information about BHATT, M. on Web of Science, BHATT, P. See more information about BHATT, P. on SCOPUS See more information about BHATT, P. on SCOPUS See more information about BHATT, P. on Web of Science
 
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Download PDF pdficon (3,574 KB) | Citation | Downloads: 576 | Views: 1,389

Author keywords
breakdown voltage, nanoparticles, oil insulation, probability, streamer dynamics

References keywords
transformer(11), nanop(9), nanofluids(9), hybrid(9), thermal(8), nanofluid(8), materials(6), today(5), dielectric(5), technology(4)
Blue keywords are present in both the references section and the paper title.

About this article
Date of Publication: 2023-05-31
Volume 23, Issue 2, Year 2023, On page(s): 67 - 74
ISSN: 1582-7445, e-ISSN: 1844-7600
Digital Object Identifier: 10.4316/AECE.2023.02008
Web of Science Accession Number: 001009953400008
SCOPUS ID: 85164362234

Abstract
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Full text preview
A contemporary research topic of interest is hybrid nanofluids. The goal of this study is to see how hybrid nanoparticles in transformer oil affect the failure probability, reliability, and streamer dynamics when subjected to massive electrical stress. A 2D axisymmetric hydrodynamic drift-diffusion model is developed to study the streamer dynamics in a hybrid nanofluid with different charging times. Failure probability and reliability for different nanofluids are estimated using the Weibull distribution function. The statistical study reveals that the hybrid nanofluid is more reliable and less dangerous, extending the transformers' service life. When compared to mineral oil and individually dispersed nanoparticles, a homogeneous mixture of Fe3O4 and Al2O3 nanoparticles reduces failure rate by 73.94%, 56.29%, and 30.41%, respectively. For positive streamer dynamics, the influence of altering the charging time of distributed multiple nanoparticles was explored. The dispersion of hybrid nanoparticles in transformer oil has been found to minimize the ionization rate, streamer velocity, and streamer re-ignition rate.


References | Cited By  «-- Click to see who has cited this paper

[1] M. Rafiq, M. Shafique, A. Azam, M. Ateeq, "Transformer oil-based nanofluid: The application of nanomaterials on thermal, electrical and physicochemical properties of liquid insulation - a review," Ain Shams Engineering Journal, vol. 12, no. 1, pp. 555-576, 2021.
[CrossRef] [Web of Science Times Cited 59] [SCOPUS Times Cited 71]


[2] R. Ekiciler, "Effects of novel hybrid nanofluid (TiO2-Cu/EG) and geometrical parameters of triangular rib mounted in a duct on heat transfer and flow characteristics," Journal of Thermal Analysis and Calorimetry, vol. 143, pp. 1371-1387, 2021.
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[3] J. Yu, A. Wang, M. Zhang, Z. Lin, "Water treatment via non-membrane inorganic nanoparticles/cellulose composites," Materials Today, vol. 50, pp. 329-357, 2021.
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[7] T. Rasheed, T. Hussain, M. Anwar, J. Ali, K. Rizwan, M. Bilal, F. Alshammari, N. Alwadai, A. Almuslem, "Hybrid nanofluids as renewable and sustainable colloidal suspensions for potential photovoltaic/thermal and solar energy applications," Frontiers in Chemistry, vol. 9, pp. 1-20, 2021.
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[8] L. Sundar, S. Nesfin, Y. Sintie, V. Punnaiah, A. Chamkha, A. Sousa, "A review on the use of hybrid nanofluid in a solar flat plate and parabolic trough collectors and its enhanced collector thermal efficiency," Journal of Nanofluids, vol. 10, pp. 147-171, 2021.
[CrossRef] [Web of Science Times Cited 13]


[9] Q. Zheng, J. Lee, X. Shen, X. Chen, J. Kim, "Graphene-based wearable piezoresistive physical sensor," Materials Today, vol. 36, pp. 158-179, 2020.
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[10] S. Ding, N. Zhang, Z. Lyu, W. Zhu, Y. Chang, X. Hu, D. Du, Y. Lin, "Protein-based nanomaterials and nanosystems for biomedical applications: A review," Materials Today, vol. 43, pp. 166-184, 2021.
[CrossRef] [Web of Science Times Cited 62] [SCOPUS Times Cited 69]


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[12] A. Sajeeb, P. Rajendrakumar, "Investigation on the rheological behavior of coconut oil based hybrid CeO2/CuO nanolubricants," Part J: Journal of Engineering Tribology, vol. 233, pp. 170-177, 2019.
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[13] S. Sumathi, R. Rajesh, P. Subburaj, "Investigation of dielectric strength of transformer oil based on hybrid TiO2/Al2O3/MoS2 nanofluid using taguchi and response surface methodology," IETE Journal of Research, vol. 67, pp. 817-825, 2019.
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[14] S. Aberoumand, A. Jafarimoghaddam, "Tungsten (III) Oxide (WO3)-silver/transformer oil hybrid nanofluid: preparation, stability, thermal conductivity and dielectric strength," Alexandria Engineering Journal, vol. 57, pp. 169-174, 2018.
[CrossRef] [Web of Science Times Cited 92] [SCOPUS Times Cited 107]


[15] A. Thabet, M. Allam, S. Shaaban, "Assessment of individual and multiple nanoparticles on electrical insulation of power transformers nanofluids," Electric Power Components and Systems, vol. 47, pp. 420-430, 2019.
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[17] S. Qing, W. Rashmi, M. Khalid, T. Gupta, M. Nabipoor, M. Hajibeigy, "Thermal conductivity and electrical properties of hybrid SiO2-graphene naphthenic mineral oil nanofluid as potential transformer oil," Materials Research Express, vol. 4, 2017.
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[CrossRef]


[21] Methods for the determination of the lightning breakdown voltage of insulating liquids, IEC Standard 60897, 1987

[22] M. Bhatt, P. Bhatt, "Comparative analysis of dielectric strength and electron velocity in transformer oil based nanofluids," Journal of Engineering Science and Technology, vol. 16, pp. 1177-1192, 2021

[23] M. Bhatt, P. Bhatt, "Finite element based comparative analysis of positive streamers in multi dispersed nanoparticle based transformer oil," International Journal of Engineering and Technology Innovation, vol. 12, no. 1, pp. 29-44, 2022.
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[25] J. Hwang, F. Sullivan, M. Zahn, O. Hjorstam, A. Pettersson, R. Liu, "Modeling of streamer propagation in transformer oil-based nanofluids," Annual Report Conference on Electrical Insulation Dielectric Phenomena, Canada, pp. 361-366, 2008.
[CrossRef] [SCOPUS Times Cited 88]




References Weight

Web of Science® Citations for all references: 1,068 TCR
SCOPUS® Citations for all references: 1,269 TCR

Web of Science® Average Citations per reference: 41 ACR
SCOPUS® Average Citations per reference: 49 ACR

TCR = Total Citations for References / ACR = Average Citations per Reference

We introduced in 2010 - for the first time in scientific publishing, the term "References Weight", as a quantitative indication of the quality ... Read more

Citations for references updated on 2024-12-03 06:02 in 161 seconds.




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