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Stefan cel Mare
University of Suceava
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Print ISSN: 1582-7445
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WorldCat: 643243560
doi: 10.4316/AECE


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A Novel High Voltage Dielectric Test System Based on Resonant Circuits Using the Magnetically Controllable Inductance

ZHANG, Y. See more information about ZHANG, Y. on SCOPUS See more information about ZHANG, Y. on IEEExplore See more information about ZHANG, Y. on Web of Science, DAI, D. See more information about  DAI, D. on SCOPUS See more information about  DAI, D. on SCOPUS See more information about DAI, D. on Web of Science, ZHANG, J. See more information about  ZHANG, J. on SCOPUS See more information about  ZHANG, J. on SCOPUS See more information about ZHANG, J. on Web of Science, CHEN, X. See more information about CHEN, X. on SCOPUS See more information about CHEN, X. on SCOPUS See more information about CHEN, X. on Web of Science
 
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Download PDF pdficon (784 KB) | Citation | Downloads: 1,726 | Views: 2,622

Author keywords
high-voltage techniques, resonance, insulation testing, magnetic variables control, EMTDC

References keywords
resonance(16), power(16), voltage(11), test(10), system(9), series(8), parallel(7), high(7), transformer(6), technology(5)
Blue keywords are present in both the references section and the paper title.

About this article
Date of Publication: 2020-02-28
Volume 20, Issue 1, Year 2020, On page(s): 3 - 10
ISSN: 1582-7445, e-ISSN: 1844-7600
Digital Object Identifier: 10.4316/AECE.2020.01001
Web of Science Accession Number: 000518392600001
SCOPUS ID: 85083709989

Abstract
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Full text preview
Dielectric tests such as high voltage withstand test is important to verify whether the electrical devices are in reliable working condition or not. This paper presents a novel high voltage dielectric test system up to 160kV AC based on resonant circuits using the magnetically controllable inductance. Firstly, the working principle and the design of the magnetically controllable inductance are introduced. In addition, a finite-element model is completed and analyzed to verify the designs of the magnetically controllable inductance. Next, resonant circuits and the control scheme of the dielectric test system are described. Finally, the proposed testing system is simulated using PSCAD/EMTDC. The test system can perform series or parallel resonance AC tests by adjusting the inductance in the resonant circuit to meet the various requirements of the equipment to be examined. Compared with the conventional high-voltage test systems, the proposed test system has the advantages of compact structure, stable output voltage, and strong adaptability of the test method.


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

[1] G. Xiangxiang, L. Haojun, J. Zhuanzhuan, and P. Jianfei, "Research of shunt reactor switching test for 1100kV UHV circuit-breakers," 2017 4th International Conference on Electric Power Equipment - Switching Technology (ICEPE-ST), Xi'an, 2017, pp. 821-824.
[CrossRef] [SCOPUS Times Cited 3]


[2] C. Jingying, et al., "Study on Optimization of Withstand Voltage Test for Long-Distance Power Cable Multi-Resonance System," 2018 International Conference on Power System Technology (POWERCON), Guangzhou, 2018, pp. 3936-3939.
[CrossRef] [SCOPUS Times Cited 2]


[3] Y. Li, J. Lian, J. Jin, Z. Liu, Z. Zhang and J. Cao, "Testing Research on Auxiliary Circuit Oscillation Characteristic Parameters for High Voltage DC Transfer Switch," 2018 IEEE 3rd Advanced Information Technology, Electronic and Automation Control Conference (IAEAC), Chongqing, 2018, pp. 1184-1188.
[CrossRef] [SCOPUS Times Cited 2]


[4] W. Bo, et al., "Design of 1100kV/I0kA Ultra-High-Voltage Alternating Current Long-term Live Test Loop," 2018 China International Conference on Electricity Distribution (CICED), Tianjin, 2018, pp. 685-692.
[CrossRef] [SCOPUS Times Cited 2]


[5] C. Liu, M. Shen, Q. Li, C. Su, and P. Wei, "Application of Neural Network in Atmospheric Correction of High Voltage Test," 2018 IEEE International Conference on High Voltage Engineering and Application (ICHVE), ATHENS, Greece, 2018, pp. 1-4.
[CrossRef] [SCOPUS Times Cited 1]


[6] G. Ueta, T. Tsuboi and S. Okabe, "Evaluation of overshoot rate of lightning impulse withstand voltage test waveform based on new base curve fitting methods - application to practical diverse waveforms," in IEEE Transactions on Dielectrics and Electrical Insulation, vol. 19, no. 1, pp. 352-362, February 2012.
[CrossRef] [Web of Science Times Cited 8] [SCOPUS Times Cited 12]


[7] H. Wang, Y. Cao, J. Fan, Research on Discharge Faults in DC Voltage Withstand Test of HVDC Project Converter Transformer, Transformer, vol. 56, no. 8, pp.60-62, August 2019.

[8] B. J. Lee, S. H. Kim, T. J. Kwon, J. H. Choi, and M. H. Kim, "Analysis of the test line impedance and strength for short time and peak withstand test of KERI's new high power laboratory," 2015 3rd International Conference on Electric Power Equipment - Switching Technology (ICEPE-ST), Busan, 2015, pp. 451-454.
[CrossRef] [SCOPUS Times Cited 1]


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[CrossRef] [SCOPUS Times Cited 1]


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[CrossRef] [SCOPUS Times Cited 4]


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[CrossRef] [Web of Science Times Cited 9] [SCOPUS Times Cited 8]


[12] L. Dong, J. Kong, J. Feng, and Y. Zhang, "Sub synchronous Resonance Mitigation for Series Compensation Transmission System of DFIG Based on PR Control," 2019 IEEE 10th International Symposium on Power Electronics for Distributed Generation Systems (PEDG), Xi'an, China, 2019, pp. 734-738.
[CrossRef] [Web of Science Times Cited 3] [SCOPUS Times Cited 6]


[13] N. Jahan, A. Barakat, and R. K. Pokharel, "Study of phase noise improvement of K-band VCO using additional series resonance realized by DGS resonator on CMOS technology," 2017 IEEE Asia Pacific Microwave Conference (APMC), Kuala Lumpur, 2017, pp. 1014-1017.
[CrossRef] [SCOPUS Times Cited 3]


[14] Y. Yang, R. Han, Y. Jin, R. Tao, T. Li, and N. Li, "Analysis of the Influencing Factors of Quality Factor of Series Resonance System with Large Capacity," 2019 IEEE 3rd International Conference on Circuits, Systems and Devices (ICCSD), Chengdu, China, 2019, pp. 65-68.
[CrossRef] [SCOPUS Times Cited 1]


[15] W. Yeetum and V. Kinnares, "Parameters Identification for Series Resonance in Power Systems Using a Frequency Response Technique," 2018 International Electrical Engineering Congress (iEECON), Krabi, Thailand, 2018, pp. 1-4.
[CrossRef] [SCOPUS Times Cited 1]


[16] L. Liang et al., "Preliminary Experiment of a SFCL Based on Air-Core Superconducting Transformer and Inductor-Capacitor Series Resonant Limiter," 2018 IEEE International Conference on Applied Superconductivity and Electromagnetic Devices (ASEMD), Tianjin, 2018, pp. 1-2.
[CrossRef] [SCOPUS Times Cited 1]


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[CrossRef] [Web of Science Times Cited 1] [SCOPUS Times Cited 3]


[18] M. Lei, S. Wang, Y. Guo, T. Xia, D. Ming and X. Zheng, "An Automatic Implementation Scheme of in-Field Power Frequency Series Resonance System," 2018 2nd IEEE Conference on Energy Internet and Energy System Integration (EI2), Beijing, 2018, pp. 1-5.
[CrossRef] [SCOPUS Times Cited 1]


[19] X. Zhang, C. Yu, F. Liu, F. Li, and H. Xu, "Overview on resonance characteristics and resonance suppression strategy of multi-parallel photovoltaic inverters," in Chinese Journal of Electrical Engineering, vol. 2, no. 1, pp. 40-51, June 2016.
[CrossRef] [SCOPUS Times Cited 12]


[20] S. Chaladying, A. Charlangsut, and N. Rugthaichareoncheep, "Parallel resonance impact on power factor improvement in power system with harmonic distortion," TENCON 2015 - 2015 IEEE Region 10 Conference, Macao, 2015, pp. 1-5.
[CrossRef] [SCOPUS Times Cited 4]


[21] S. Wang, J. Chen, Z. Hu, and M. Liu, "Study on series-parallel mixed-resonance model of wireless power transfer via magnetic resonance coupling," 2016 Progress in Electromagnetic Research Symposium (PIERS), Shanghai, 2016, pp. 2941-2945.
[CrossRef] [SCOPUS Times Cited 8]


[22] V. Kindl, T. Kavalir and R. Pechanek, "Key construction aspects of low frequency wireless power transfer system using parallel resonance," 2015 17th European Conference on Power Electronics and Applications (EPE'15 ECCE-Europe), Geneva, 2015, pp. 1-5.
[CrossRef] [SCOPUS Times Cited 14]


[23] C. Xu, K. Dai, X. Chen, L. Peng, Y. Zhang and Z. Dai, "Parallel Resonance Detection and Selective Compensation Control for SAPF With Square-Wave Current Active Injection," in IEEE Transactions on Industrial Electronics, vol. 64, no. 10, pp. 8066-8078, Oct. 2017.
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[24] W. Yeetum and V. Kinnares, "Parallel Active Power Filter Based on Source Current Detection for Antiparallel Resonance With Robustness to Parameter Variations in Power Systems," in IEEE Transactions on Industrial Electronics, vol. 66, no. 2, pp. 876-886, Feb. 2019.
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[25] Z. Shuai, D. Liu, J. Shen, C. Tu, Y. Cheng and A. Luo, "Series and Parallel Resonance Problem of Wideband Frequency Harmonic and Its Elimination Strategy," in IEEE Transactions on Power Electronics, vol. 29, no. 4, pp. 1941-1952, April 2014.
[CrossRef] [Web of Science Times Cited 57] [SCOPUS Times Cited 85]


[26] J. Penttonen, M. Lehtonen and S. Muhammad, "Smart grid element: efficient controllable inductance with virtual air gap," in IET Generation, Transmission & Distribution, vol. 12, no. 1, pp. 72-77, 2 1 2018.
[CrossRef] [Web of Science Times Cited 4] [SCOPUS Times Cited 6]




References Weight

Web of Science® Citations for all references: 134 TCR
SCOPUS® Citations for all references: 245 TCR

Web of Science® Average Citations per reference: 5 ACR
SCOPUS® Average Citations per reference: 9 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 2024-11-17 22:57 in 169 seconds.




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