Magnetic Force Calculation of Movable YBCO Superconducting Helical Coils Applicable to Electric Vehicles Wireless Power Transfer

Pahlavani, M. Alizadeh; Dehestani Kolagar, A.; Soltani, I.

doi:10.22061/jecei.2021.7505.399

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	Magnetic Force Calculation of Movable YBCO Superconducting Helical Coils Applicable to Electric Vehicles Wireless Power Transfer
Journal of Electrical and Computer Engineering Innovations (JECEI)
مقاله 13، دوره 10، شماره 1، فروردین 2022، صفحه 153-162 اصل مقاله (1.58 M)
نوع مقاله: Original Research Paper
شناسه دیجیتال (DOI): 10.22061/jecei.2021.7505.399
نویسندگان
M. Alizadeh Pahlavani¹؛ A. Dehestani Kolagar¹؛ I. Soltani^* ²
¹Faculty of Electrical and Computer Engineering, Malek Ashtar University of Technology, Tehran, Iran
²Supreme National Defense University and institute for Strategic Research, Tehran, Iran
تاریخ دریافت: 26 اردیبهشت 1400، تاریخ بازنگری: 13 مرداد 1400، تاریخ پذیرش: 16 شهریور 1400
چکیده
Background and Objectives: Today, replacing gasoline-powered vehicles with electric vehicles (EVs) and connecting them to an electric power source have made the optimal usage of energy-saving resources. Therefore, wireless Power Transfer (WPT) outstands as an alternative technology to improve the user perception about the charging process of the EVs. Superconducting coils (SCs) with high-temperature have an applied feature in decreasing losses of wireless power transmission (WPT). The Magnetic force has effects of overall deformation modes between two current carrier superconducting coils, i.e. axial extension, torsion, and bending. Coil misalignment is a fundamental problem and its impact on wireless power transmission efficiency is very complex. The analysis of a magnetic force which is presented in this paper are beneficially for the design and application of the WPT systems. Here, a fast analytical solution is presented to obtain the magnetic force between the transmitter and receiver helical superconducting coils in different positions. Methods: In this paper, a new method applied to solve the numerically magnetic force solutions in different superconducting coils mismatch states for WPT. Finally, for improvement of efficiency, the WPT system has been designed on the basis of mutual inductance changes which receiving helical coil was moved inside the transmitting helical coil. Hence, the magnetic force calculation of movable YBCO superconducting helical coils inside each other is presented. These models have been compared with the FEM. Results: Results show that the presented equations are reliable as well. According to the comparing the analysis and FEM data, the obtained results indicated the errors with less than 0.0064%. Also, results show an excellent agreement with respect to the finite element method. Conclusion: In this paper, the numerical solutions of magnetic force in different superconducting coils mismatch states were solved by a new method. The magnetic force analysis basics introduced in this paper are useful to develop and apply for wireless power transmission system. The simulation results show that only by applying some constraints, the efficiency of the transmitted wireless power will be optimized. Then, analytical models have been presented which make it possible to calculate the axial force which was exerted between two axially Helical magnetized and two thin coils in air. Also, the analytical stiffness calculation applied between these distributions of magnetic source has been presented. These models have been compared with the FEM to show an appropriate consistency.
کلیدواژه‌ها
Magnetic Force؛ Mutual Inductance؛ Non-alignment؛ Wireless Power Transmission؛ Superconducting Helical Coils

مراجع
[1] M.R. Pahlavani Alizadeh, I.Soltani, A. Dehestani Kolagar, "Numerical and analytical investigation of the effects of dimensional parameters on mutual inductance of helical-shaped YBCO superconducting variable inductors," Mater. Res. Express, 6(12): 126001, 2019. [2] H. Yingda, Y. Wang, Y. Hu, W. Chen, Z. Yan, "Superconducting electrode capacitor based on double-sided YBCO thin film for wireless power transfer applications," Supercond. Sci. Technol., 32(1): 015010, 2018. [3] D. Chung, Yoon, C. Young Lee, H. Kang, Y. Gun Park, "Design considerations of superconducting wireless power transfer for electric vehicle at different inserted resonators," IEEE Trans. Appl. Supercond., 26(4) : 1-5, 2016. [4] I. Ryota, K. Igarashi, Y. Nagasaki, D. Miyagi, M. Tsuda, H. Matsuki, "Electric power transmission characteristics of a wireless power transmission system using high temperature superconducting coils for railway vehicle," IEEE Trans. Appl. Supercond., 29(5): 1-5, 2019. [5] Z. Sergey, B. Zechikhin, N. Ivanov, J. Nekrasova, "Analytical calculation of the magnetic field in electrical machines with HTS excitation and armature windings," Mater. Res. Express, 6(7): 076001, 2019. [6] A. Moradnouri, M. Vakilian, A. Hekmati, M. Fardmanesh, "HTS transformer windings design using distributive ratios for minimization of short circuit forces," J. Supercond. Novel Magn., 32(2): 151-158, 2019. [7] S. Hui, W. Zhong, C. Kwan Lee, "A critical review of recent progress in mid-range wireless power transfer," IEEE Trans. Power Electron., 29(9): 4500-4511, 2013. [8] A. Benhama, A.C. Williamson, A.B.J. Reece, "Force and torque computation from 2-D and 3-D finite element field solutions," IEE Proc. Electr. Power Appl., 146(1): 25-31, 1999. [9] P. Dular, G. Meunier, F. Piriou, A. Demenko, D.Stachowiak, "Electromagnetic torque calculation using magnetic network methods," COMPEL- Int. J. comput. Math. Electr. Electron. Eng., 27(1): 17-26, 2008. [10] J. Xia, H. Bai, H. Yong, H.W. Weijers, T.A. Painter, M.D. Bird, "Stress and strain analysis of a REBCO high field coil based on the distribution of shielding current," Supercond. Sci. Tech. 32(9): 095005, 2019. [11] J. Compter, "Mutual inductance and forces between two non-coaxial co-planar circular thin-wall air coils," COMPEL- Int. J. comput. Math. Electr. Electron. Eng., 38(1): 216-231, 2019. [12] A. Shafee, M. Saber Shahraki, A. Hosseini Taleghani, N. Dang Nam, I. Tlili, "Analysis of nanomaterial flow among two circular tubes in the presence of magnetic force," J. Therm. Anal. Calorim., 144(3) : 993-1002-2021. [13] J.T. Conway, "Inductance calculations for circular coils of rectangular cross section and parallel axes using Bessel and Struve functions," IEEE Trans. Magn., 46(1): 75-81, 2009. [14] S. Babic, F. Sirois, C. Akyel, G. Lemarquand, V. Lemarquand, R. Ravaud, "New formulas for mutual inductance and axial magnetic force between a thin wall solenoid and a thick circular coil of rectangular cross-section," IEEE Trans. Magn., 47(8): 2034-2044, 2011. [15] Y. Ren, F. Wang, G. Kuang, W. Chen, Y. Tan, J. Zhu, P. He, "Mutual inductance and force calculations between coaxial bitter coils and superconducting coils with rectangular cross section," J. Supercond. Novel Magn., 24(5): 1687-1691, 2011. [16] M.R. Alizadeh Pahlavani, A. Shoulaie, "Elimination of compressive stress in helical-toroidal-coil advanced structure for reactor plasmas," IEEE Trans. Plasma Sci., 37(11): 2166-2177, 2009. [17] M.R. Alizadeh Pahlavani, H. A. Mohammadpour, "Electromagnetic torque and force analysis of toroidal field coil using numerical and experimental results applicable to tokamak reactors," IEEE Trans. Plasma Sci., 38(7): 1632-1638, 2010. [18] A. Nishimura, T. Mito, S. Yamada, S. Imagawa, K. Takahata, N. Yanagi, H. Chikaraishi, "Measurement of superconductor motion in R&D coil for supercooling of the LHD helical coil," IEEE Trans. Appl. Supercond., 14(2): 1515-1518, 2004. [19] G. Ning, K. Zhao, M. Fu, "A passive current sharing method for multi-transmitter inductive power transfer systems," IEEE Trans. Ind. Electron., 2021. [20] F.W. Grover, "Inductance Calculations–New York," Van Norstrand Company inc ,1946. [21] S. Tolpygo, E.B. Golden, T.J. Weir, Vl. Bolkhovsky, "Inductance and mutual inductance of superconductor integrated circuit features with sizes down to 120 nm. part I," arXiv preprint arXiv:2101.07457 -2021. [22] X. Zhang, C.Quan, Z.Li, "Mutual inductance calculation of circular coils for an arbitrary position with electromagnetic shielding in wireless power transfer systems," IEEE Trans. Transp. Electrif.,2021. [23] F. Wen, X. Chu, Q. Li, Wenhan Zhao, X. Zhu, Y. Wu, "Receiver localization strategy of wireless charging system based on mutual inductance disturbance," IEEE Trans. Appl. Supercond., 2021. [24] C. Yu, R. Lu, Y. Mao, L. Ren, C. Zhu, "Research on the model of magnetic-resonance based wireless energy transfer system," in Proc. 2009 IEEE Vehicle Power and Propulsion Conference: 414-418. IEEE, 2009. [25] S. Li, C. Chris Mi, "Wireless power transfer for electric vehicle applications," IEEE J. Emerging Sel. Top. Power Electron., 3(1): 4-17, 2014. [26] O. Tremblay, L.A. Dessaint, "Experimental validation of a battery dynamic model for EV applications," World Electr. Veh. J., 3(2): 289-298, 2009. [27] J. Meins, G. Bühler, R. Czainski, F. Turki. "Contactless inductive power supply magnetically levitated systems and linear drives" In Proc. intern. conf., Dresden: 13-15, 2006. [28] X. Zhou, B. Chen, Y. Luo, R. Zhu, "Analytical calculation of mutual inductance of finite-length coaxial helical filaments and tape coils," Energies, 12(3): 566, 2019. [29] S. Lucyszyn, "Review of radio frequency microelectromechanical systems technology," IEE Proc. Scie. Meas. Technol. 151(2): 93-103, 2004. [30] R.H. Pennington, Introduction Computer Methods and Numerical Analysis. Macmillan, 1970.
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Magnetic Force Calculation of Movable YBCO Superconducting Helical Coils Applicable to Electric Vehicles Wireless Power Transfer