Page 229 - 2024-Vol20-Issue2

P. 229

225 | Salman & Mohammed & Mohammed

an equivalent circuit method,” IET Electrical Systems in [15] T. Tong and D. Wang, “Analytical modeling and optimal
Transportation, vol. 11, no. 3, pp. 218–226, 2021. design of disk permanent magnet eddy current coupler,”
in 2023 2nd Conference on Fully Actuated System The-
[5] M. I. Gonza´lez, “Experiments with eddy currents: ory and Applications (CFASTA), pp. 900–905, IEEE,
the eddy current brake,” European journal of physics, 2023.
vol. 25, no. 4, p. 463, 2004.
[16] C. Chen, J. Xu, and X. Wu, “Analytical calculation of
[6] S. Cho, H.-C. Liu, J. Lee, C.-M. Lee, S.-C. Go, S.-H. braking force of super-high speed maglev eddy current
Ham, J.-H. Woo, and H.-W. Lee, “Design and analy- braking system,” in 2019 22nd International Conference
sis of the eddy current brake with the winding change,” on Electrical Machines and Systems (ICEMS), pp. 1–5,
Journal of Magnetics, vol. 22, no. 1, pp. 23–28, 2017. IEEE, 2019.

[7] S. Zhou, H. Yu, M. Hu, and L. Huang, “Design of perma- [17] K. Karakoc, A. Suleman, and E. J. Park, “Analytical
nent magnet eddy current brake for a small scaled elec- modeling of eddy current brakes with the application
tromagnetic launch model,” Journal of Applied Physics, of time varying magnetic fields,” Applied Mathematical
vol. 111, no. 7, 2012. Modelling, vol. 40, no. 2, pp. 1168–1179, 2016.

[8] D. Zheng, X. Guo, Y. Li, W. Cong, and S. Jiang, [18] K. Filipecka, P. Pawlik, A. Kozdras´, J. Filipecki, K. Paw-
“Torque analysis of axial-flux permanent magnet cou- lik, and J. Wyslocki, “Magnetic properties and phase
plers with skewed slots using electromagnetic-thermal constitution of the nanocrystalline fe 65 pr 9 b 18 w 8
semi-analytical model,” in 2020 Chinese Control And alloy ribbons.,” Acta Physica Polonica A, vol. 131, no. 5,
Decision Conference (CCDC), pp. 4077–4081, IEEE, pp. 1207–1211, 2017.
2020.
[19] M. Hano, T. Miyamura, and M. Hotta, “Finite element
[9] E. Galardi, E. Meli, D. Nocciolini, L. Pugi, and A. Rindi, eddy current analysis by novel mixed-order vector ele-
“Development of efficient models of magnetic braking ments,” International Journal of Applied Electromagnet-
systems of railway vehicles,” International Journal of ics and Mechanics, vol. 14, no. 1-4, pp. 19–22, 2002.
Rail Transportation, vol. 3, no. 2, pp. 97–118, 2015.
[20] M. Gulec and M. Aydin, “Modelling and analysis of a
[10] K. Karakoc, A. Suleman, and E. J. Park, “Analytical new axial flux permanent magnet biased eddy current
modeling of eddy current brakes with the application brake,” in 2016 XXII International Conference on Elec-
of time varying magnetic fields,” Applied Mathematical trical Machines (ICEM), pp. 459–465, IEEE, 2016.
Modelling, vol. 40, no. 2, pp. 1168–1179, 2016.
[21] R. W. Johnson and S. P. Brown, “Application of per-
[11] J. A. Doe and B. C. Smith, “Electromagnetic theory of manent magnetic eddy current braking in public trans-
permanent magnetic eddy current braking,” Journal of portation,” Transportation Research Part C: Emerging
Applied Physics, 2014. Technologies, 2015.

[12] R. Sattarov and D. Garafutdinov, “Simulation of a self-
regulating eddy-current brakes with permanent mag-
nets,” in 2021 International Ural Conference on Electri-
cal Power Engineering (UralCon), pp. 587–591, IEEE,
2021.

[13] K. J. Lee and S. H. Park, “Enhancing reliability and
safety of industrial machinery through permanent mag-
netic eddy current braking,” Mechanical Systems and
Signal Processing, 2016.

[14] O. Taqavi and N. Taghavi, “Development of a mixed
solution of maxwell’s equations and magnetic equivalent
circuit for double-sided axial-flux permanent magnet
machines,” IEEE Transactions on Magnetics, vol. 57,
no. 4, pp. 1–11, 2021.

224 225 226 227 228 229 230 231 232 233 234