Design of Electrodynamic Suspension System for Hyperloop Pod

İbrahim Enes Uslu; Ahmet Selim Akkaş; Mehmet Onur Gulbahce; İlhan Kocaarslan

doi:10.5152/tepes.2025.24037

Design of Electrodynamic Suspension System for Hyperloop Pod

Abstract

Hyperloop technology, introduced in 2013, is a revolutionary transportation concept designed to achieve near-supersonic speeds of approximately 1220 km/h for long-distance travel. The key factor enabling the Hyperloop capsule to reach such high speeds is that the system is exposed to minimal friction. This study focuses on the design of an electrodynamic suspension disc for the levitation system of a Hyperloop capsule to be used in the Hyperloop Development Competition hosted by The Scientific and Technological Research Council of Türkiye (TUBITAK) Rail Transportation Technologies Institute (RUTE). The levitation system utilizes a high-speed rotating permanent magnet to generate magnetic forces that lift and stabilize the capsule above the rail. Following the completion of the analytical design, the system was simulated using the finite element method in ANSYS Electronics Desktop, and necessary geometric and electrical optimizations were performed based on the simulation results. Finally, the system was implemented, and the experimental results were analyzed to validate the design.

Keywords

Supporting Institution

This study was supported by İstanbul Technical University (İTU) Scientific Research Projects Unit (BAP) under Project MGA-2022-43948.

Project Number

MGA-2022-43948

Ethical Statement

Mehmet Onur Gulbahce is a member of the Advisory Board of Turkish Journal of Electrical Power, however, his involvement in the peer review process was solely as an author. Other authors have no conflicts of interest to declare.

References

1. E. Musk, Hyperloop Alpha, 2013.
2. C. Timperio, Linear Induction Motor (Lim) for Hyperloop Pod Prototypes Master’s thesis. ETH Zurich, Institute of Electromagnetic Fields (IEF), 2018.
3. I. A. Hansen, “Hyperloop transport technology assessment and system analysis,” Transp. Plan. Technol., vol. 43, no. 8, pp. 803–820, 2020.
4. L. Mitropoulos, A. Kortsari, A. Koliatos, and G. Ayfantopoulou, “The hyperloop system and stakeholders: A review and future directions,” Sustainability, vol. 13, no. 15, p. 8430, 2021.
5. A. Silic, “‘What Is Hyperloop and When Will It Be Ready?’, discover magazine,” 2022. [Online]. Available: https:// www.disc overmaga zine. com /technol ogy/what -is-hype rloop-an d-when-w ill-it-b e-ready. [.Accessed: 07 Oct, 2022].
6. R. Galluzzi et al., “A multi-domain approach to the stabilization of electrodynamic levitation systems,” J. Vib. Acoust., vol. 142, no. 6, p. 061004, 2020.
7. E. E. Dudnikov, “Advantages of a new hyperloop transport technology,” in Tenth International Conference Management of Large-Scale System Development (MLSD). New York, United States of America: IEEE, 2017, pp. 1–4.
8. J. K. Nøland, “A reality check on maglev technology for the hyperloop transportation system: Status update after a decade of development,” IEEE Access, vol. 12, pp. 162918–162928, 2024.

9. J. R. Dhobale, and S. Sahu, “Hyperloop transportation system,” Int. J. Innov. Eng. Res. Technol., pp. 1–3, 2018.
10. V. A. Kumar, G. Prajwal, F. Khan, C. Kapai, and N. Varun, “Design and development of hyperloop train,” Int. J. Res. Eng. Sci. Manag., vol. 3, pp. 235–238, 2020.
11. A. E. Hodaib, and S. F. A. Fattah, “Conceptional design of a hyperloop capsule with linear induction propulsion system,” Int. J. Aerosp. Mech. Eng., vol. 10, no. 5, pp. 997–1005, 2016.
12. F. H. Pelle, and S. R. Magdalena, Air Cushion Vehicle (Acv): History Development and Maglev Comparison, vol. 5, no. 1, 2019, pp. 5–25.
13. J. K. Nøland, “Prospects and challenges of the hyperloop transportation system: A systematic technology review,” IEEE Access, vol. 9, pp. 28439–28458, 2021.
14. M. N. O. Sadiku, and C. M. Akujuobi, “Magnetic levitation,” IEEE Potentials, vol. 25, no. 2, pp. 41–42, 2006.
15. R. Borcherts, and L. Davis, “Lift and drag forces for the attractive electromagnetic suspension systems,” IEEE Trans. Magn., vol. 10, no. 3, pp. 425–428, 1974.
16. L. Zhu, and C. R. Knospe, “Modeling of nonlaminated electromagnetic suspension systems,” IEEE ASME Trans. Mechatron., vol. 15, no. 1, pp. 59–69, 2009.
17. S. Choi, C. Lee, and J. Lim, “Analysis of guidance and levitation forces between hts magnets and conductive tubes for hyperloop,” AIP Adv., vol. 14, no. 3, 2024.
18. Y. Chen, W. Zhang, J. Z. Bird, S. Paul, and K. Zhang, “A 3-d analytic-based model of a null-flux halbach array electrodynamic suspension device,” IEEE Trans. Magn., vol. 51, no. 11, pp. 1–5, 2015.
19. M. O. Gulbahce, D. A. Kocabas, and F. Nayman, “Investigation of the effect of pole shape on braking torque for a low power eddy current brake by finite elements method,” in 8th International Conference on Electrical and Electronics Engineering (ELECO). New York, United States of America: IEEE, 2013, pp. 263–267.
20. A. Lendek, and C. M. Apostoaia, “Investigation of an electrodynamic magnetic levitation device,” in IEEE International Conference on Electro Information Technology (EIT). New York, United States of America: IEEE, 2020, pp. 297–303.
21. R. F. Post, and D. Ryutov, The Inductrack Concept: A New Approach to Magnetic Levitation,” tech. rep. Livermore, CA (United States): Lawrence Livermore National Laboratory (Lawrence Livermore National Laboratory, Office of Science), 1996.
22. R. F. Post, and D. D. Ryutov, “The inductrack: A simpler approach to magnetic levitation,” IEEE Trans. Appl. Supercond., vol. 10, no. 1, pp. 901–904, 2000.
23. M. O. Gulbahce, D. A. Kocabas, and A. K. Atalay, “Determination of the effect of conductive disk thickness on braking torque for a low power eddy current brake,” in New York, United States of America: IEEE, 2013, pp. 1272–1276.

Details

Primary Language

English

Subjects

Electrical Machines and Drives

Journal Section

Research Article

Authors

İbrahim Enes Uslu This is me
0009-0003-2878-605X
Türkiye

Ahmet Selim Akkaş This is me
0009-0000-8086-0585
Türkiye

Mehmet Onur Gulbahce ^*
0000-0002-6689-8445
Türkiye

İlhan Kocaarslan
Türkiye

Publication Date

June 16, 2025

Submission Date

December 26, 2024

Acceptance Date

January 31, 2025

Published in Issue

Year 2025 Volume: 5 Number: 2

DOI

https://doi.org/10.5152/tepes.2025.24037

IZ

https://izlik.org/JA42DJ43SG

Cite

RIS / Bibtex

APA

Uslu, İ. E., Akkaş, A. S., Gulbahce, M. O., & Kocaarslan, İ. (2025). Design of Electrodynamic Suspension System for Hyperloop Pod. Turkish Journal of Electrical Power and Energy Systems, 5(2), 125-131. https://doi.org/10.5152/tepes.2025.24037

AMA

1.Uslu İE, Akkaş AS, Gulbahce MO, Kocaarslan İ. Design of Electrodynamic Suspension System for Hyperloop Pod. TEPES. 2025;5(2):125-131. doi:10.5152/tepes.2025.24037

Chicago

Uslu, İbrahim Enes, Ahmet Selim Akkaş, Mehmet Onur Gulbahce, and İlhan Kocaarslan. 2025. “Design of Electrodynamic Suspension System for Hyperloop Pod”. Turkish Journal of Electrical Power and Energy Systems 5 (2): 125-31. https://doi.org/10.5152/tepes.2025.24037.

EndNote

Uslu İE, Akkaş AS, Gulbahce MO, Kocaarslan İ (June 1, 2025) Design of Electrodynamic Suspension System for Hyperloop Pod. Turkish Journal of Electrical Power and Energy Systems 5 2 125–131.

IEEE

[1]İ. E. Uslu, A. S. Akkaş, M. O. Gulbahce, and İ. Kocaarslan, “Design of Electrodynamic Suspension System for Hyperloop Pod”, TEPES, vol. 5, no. 2, pp. 125–131, June 2025, doi: 10.5152/tepes.2025.24037.

ISNAD

Uslu, İbrahim Enes - Akkaş, Ahmet Selim - Gulbahce, Mehmet Onur - Kocaarslan, İlhan. “Design of Electrodynamic Suspension System for Hyperloop Pod”. Turkish Journal of Electrical Power and Energy Systems 5/2 (June 1, 2025): 125-131. https://doi.org/10.5152/tepes.2025.24037.

JAMA

1.Uslu İE, Akkaş AS, Gulbahce MO, Kocaarslan İ. Design of Electrodynamic Suspension System for Hyperloop Pod. TEPES. 2025;5:125–131.

MLA

Uslu, İbrahim Enes, et al. “Design of Electrodynamic Suspension System for Hyperloop Pod”. Turkish Journal of Electrical Power and Energy Systems, vol. 5, no. 2, June 2025, pp. 125-31, doi:10.5152/tepes.2025.24037.

Vancouver

1.İbrahim Enes Uslu, Ahmet Selim Akkaş, Mehmet Onur Gulbahce, İlhan Kocaarslan. Design of Electrodynamic Suspension System for Hyperloop Pod. TEPES. 2025 Jun. 1;5(2):125-31. doi:10.5152/tepes.2025.24037