High-speed magnetolevitatve land transport with power supply by distributed photoelectric energy system with perspective energy storage
DOI:
https://doi.org/10.34185/1562-9945-4-141-2022-07Keywords:
high-speed land transport, magnetic levitation, power supply, distributed photovoltaic power system, energy storage devices, phase-metric radio navigation, high-speed con-trol systemAbstract
Among the various types of high-speed land transport a magnetic levitation transport (magnetoplanes) is recognized as the most promising, so research related to the improvement of this type of transport is relevant. The work is devoted to the integra-tion of three promising research technologies: magnetolevitative transport, photoelec-tric energy conversion and phase-metric radionavigation. It is this integration, i.e. the essential interpenetration of these three subsystems, results in an overall synergistic ef-fect. Achieving the goals of sustainable development of the national economic complex within the framework of traditional transport and energy technologies is problematic, as energy consumption of transport systems exceeds one third of energy consumption, and the fastest mode of transport – an air transport is one of the leading air pollutants. Therefore, the purpose of this work is to substantiate a promising way to solve this problem by combining in a single system of renewable energy technologies and magne-tolevitative transport. The methods of system analysis and decomposition, statistical analysis of solar insolation, radiophysical experiment, computer modeling of photovol-taic energy converters, algorithmization of current control processes and forecasting the energy storage devices state are involved. The result of the research is the development of physical and technical bases for the improvement of magnetolevitative transport. Conclusion: by combining in a single system of renewable energy technologies and mag-netic levitation transport it is possible to create a system of all-weather guaranteed power supply based on solar energy and a reliable precision high-speed control system in real time.
References
Shanghai maglev. URL: http://www.shanghai.ru/shanghai-maglev.html (дата звернення 17.05.2022) [in Russian].
Fritz E., Kluhspies J., Kircher R., Witt M. & Blow L. (2019) Energy Consumption of Track-Based High-Speed Transportation Systems: Maglev Technologies in Compari-son with Steel-Wheel-Rail. Transportation Systems and Technology. 4(3). DOI: https://doi.org/10.17816/transsyst201843s1134-155 [in English].
Kircher R., Palka R., Fritz E., Eiler K., Witt M., Blow L. & Klühspies J. (2018). Elec-tromagnetic Fields of High-Speed Transportation Systems: Maglev Technologies in Comparison with Steel-Wheel-Rail. The International Maglev Board. Research Se-ries 2. ISBN: 978-3-947957-01-9. Retrieved from
https://www.researchgate.net/publication/327972538 [in English].
Wenk M., Klühspies, J., Blow L., Kircher R., Fritz E., Witt M. & Hekler M. (2018) Maglev: Science Experiment or the Future of Transport? Practical Investigation of Future Perspectives and Limitations of Maglev Technologies in Comparison with Steel-Wheel-Rail. ISBN: 978-3-947957-00-2. Germany, DC: The International Mag-lev Board [in English].
Davydov А. (2019) Monitoring оf Changes in the Condition and Tendencies of De-velopment of Maglev Transportation Systems. Transportation Systems and Technol-ogy. 5(4). 5-15. DOI:10.17816/transsyst2019545-15 [in English].
De Oliveira R. A. H., Stephan R. M., Ferreira A. C., Murta-Pina J. (2020) Design and Innovative Test of a Linear Induction Motor for Urban MagLev Vehicles. IEEE Transactions on Industry Applications. 6. 6949-6956.
DOI: https://doi.org/10.1109/TIA2020.3023066 [in English].
Horizon 2020 (2015). Work Programme 2016 – 2017. 11. Smart, green and inte-grated transport. European Commission Decision C 6776 of 13 October 2015 [in English].
Dzenzerskiy V. A., Plaksin S. V., Toldaev V. G. & Shkil Yu. V. (2019). Integration of Maglev Highway and Distributed Solar Power Plant. Kyiv: Naukova dumka [in Russian].
Mukha A. M., Plaksin S. V. & Shkil Yu. V. Combined acceleration system for trac-tion drive of high-speed transport. Problems and prospects of railway transport de-velopment: Abstracts of the 81-st International scientific-practical conference. Dnipro, 2021. D .: DNUZT, 2021. - P. 78 – 79 (in Ukrain).
Simulating Solar Cell Devices Using Silvaco TCAD (2008). Simulation Standard. 2. 1–3 [in English].
