PERSPECTIVE TRANSPORT-POWER SYSTEM BASED ON THE INTEGRATION OF MAGLEV-TECHNOLOGY AND DISTRIBUTED PHOTO-ELECTRIC STATION
DOI:
https://doi.org/10.15802/stp2018/123116Keywords:
magnetolevitating (MAGLEV) transport, distributed power supply system, sun energy, precision fast-acting control systemAbstract
Purpose. The research main purpose is the perfection of magnetolevitating technology on electrodynamic suspension and providing its functioning on the base of ecologically rational energy systems. It means creation of the MAGLEV transport-power system which uses renewable energy sources (in particular, photoelectric converters) and is connected to national/local networks as an energy user and producer simultaneously. Methodology. Conducted research, analysis and summary conclusions are based both on the results of works on the given subject, and own works of authors. The methods of systems analysis and computer design of components of the large cyber-physical transport-power system were used during research conducting. Findings. The physical-technical foundations of conception of the perspective transport-power system, which includes high-speed ground vehicle on electrodynamic suspension and distributed photo-electric energy complex are developed. The adapt to the performance of the given transport type and guaranteeing its safe functioning in any weather terms. Originality. For the first time authors substantiated the possibility for creation of single transport complex uniting the speed magnetolevitating system and distributed power supply system on the base of sun energy. It is simultaneously the inalienable part of the precision fast-acting control system, working in the real-time mode. Practical value. The offered scientific-technical solution allows on the base of renewable energy source to solve the problems of power supply and a high-speed transport control. Due to the inclusion of the distributed power supply system into local intellectual networks on the SMART-grid technology it gives the possibility to optimize energy consumption of territories neighboring to high-speed way.References
Bocharov, V. I., Sally, I. V., & Dzenzerskiy, V. A. (1988). Transport na sverkhprovodyashchikh magnitakh. Rostov-on-Don: Izdatelstvo rostovskogo universiteta. (in Russian)
Vanke, V. A. (2007). Millimeter Wave Electronics. Prospects for Space Energy. Electronics: Science, Technology, Business, 5, 98-102. (in Russian)
Gonorovskiy, I. S., & Demin, M. P. (1994). Radiotekhnicheskie tsepi i signaly: Uchebnoe posobie dlya vysshikh uchebnykh zavedeniy. Moscow: Sovetskoe radio. (in Russian)
Myamlin, S. V. (2013). Transport progress as a pledge of national economy development. Science andTransport Progress, 1(43), 7-12. doi: 10.15802/stp2013/9786. (in Russian)
Dzenzerskyi, V. O., Sokolovskyi, І. І., Brovkіn, Y. M., Kravchenko, O. V., Plaksіn, S. V., & Pohorіla, L. M. (2010). UA Patent No. 92531. Kyiv: Derzhavnyi departament intelektualnoi vlasnosti. (in Ukranian)
Polskiy, B. S. (1986). Chislennoe modelirovanie poluprovodnikovykh priborov. Riga: Zinatne. (in Russian)
Dzenzerskiy, V. A., Plaksin, S. V., Pogorelaya, L. M., Toldaev, V. G., & Shkil, Yu. V. (2014). Sistemy upravleniya i energoobespecheniya magnitolevitiruyushchego transporta. Kiev: Naukova dumka. (in Russian)
Chopra, K., & Das, S. (1986). Tonkoplenochnye solnechnye elementy: Perevod s angliyskogo. Moscow: Mir. (in Russian)
Dzenzerskiy, V. A., Khachapuridze N. M., Plaksin, S. V., Toldayev, V. G., & Shkil, Y. V. (2014). ActiveMaglev guideway as electricity generating and distributing facility. Transport Research Arena (TRA) 5th Conference: Transport Solutions from Research to Deployment. Retrived from https://trid.trb.org/view/1327840. (in English)
FP6 Instruments. Implementing the Priority (2002). Thematic Areas of the Sixth Frame Program of European.Community Research. Luxembourg: Office for Official Publications of the European Communities. (in English)
Weitemeyer, S., Kleinhans, D., Vogt, T., & Agert, C. (2015). Integration of Renewable Energy Sources in future power systems: The role of storage. Renewable Energy, 75, 14-20. doi: 10.1016/j.renene.2014.09.028. (inEnglish)
Simulating Solar Cell Devices Using Silvaco TCAD. (2008). Simulation Standard, 18(2), 1-3. (in English)
Zarkov, Z., Stoyanov, L., Kanchev, H., Milenov, V., & Lazarov, V. (2016). Study of Photovoltaic Systems’ Performances with Different Module Types. Materials Science Forum, 856, 279-284. doi: 10.4028/www.scientific.net/msf.856.279. (in English)
Suberu, M. Y., Mustafa, M. W., & Bashir, N. (2014). Energy storage systems for renewable energy powersector integration and mitigation of intermittency. Renewable and Sustainable Energy Reviews, 35, 499-514. doi: 10.1016/j.rser.2014.04.009. (in English)
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2021 V. O. Dzenzerskiy, A. B. Gnilenko, S. V. Plaksin, L. M. Pogorelaya, Y. V. Shkil
This work is licensed under a Creative Commons Attribution 4.0 International License.
Copyright and Licensing
This journal provides open access to all of its content.
As such, copyright for articles published in this journal is retained by the authors, under the terms of the Creative Commons Attribution 4.0 International License (CC BY 4.0). The CC BY license permits commercial and non-commercial reuse. Such access is associated with increased readership and increased citation of an author's work. For more information on this approach, see the Public Knowledge Project, the Directory of Open Access Journals, or the Budapest Open Access Initiative.
The CC BY 4.0 license allows users to copy, distribute and adapt the work in any way, provided that they properly point to the author. Therefore, the editorial board of the journal does not prevent from placing published materials in third-party repositories. In order to protect manuscripts from misappropriation by unscrupulous authors, reference should be made to the original version of the work.
