On possibilities of utilisation of energy storage in electric traction systems

• Autorzy: Pawełczyk M.
• Języki publikacji: EN

Abstrakty

EN

Some possibilities of the energy storage applications in the passenger rail transportation systems have been presented in the paper. An overview of the most suitable energy storage devices has been shown and common areas of the energy storage utilisations have been discussed.

Słowa kluczowe

EN

energy; storage; rail; transportation

• Wydawca: Instytut Naukowo-Wydawniczy "TTS" Sp. z o.o
• Czasopismo: TTS Technika Transportu Szynowego
• Rocznik: 2015
• Tom: R. 22, nr 10
• Strony: 110--115, CD
• Opis fizyczny: Bibliogr. 21 poz., rys.

Twórcy

autor

Pawełczyk M.

• Technical University of Kielce, Poland

Bibliografia

• [1] T. Albrech Reducing power peaks and energy consumption in rail transit systems by simultaneous train running time control. Adv Transport 2004;15:885–94.
• [2] Al Fin Energy http://alfin2300.blogspot.com/ 2011_05_01_archive.htm Retrieved June 16, 2015.
• [3] F. Ampofo, G.G. Maidment, J.F. Missenden, Application of groundwater cooling scheme for London Underground network. Int. J. Refrig. 2011;34:2042–9.
• [4] D. Bhatnagar, V. Loose Evaluating Utility Procured Electric Energy Storage Resources: A Perspective for State Electric Utility Regulators. A Study for the DOE Energy Storage Systems Program. SANDIA REPORT SAND2012-9422. November 2012.
• [5] J.R. Boizumeau, P. Leguay, E. Navarro Braking energy recovery at the Rennes metro. In: Workshop on Braking Energy Recovery Systems–Ticket to Kyoto Project. Bielefeld, Germany; 2011.
• [6] M. Brenna, F, Foiadelli, E. Tironi, D. Zaninelli. Ultracapacitors application for energy saving in subway transportation systems. In: International Conference on Clean Electrical Power – ICCEP 2007. Capri, Italy; 2007.
• [7] J.F. Chen, R.L. Lin, Y.C. Liu Optimization of an MRT train schedule – reducing maximum traction power by using genetic algorithms. IEEE Trans. Power Syst. 2005;20:1366–72.
• [8] B. E. Conway Electrochemical Supercapacitors. Scientific Fundamentals and Technological Applications. Springer 1999.
• [9] Put stacks through their paces. http://forschungenergiespeicher.info/en/project-showcase/industrialprocesses/project-single-view// Stacks_auf_Herz_und_Nieren_testen Retrieved June 16, 2015.
• [10] Fuel Cell Handbook (Seventh Edition) By EG&G Technical Services, Inc. Under Contract No. DEAM26-99FT40575 U.S. Department of Energy. Office of Fossil Energy. National Energy Technology Laboratory. November 2004.
• [11] A. Gonzalez-Gil, R. Palacin, P. Batty Sustainable urban rail systems: Strategies and technologies for optimal management of regenerative braking energy. Energy Conversion and Management 75 (2013) 374–388.
• [12] DOE/EPRI 2013 Electricity Storage Handbook. SANDIA REPORT in Collaboration with NRECA SAND 2013-5131. July 2013.
• [13] E. Ingebretsen, T.H. Glimsdal Johansen The Potential of Pumped Hydro Storage in Norway (abstract). http:// www.nhh.no/en/research-faculty/department-ofbusiness-and-management-science/seminars--conferences/conferences/beeer-conference/beeerconference-2013-abstracts.aspx Retrieved June 16, 2015.
• [14] M. Jayalakshmi, K. Balasubramanian Simple Capacitors to Supercapacitors - An Overview. Int. J. Electrochem. Sci., 3 (2008) 1196 – 1217.
• [15] G. Malavasi, P. Palleschi, S. Ricci Driving and operation strategies for traction energy saving in mass rapid transit systems. PI Mech. Eng. F-J Rai 2011; 225:475–82.
• [16] A. Nasri, M. Fekri Moghadam, H. Mokhtari Timetable optimization for maximum usage of regenerative energy of braking in electrical railway systems. In: SPEEDAM 2010 – International Symposium on Power Electronics, Electrical Drives, Automation and Motion. Pisa, Italy; 2010.
• [17] M. Pawełczyk Electrical traction effectiveness improvement by use of the energy storage devices (in Russian). Moscow, 2000.
• [18] M. Pena-Alcaraz, A. Fernandez, A.P. Cucala, A. Ramos, R.R, Pecharroman Optimal underground timetable design based on power flow for maximizing the use of regenerative-braking energy. PI Mech. Eng. F-J Rai 2011;226:397–408.
• [19] R. Sebastiá, R. Peña Alzol Flywheel energy storage systems: Review and simulation for an isolated wind power system Renewable and Sustainable Energy Reviews 2012 9(16): 6803–6813.
• [20] J.A. Thompson, G.G. Maidment, J.F. Missenden, Modelling low-energy cooling strategies for underground railways. Appl. Energy 2006;83:1152–62.
• [21] V.R. Vuchic Urban transit systems and technology Hoboken: John Wiley & Sons; 2007