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Supercapacitors as storage of modern energy systems

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Warianty tytułu
PL
Superkondensatory jako magazyn energii w nowoczesnych systemach energetycznych
Języki publikacji
EN
Abstrakty
EN
The paper presents supercapacitors as energy storing devices for renewable energy and transportation systems. Basic principles of operation are presented, as well as operation layouts and equivalent circuits of various accuracy. Example charging and discharging curves of the investigated supercapacitors are given along with the main capacitor parameters derived from them.
PL
Artykuł przedstawia superkondensatory jako urządzenia magazynujące energię w systemach energetycz-nych, wykorzystujących energie odnawialne, oraz w systemach transportowych. Przedstawiono zasadę działania, jak również układy pracy oraz schematy zastępcze o różnym stopniu dokładności. Zamieszczono krzywe ładowania i rozładowania badanego kondensatora oraz na ich podstawie obliczono jego parametry elektryczne.
Czasopismo
Rocznik
Tom
Opis fizyczny
Bibliogr. 21 poz., rys., pełen tekst na CD
Twórcy
autor
  • University of Life Sciences in Lublin, Department of Technology Fundamentals
  • University of Life Sciences in Lublin, Department of Technology Fundamentals
autor
  • University of Life Sciences in Lublin, Department of Technology Fundamentals
autor
  • University of Life Sciences in Lublin, Department of Technology Fundamentals
Bibliografia
  • [1] Cao, J., and Emadi, A. (2012). A New Battery/UltraCapacitor Hybrid Energy Storage System for Electric, Hybrid, and Plug-In Hybrid Electric Vehicles. IEEE Transactions on Power Electronics 27, pp. 122–132.
  • [2] Castillo, A., and Gayme, D.F. (2014). Grid-scale energy storage applications in renewable energy integration: A survey. Energy Conversion and Management 87, pp. 885–894.
  • [3] Danila E., Lucache D. D., Livint G. (2011). Models and modelling the supercapacitors for a defined application, Annals of the University of Craiova, Electrical Engineering series, No. 35.
  • [4] Ding, S., Cheng, M., Hu, C., Zhao, G., and Wang, W. (2013). An energy recovery system of regener-ative braking based permanent magnet synchronous motor for electric vehicles. In 2013 International Conference on Electrical Machines and Systems (ICEMS), pp. 280–284.
  • [5] Frackowiak, E., Abbas, Q., and Béguin, F. (2013). Carbon/carbon supercapacitors. Journal of Energy Chemistry 22, pp. 226–240.
  • [6] Guillemet P., Scudeller Y., Brousse T. (2006) Multi-level reduced-order thermal modeling of electro-chemical capacitors, Journal of Power Sources 157, pp. 630-640.
  • [7] Lee, Y.-S., and Cheng, M.-W. (2005). Intelligent control battery equalization for series connected lithium-ion battery strings. IEEE Transactions on Industrial Electronics 52, pp. 1297–1307.
  • [8] Hajizadeh, A., and Golkar, M.A. (2010). Control of hybrid fuel cell/energy storage distributed gener-ation system against voltage sag. International Journal of Electrical Power & Energy Systems 32, pp. 488–497.
  • [9] Lisowska – Oleksiak A., Nowak A.,Wilamowska M. (2010). Superkondensatory jako materialy do magazynowaia energii, Acta Energetica nr 1, pp. 71-79.
  • [10] Maxwell Technologies. (2009). Product guide, Maxwell Technologies Boostcap Ultracapacitors, Doc. No. 1014627.1.
  • [11] Maxwell Technologies: Datasheet, 16 V small cell module, (2014). Doc. No. 1015371.6
  • [12] Rafik, F., Gualous, H., Gallay, R., Crausaz, A., and Berthon, A. (2007). Frequency, thermal and voltage supercapacitor characterization and modeling. Journal of Power Sources 165, pp. 928–934.
  • [13] Sharma, P., and Bhatti, T.S. (2010). A review on electrochemical double-layer capacitors. Energy Conversion and Management 51, pp. 2901–2912.
  • [14] Shen, X., Chen, S., Li, G., Zhang, Y., Jiang, X., and Lie, T.T. (2013). Configure Methodology of Onboard Supercapacitor Array for Recycling Regenerative Braking Energy of URT Vehicles. IEEE Transactions on Industry Applications 49, pp. 1678–1686.
  • [15] Teymourfar, R., Asaei, B., Iman-Eini, H., and Nejati fard, R. (2012). Stationary super-capacitor energy storage system to save regenerative braking energy in a metro line. Energy Conversion and Management 56, pp. 206–214.
  • [16] Thounthong, P., Piegari, L., Pierfederici, S., and Davat, B. (2015). Nonlinear intelligent DC grid stabilization for fuel cell vehicle applications with a supercapacitor storage device. International Jour-nal of Electrical Power & Energy Systems 64, pp. 723–733.
  • [17] UltraBattery. (2014). Available online: http://www.ultrabattery.com. Accessed on September 30th 2014.
  • [18] Uno, M. (2009). Interactive charging performance of a series connected battery with shunting equal-izers. In Telecommunications Energy Conference, 2009. IN℡EC 2009. 31st International, pp. 1–4.
  • [19] Uno, M., and Tanaka, K. (2011). Influence of High-Frequency Charge #x2013;Discharge Cycling Induced by Cell Voltage Equalizers on the Life Performance of Lithium-Ion Cells. IEEE Transactions on Vehicular Technology 60, pp. 1505–1515.
  • [20] Uno, M. (2013). Single- and Double-Switch Cell Voltage Equalizers for Series-Connected Lithium-Ion Cells and Supercapacitors. In Energy Storage - Technologies and Applications, A. Zobaa, ed. (InTech).
  • [21] Zubieta, L., and Bonert, R. (2000). Characterization of double-layer capacitors for power electronics applications. IEEE Transactions on Industry Applications 36, pp. 199–205.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-3f7d341c-bc8f-4d8a-9546-7a0dac462558
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