ANALYSIS AND SIZING OF HYBRID ENERGY STORAGE SYSTEM (HESS) TOPOLOGIES FOR SOLAR PHOTOVOLTAIC APPLICATIONS

Kashif Javed, Haroon Ashfaq, and Rajveer Singh

References

  1. [1] A. Mamun, Z. Liu, D.M. Rizzo, and S. Onori, An integrated design and control optimization framework for hybrid military vehicle using lithium-ion battery and supercapacitor as energy storage devices, IEEE Transactions on Transportation Electrification, 5(1), 2019, 519–527.
  2. [2] K. Kapoor, K.K. Pandey, A.K. Jain, and A. Nandan, Evolution of solar energy in India: a review, Renewable and Sustainable Energy Reviews, 40, 2014, 475–487.
  3. [3] Y. Parvini, A. Vahidi, and S.A. Fayazi, Heuristic versus optimal charging of supercapacitors, lithium-ion, and lead-acid batteries: An efficiency point of view, IEEE Transactions on Control Systems Technology, 26(1), 2018, 167–180.
  4. [4] S.C. Bhattacharya and C. Jana, Renewable energy in India: Historical developments and prospects, Energy, 34(8), 2009, 981–989.
  5. [5] R.B. Hiremath, B. Kumar, P. Balachandra, N.H. Ravindranath, and B.N. Raghunandan, Decentralised renewable energy: scope, relevance and applications in the Indian context, Energy for Sustainable Development, 13(1), 2009, 4–10.
  6. [6] S.K. Kollimalla, N.K. Mishra, and N.L. Narasamma, Design and analysis of novel control strategy for battery and super-capacitor storage system, IEEE Transaction on Sustainable Energy, 5, 2014, 1137–1144. 119
  7. [7] F. Ongaro, S. Saggini, and P. Mattavelli, Li-ion battery-supercapacitor hybrid storage system for a long lifetime, photovoltaic-based wireless sensor network, IEEE Transaction on Power Electronics, 27, 2012, 3944–3952.
  8. [8] H. Kanchev, D. Lu, F. Colas, V. Lazarov, and B. Francois, Energy management and operational planning of a microgrid with a PV-based active generator for smart grid applications, IEEE Transaction on Industrial Electronics, 58, 2011, 4583– 4592.
  9. [9] K. Javed, H. Ashfaq, and R. Singh, Optimized load profile & cost analysis of standalone photovoltaic system for rural power applications in Indian scenario, Smart Science, 6, 2018, 245–255.
  10. [10] R.T. Bambang, A.S. Rohman, C.J. Dronkers, R. Ortega, and A. Sasongko, Energy management of fuel cell/battery/ supercapacitor hybrid power sources using model predictive control, IEEE Transaction on Industrial Informatics, 10, 2014, 1992–2002.
  11. [11] D.P. Jenkins, J. Fletcher, and D. Kane, Lifetime prediction and sizing of lead acid batteries for micro generation storage applications, IET Renewable Power Generation, 3(19), 2008, 191–200.
  12. [12] C.M. Krishna, Managing battery and supercapacitor resources for real-time sporadic workloads, IEEE Embed Systems Letters, 3(6), 2011, 2–6.
  13. [13] S.D.G. Jayasinghe, D.M. Vilathgamuwa, and U.K. Madawala, Diode clamped three-level inverter-based battery/ supercapacitor direct integration scheme for renewable energy systems, IEEE Transaction on Power Electronics, 26, 2011, 3720–3729.
  14. [14] Z. Cabrane, M. Ouassaid, and M. Maarouf, Integration of supercapacitor in photovoltaic energy storage: modelling and control, IEEE Con., Morocco, 2014, 185–190.
  15. [15] Z. Cabrane, M. Ouassaid, and M. Maarouf, Management and control of storage photovoltaic energy using battery-supercapacitor combination, IEEE Second World Conf. on Complex Systems (WCCS), Morocco, 2014, 380–385.
  16. [16] W. Li, G. Joos, and J. Belanger, Real-time simulation of a wind turbine generator coupled with a battery supercapacitor energy storage system, IEEE Transactions on Industrial Electronics, 57, 2010, 1137–1145.
  17. [17] K. Javed, H. Ashfaq, and R. Singh, An improved MPPT algorithm to minimize transient and steady-state oscillation conditions for small SPV systems, International Journal of Renewable Energy Development, 7(3), 2018, 191–197.
  18. [18] A. Mansour, B. Faouzi, G. Jamel, and E. Ismahen, Design and analysis of a high-frequency DC–DC converter for fuel cell and super-capacitor used in the electrical vehicle, International Journal of Hydrogen Energy, 39, 2014, 1580–1592.
  19. [19] A. Lahyani, P. Venet, A. Guermazi, and A. Troudi, Battery/ supercapacitors combination in uninterruptible power supply (UPS), IEEE Transactions on Power Electronics, 28, 2013, 1509–1522.
  20. [20] Y. Wang, X. Lin, Y. Kim, N. Chang, and M. Pedram, Architecture and control algorithms for combating partial shading in photovoltaic systems, IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems, 33, 2014, 917e30.
  21. [21] F.C. Dezza, V. Musolino, L. Piegari, and R. Rizzo, Hybrid battery–supercapacitor system for full electric forklifts, IET Electrical Systems in Transportation, 9, 2018, 16–23.
  22. [22] J. Shen and A. Khaligh, A supervisory energy management control strategy in a battery/ultracapacitor hybrid energy storage system, IEEE Trans Transactions on Power Electrification, 1, 2015, 223–231.
  23. [23] D. Zhao, H. Yin, Z. Yang, and C. Ma, Equivalent series resistance based energy loss analysis of a battery semi-active hybrid energy storage system, IEEE Transactions on Energy Conversion, 30, 2015, 1081e91.
  24. [24] P. Garcıa, J.P. Torreglosa, L.M. Fernandez, and F. Jurado, Viability study of a FC-battery-SC tramway controlled by equivalent consumption minimization strategy, International Journal of Hydrogen Energy, 37, 2012, 9368e82.
  25. [25] M.Z. Daud, M. Azah, and M.A. Hannan, An optimal state of charge feedback control strategy for battery energy storage in the hourly dispatch of PV sources, Procedia Technology, 11, 2013, 24e31.
  26. [26] F. Belhachemi, S. Rael, and B. Davat, A physical-based model of power electric double-layer supercapacitors, IEEE Industrial Application Conference, 5, 2000, 3069–3076.
  27. [27] L. Bangyin, D. Shanxu, and C. Tao, Photovoltaic DC-building-module based BIPV system-concept and design considerations, IEEE Transaction on Power Electron., 26(5), 2011, 1418–1429.
  28. [28] A. Luque and S. Hegedus, Handbook of photovoltaic science and engineering (Chichester: Wiley, 2003), ISBN: 0471491969.
  29. [29] K. Ishaque, Z. Salam, and H. Taheri, Accurate MATLAB/ Simulink PV system simulator based on a two-diode model, Journal of Power Electronics, 11, 2011, 179–187.
  30. [30] K. Ishaque, Z. Salam, H. Taheri, and Syafaruddin, Modeling and simulation of photovoltaic (PV) system during partial shading based on a two-diode model, Simulation Modeling Practical Theory, 19, 2011, 1613–1626.

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