Document Type
Conference Item
Publication Date
1-1-2011
Abstract
This paper proposes a hybrid system which consists of a photovoltaic panel, wind turbine, proton exchange membrane fuel cell (PEMFC), electrolyzer, super capacitor, power convertor and a three-phase variation load. The load supplied is based on the photovoltaic panel and wind turbine, while the fuel cells are back-up for compensating possible power load shortage. The surplus of power produced will be stored in a hydrogen tank by an electrolyzer system when the PV panel and wind turbine produce more power than required. The capacitor banks are used in parallel with other sources in order to reduce DC bus variation. Matlab software is chosen for the hybrid system simulation.
Keywords
Electrolyzer, Fuel cell, Photovoltaic panel, Super capacitor, Wind turbine, Capacitor bank, Electrolyzers, Hydrogen tank, Matlab- software, Off-grids, Photovoltaic panels, Power load, PV panel, System simulations, Capacitors, Computer software, Control systems, DC power transmission, Electric load forecasting, Electrolytic cells, Fuel cells, Hybrid systems, Hydrogen, MATLAB, Photovoltaic cells, Proton exchange membrane fuel cells (PEMFC), Wind turbines, Photovoltaic effects.
Divisions
fac_eng
Event Title
2011 IEEE International Conference on Control System, Computing and Engineering, ICCSCE 2011
Event Location
Penang
Event Type
conference
Additional Information
Conference code: 89794 Export Date: 16 November 2012 Source: Scopus Art. No.: 6190560 doi: 10.1109/ICCSCE.2011.6190560 Language of Original Document: English Correspondence Address: Palizban, O.; Dep. of Electrical Engineering, University of Malaya, Kuala Lumpur, Malaysia; email: omid.palizban@siswa.um.edu.my References: Wang, C., Nehrir, M.H., Power management of a stand-alone wind/photovoltaic/fuel cell energy system (2008) Energy Conversion, IEEE Transactions on, 23, pp. 957-967; Benmessaoud, M., New approach modeling and a maximum power point tracker method for solar cells (2010) Computers & Mathematics with Applications, 60, pp. 1124-1134; Pandiarajan, N., Muthu, R., (2011) Mathematical Modeling of Photovoltaic Module with Simulink, pp. 258-263; Spiegel, C., (2008) PEM Fuel Cell Modeling and Simulation Using Matlab, , Academic Press; Xiao, Y., Agbossou, K., (2009) Interface Design and Software Development for PEM Fuel Cell Modeling Based on Matlab/Simulink Environment; Adzakpa, K., PEM fuel cells modeling and analysis through current and voltage transient behaviors (2008) Energy Conversion, IEEE Transactions on, 23, pp. 581-591; Ko, H.S., (2006) Supervisory Voltage Control Scheme for Grid-connected Wind Farms, , University of British Columbia; Uzunoglu, M., Modeling, control and simulation of a PV/FC/UC based hybrid power generation system for stand-alone applications (2009) Renewable Energy, 34, pp. 509-520