An integrated wind-photovoltaic-battery system with reduced power-electronic interface and fast control for grid-tied and off-grid applications

Renewable Energy

Volumn 45, Issue , 2012, Pages 128-137

  Ghoddami, Hamidreza ^a   Delghavi, Mohammad B ^a   Yazdani, Amirnaser ^b  

^a UNIVERSITY OF WESTERN ONTARIO   (Canada)

^b RYERSON UNIVERSITY   (Canada)

Author keywords

Control; Photovoltaic (PV) systems; Power electronics; Pulse width modulation (PWM); Voltage mode control; Wind power

Indexed keywords

BLACK START; DUMP LOAD; ELECTRIFICATION SYSTEMS; FAST CONTROL; GRID-CONNECTED MODES; GRID-CONNECTED OPERATION; HIGHER EFFICIENCY; LOWER COST; OFF-GRIDS; PHOTOVOLTAIC; PHOTOVOLTAIC (PV) SYSTEMS; PLUG-AND-PLAY; POWER ELECTRONIC CONVERTERS; POWER MANAGEMENT STRATEGIES; POWER OUT PUT; POWER SHARING; PSCAD/EMTDC; RAPID CONTROL; SOFTWARE ENVIRONMENTS; STANDALONE SYSTEMS; TIME-DOMAIN SIMULATIONS; VOLTAGE-MODE CONTROL;

COMPUTER SOFTWARE; CONTROL; ENERGY MANAGEMENT; HYBRID SYSTEMS; INTEGRATION; VOLTAGE CONTROL; WIND POWER;

PHOTOVOLTAIC EFFECTS;

ELECTRICITY GENERATION; ELECTRICITY SUPPLY; ELECTRONIC EQUIPMENT; NUMERICAL MODEL; PHOTOVOLTAIC SYSTEM; WIND POWER;

EID: 84859566182     PISSN: 09601481     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.renene.2012.02.016     Document Type: Article

References (15)

1. Bernal-Agustin J.L., Dufo-Lopez R. Simulation and optimization of stand-alone hybrid renewable energy systems. Renewable Sustainable Energy Rev 2009, 13(8):2111-2118.
2. Borowy B.S., Salameh Z.M. Methodology for optimally sizing the combination of a battery bank and PV array in a wind/PV hybrid system. IEEE Trans Energy Convers Jun. 1996, 11(2):367-375.
3. Nehrir M.H., LaMeres B.J., Venkataramanan G., Gerez V., Alvarado L.A. An Approach to evaluate the general performance of stand-alone wind/photovoltaic generating systems. IEEE Trans Energy Convers Dec. 2000, 15(4):433-439.
4. Daniel S.A., AmmasaiGounden N. A novel hybrid isolated generating system based on PV fed inverter-assisted wind-driven induction generators. IEEE Trans Energy Convers Jun. 2004, 19(2):416-422.
5. Valenciaga F., Puleston P.F. Supervisor control for a stand-alone hybrid generation system using wind and photovoltaic energy. IEEE Trans Energy Convers Jun. 2005, 20(2):398-405.
6. Wang C., Nehrir M.H. Power management of a stand-alone wind/photovoltaic/fuel cell energy system. IEEE Trans Energy Convers Sep. 2008, 23(3):957-967.
7. Takle E.S., Shaw R.H. Complimentary nature of wind and solar energy at a continental mid-latitude station. Int J Energy Res 1979, 2(2):103-112.
8. Leonhard W. Control of electrical drives 2001, Springer, New York. 3rd ed.
9. Yazdani A., Iravani R. Voltage-sourced converters: modeling, control, and applications 2010, Wiley, Hoboken, NJ.
10. Datta R., Ranganathan V.T. Variable-speed wind-power generation using doubly-fed wound-rotor induction machine - a comparison with alternative schemes. IEEE Trans Energy Convers Sep. 2002, 17(3):414-421.
11. Yazdani A., Di Fazio A.R., Ghoddami H., Russo M., Kazerani M., Jatskevich J., et al. Modeling guidelines and a benchmark for power system simulation studies of three-phasesingle-stage photovoltaic systems. IEEE Trans Power Del Apr. 2011, 26(2):1247-1264.
12. Esram T., Chapman P.L. Comparison of photovoltaic array maximum power point tracking techniques. IEEE Trans Energy Convers Jun. 2007, 22:434-449.
13. Li Y., Vilathgamuwa D.M., Loh P.C. Design, analysis, and real-time testing of a controller for multibus microgrid system. IEEE Trans Power Electron 2004, 19(5):1195-1204.
14. PSCAD/EMTDC v. 4.2. Manitoba HVDC Research Centre. Winnipeg, MB, Canada.
15. CIGRE Task Force C6.04.02 Benchmark systems for network integration of renewable and distributed energy resources, CIGRE technical brochure 2011.