Trends in Electrical Engineering (TEE)

Presently the world has relied upon petroleum products for energy supply. The overall utilization of non-renewable energy sources (coal, gas and oil) is as yet expanding regardless of the developing worldwide familiarity with the natural effect of non-renewable energy source utilization and of restricted petroleum derivative stores. By and by increment in the cost of oil has been a most significant wellspring of prudent issue on the planet. The creation of oil level on the planet will disseminate in under 50 years. So we have solid inspiration on our advances to create and collect the bottomless sun based energy into clean sustainable power source for a definitive substitution of non-renewable energy sources. The essential deterrent in the development of photovoltaic is the high absolute expense of photovoltaic establishments. Interestingly, coal is modest and bounteous in key expending nations, for example, India and China, making coal the world is quickly developing fuel. Thus, the principle point of this exploration is making photovoltaic cells increasingly effective for changing over sun powered energy into power and by lessening creation costs. This development has been bolstered by the expanded effectiveness and related cost intensity of photovoltaic cells just as empowering sustainable power source approaches. To keep up the high development pace of the photovoltaic business, it is basic to keep improving transformation effectiveness while diminishing the creation cost of photovoltaic cells. This paper at first presents the essential outline of the matrix associated framework,sunlight based breeze half and half framework at that point clarifies the investigation of framework structure, and reproduction ideas of the cross breed lattice associated frameworks. Results clarify the structure and recreation of a framework associated sun based PV wind half breed framework for understanding the difficulties in lattice interfacing of mixture wind PV framework. It is likewise useful in showing the displaying of crossover energy framework utilizing building squares and estimation of the figure of benefits for introduced framework.

Keywords: Grid Connected, MPPT, Power, Solar PV, SPV System Wind Energy.

Dr Allabaksh Naikodi, “Solar-Wind Hybrid Power for Rural Indian Cell Sites”, 978-1-4244-9380-7/10, 2010, IEEE.

Prashant Baredar, V. K. Sethi, Mukesh Pandey, “Correlation analysis of small wind–solar–biomass hybrid energy system”, installed atRGTU Bhopal, MP (India), Received: 16 September 2008 / Accepted: 18 February 2009 / Published online: 25 March 2009.

Wang Jinggang, Gao Xiaoxia, “The Economic Analysis of Wind Solar Hybrid Power Generation System in Villa”, International Conferenceon Energy and Environment Technology, 2009.

S.C.Gupta, Dr.Y.Kumar and Dr.Gayatri Agnihotri, “Optimal Sizing Of Solar-Wind Hybrid System”, lET-UK International Conference on Information and Communication Technology in Electrical Sciences (ICTES 2007), Dec. 20-22, 2007, 282-287.

Lingfeng Wang, Chanan Singh, “PSO-Based Multidisciplinary Design of a Hybrid Power Generation System with Statistical Models of Wind Speed and Solar Insolation”, IEEE, 0-7803-9772-X/06/2006.

M.A. Elhadidy and S.M. Shaahid, “Parametric Study of Hybrid (Wind + Solar + Diesel) Power Generating Systems”, Renewable Energy, 21 (2000), 129–139.

M.A. Elhadidy and S.M. Shaahid, “Promoting Applications of Hybrid (Wind + Photovoltaic + Diesel + Battery) Power Systems in Hot Regions”, Renewable Energy, 29(2004), 17–28.

M.A. Elhadidy, “Performance Evaluation of Hybrid (Wind/Solar/Diesel) Power Systems”, Renewable Energy, 26(2002), 401–413.

A.R. Prasad and E. Natarajan, “Optimization of Integrated Photovoltaic–Wind Power Generation Systems with Battery Storage”, Energy, 31(2006), 1943–1954.

D.B. Nelson, M.H. Nehrir, and C. Wang, “Unit Sizing and Cost Analysis of Stand-Alone Hybrid Wind/PV/Fuel Cell Power Generation Systems”, Renewable Energy, 31(2006), 1641–1656.

P. Lei, Y. Li, and J. E. Seem, “Sequential ESC-based global MPPT control for photovoltaic array with variable shading” ,IEEE Transactions on Sustainable Energy, vol. 2, no. 3, pp. 348–358, 2011.

B. N. Alajmi, K. H. Ahmed, S. J. Finney, B. W. Williams, and B. Wayne Williams, “A Maximum Power Point Tracking Technique for Partially Shaded Photovoltaic Systems in Micro grids” ,IEEE Transactions on Industrial Electronics, vol. 60, no. 4, pp. 1596–1606, 2011.

K. Chen, S. Tian, Y. Cheng, and L. Bai, “An Improved MPPT Controller for Photovoltaic System Under Partial Shading Condition,” Sustain. Energy, IEEE Trans., vol. 5, no. 3, pp. 978–985, 2014.

J. Ahmed, S. Member, and Z. Salam, “An Improved Method to Predict the Position of Maximum Power Point During Partial Shading for PV Arrays,” IEEE Trans. Ind. Informatics, vol. 11, no. 6, pp.

–1387, 2015.

Hariharan, M. Chakkarapani, G. S. Ilango, C. Nagamani, and S. Member, “A Method to Detect Photovoltaic Array Faults and Partial Shading in PV Systems,” IEEE J. Photovoltaics, pp. 1–8, 2016.

Uzunoglu, M., and M. S. Alam. "Dynamic modeling, design, and simulation of a combined PEM fuel cell and ultracapacitor system for stand-alone residential applications." IEEE Transactions on Energy Conversion 21.3 (2006): 767-775.

Onar, O. C., M. Uzunoglu, and M. S. Alam. "Modeling, control and simulation of an autonomous wind turbine/photovoltaic/fuel cell/ultra-capacitor hybrid power system." Journal of Power Sources 185.2 (2008): 1273-1283.

Hidaka, Yasuhito, and Koji Kawahara. "Modeling of a hybrid system of photovoltaic and fuel cell for operational strategy in residential use." Universities Power Engineering Conference (UPEC), 2012 47th International. IEEE, 2012.

Gaonkar, D. N., and Sanjeev Nayak. "Modeling and performance analysis of microturbine based Distributed Generation system,“a review”." Energytech, 2011 IEEE. IEEE, 2011.

Khan, M. J., and M. T. Iqbal. "Pre-feasibility study of stand-alone hybrid energy systems for applications in Newfoundland." Renewable energy 30.6 (2005): 835-854.