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Enhancing Grid-Connected Hybrid PV-Wind Systems: A Comprehensive Review

Madhulika Dewangan*, Tanu Rizvi**, Devanand Bhonsle***

*-*** Department of Electrical Engineering, Shri Shankaracharya Institute of Engineering and Technology, Bhilai, Chhattisgarh, India.

Periodicity:April - June'2023
DOI : https://doi.org/10.26634/jee.16.4.19443

Abstract

The ability to convert energy from one form to another is essential for both survival and the advancement of society. Wind and solar energy represent the most abundant and widely accessible renewable energy sources globally. It offers significant potential for sustainable power generation and reducing dependence on fossil fuels. Because of the tremendous advancements in power electronic systems in recent years, the output of electricity from wind and photovoltaic energy sources has expanded dramatically. The nonlinear programming (NLP) optimization method was used to determine the maximum electrical efficiency of the grid-connected SOFC subject to the constraints of fuel utilization factor, stack temperature, and output active power based on the benchmark Solid Oxide Fuel Cell (SOFC) dynamic model for power system studies and the analysis of the SOFC operating conditions. By solving the NLP issue with the power required by the air compressor, the optimal operating conditions of the grid-connected SOFC were determined. With the optimal SOFC operating conditions for maximum efficiency operation obtained at different active power output levels, a hierarchical load tracking control scheme for the grid-connected SOFC was proposed to have maximum electrical efficiency operation while keeping the stack temperature bounded.

Keywords

Grid Integration, Solid Oxide Fuel Cell (SOFC), PV Cell.

How to Cite this Article?

Dewangan, M., Rizvi, T., and Bhonsle, D. (2023). Enhancing Grid-Connected Hybrid PV-Wind Systems: A Comprehensive Review. i-manager’s Journal on Electrical Engineering , 16(4), 1-11. https://doi.org/10.26634/jee.16.4.19443

References

[1]. Ahmed, N. A., Miyatake, M., & Al-Othman, A. K. (2008). Power fluctuations suppression of stand-alone hybrid generation combining solar photovoltaic/wind turbine and fuel cell systems. Energy Conversion and Management, 49(10), 2711-2719.

[2]. Allag, T., & Das, T. (2011). Robust control of solid oxide fuel cell ultracapacitor hybrid system. IEEE Transactions on Control Systems Technology, 20(1), 1-10.

[3]. Babrekar, V. J., Bandawar, S. D., & Behade, A. R. (2017). Review paper on hybrid solar-wind power generator. International Journal of Computer Applications, 165(5), 36-40.

[4]. Badwawi, R. A., Abusara, M., & Mallick, T. (2015). A review of hybrid solar PV and wind energy system. Smart Science, 3(3), 127-138.

[5]. Borowy, B. S., & Salameh, Z. M. (1994). Optimum photovoltaic array size for a hybrid wind/PV system. IEEE Transactions on Energy Conversion, 9(3), 482-488.

[6]. Borowy, B. S., & Salameh, Z. M. (1996). Methodology for optimally sizing the combination of a battery bank and PV array in a wind/PV hybrid system. IEEE Transactions on Energy Conversion, 11(2), 367-375.

[7]. Camacho, E. F., Samad, T., Garcia-Sanz, M., & Hiskens, I. (2011). Control for renewable energy and smart grids. The Impact of Control Technology, Control Systems Society, 4(8), 69-88.

[8]. Celik, A. N. (2002). Optimisation and technoeconomic analysis of autonomous photovoltaic–Wind hybrid energy systems in comparison to single photovoltaic and wind systems. Energy Conversion and Management, 43(18), 2453-2468.

[9]. Chandra. S. & Rizvi. T. (2022). Energy Audit of Thermal Power Plant : A Literature Survey. i-manager’s Journal on Power System Engineering, 9(4), 36-41.

[10]. Chandra. S. & Rizvi. T. (2022). Detailed Energy Audit of Thermal Power Plant. International Journal for Research in Applied Science & Engineering Technology (IJRASET), 10(5), 1836-1846.

[11]. Chedid, R., & Saliba, Y. (1996). Optimization and control of autonomous renewable energy systems. International Journal of Energy Research, 20(7), 609-624.

[12]. Chedid, R., Akiki, H., & Rahman, S. (1998). A decision support technique for the design of hybrid solar-wind power systems. IEEE Transactions on Energy Conversion, 13(1), 76-83.

[13]. Das, T., & Snyder, S. (2012). Adaptive control of a solid oxide fuel cell ultra-capacitor hybrid system. IEEE Transactions on Control Systems Technology, 21(2), 372-383.

[14]. El-Shatter, T. F., Eskandar, M. N., & El-Hagry, M. T. (2001, April). Hybrid PV/fuel cell system design and simulation. In International Solar Energy Conference (Vol. 16702, pp. 267-273). American Society of Mechanical Engineers.

[15]. Ernst, B., Reyer, F., & Vanzetta, J. (2009, July). Wind power and photovoltaic prediction tools for balancing and grid operation. In 2009 CIGRE/IEEE PES Joint Symposium Integration of Wide-Scale Renewable Resources into the Power Delivery System (pp. 1-9). IEEE.

[16]. Gajbhiye, V. K., Kanaskar, A. A., & Jawre, S. S. (2017). Solar wind hybrid system–A review. Int J Res Advent Technol, 5(5), 112-116

[17]. Halamay, D. A., Brekken, T. K., Simmons, A., & McArthur, S. (2011). Reserve requirement impacts of large-scale integration of wind, solar, and ocean wave power generation. IEEE Transactions on Sustainable Energy, 2(3), 321-328.

[18]. Ingole, A. S., & Rakhonde, B. S. (2015). Hybrid power generation system using wind energy and solar energy. International Journal of Scientific and Research Publications, 5(3), 1-4.

[19]. Kamal, T., & Hassan, S. Z. (2016). Energy management and simulation of photovoltaic/hydrogen/battery hybrid power system. Adv. Sci. Technol. Eng. Syst. J, 1(2), 11-18.

[20]. Kammer, P., & Kober, A. (2006). Grid integration of renewable energy sources. BTU Cottbus, Germany, (pp.4).

[21]. Khadem, S. K., Basu, M., & Conlon, M. (March, 2010). Power quality in grid connected renewable energy systems: Role of custom power devices. In 2010 International Conference on Renewable Energy and Power Quality (ICREPQ) pp.6.

[22]. Kumar, S., & Garg, V. K. (2013). A hybrid model of solar-wind power generation system. International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering (IJAREEIE), 2(8), 4107-4016

[23]. Linh, N. T. (2009, May). Power quality investigation of grid connected wind turbines. In 2009 4th IEEE Conference on Industrial Electronics and Applications (pp. 2218- 2222). IEEE.

[24]. Liu, Y. J., & Jiang, C. W. (2013). A review on technologies and methods of mitigating impacts of large-scale intermittent renewable generations on power system. Research Journal of Applied Sciences, Engineering and Technology, 5(9), 2765-2770.

[25]. Mauryan, C. KS, Nivethitha. T, Yazhini. B, Preethi. B, (2014). Study on Integration of Wind and Solar Energy to Power Grid. Journal of Engineering Research and Application, 4(5).

[26]. Medugu, D. W., & Michael, E. (2014). Integrated solar–Wind hybrid power generating system for residential application. Global Journal of Researches in Engineering, 14(4), 47-53.

[27]. Mezzai, N., Rekioua, D., Rekioua, T., Mohammedi, A., Idjdarane, K., & Bacha, S. (2014). Modeling of hybrid photovoltaic/wind/fuel cells power system. International Journal of Hydrogen Energy, 39(27), 15158-15168.

[28]. Mousa, K., AlZu'bi, H., & Diabat, A. (2010, March). Design of a hybrid solar-wind power plant using optimization. In 2010 Second International Conference on Engineering System Management and Applications (pp. 1-6). IEEE.

[29]. Nelson, D. B., Nehrir, M. H., & Wang, C. (2006). Unit sizing and cost analysis of stand-alone hybrid wind/PV/fuel cell power generation systems. Renewable Energy, 31(10), 1641-1656.

[30]. Nirmal, S., & Rizvi, T. (2022). A Review of Renewable Energy Systems for Industrial Applications. International Journal for Research in Applied Science & Engineering Technology (IJRASET), 10(9), 1740-1745.

[31]. Reddy, M. K., Kumar, D. G., & Rao, J. V. (2014). Design and modeling of grid connected hybrid renewable energy power generation. Journal of Engineering Research and Applications, 4(9), pp.158-164.

[32]. Rehman, S., & Al-Hadhrami, L. M. (2010). Study of a solar PV–diesel–battery hybrid power system for a remotely located population near Rafha, Saudi Arabia. Energy, 35(12), 4986-4995.

[33]. Resende, F. O., & Lopes, J. P. (2011, April). Management and control systems for large scale integration of renewable energy sources into the electrical networks. In 2011 IEEE EUROCON-International Conference on Computer as a Tool (pp. 1-6). IEEE.

[34]. Rizvi, T., Dubey, S. P., & Tripathi, N. (2021). Designing of a Feasible Low Pollutant Grid Integrated System for Steel Plant. CSVTU Research Journal, 10(02), 144-154.

[35]. Rizvi, T., Dubey, S. P., & Tripathi, N. (2022). Reconceptualizing the Application of Renewable Energy Sources in Industry: A Review. Int. Res. J. Eng. Technol, 9, 514-518.

[36]. Rizvi, T., Dubey, S. P., Tripathi, N., Srivastava, G., Makhija, S. P., & Mohiddin, M. K. (2023). FSPV-Grid System for an Industrial Subsection with PV Price Sensitivity Analysis. Sustainability, 15(3), 2495.

[37]. Rizvi, T., Tripathi, N., & Dubey, S. P. (2020). Feasibility Analysis of a Grid Integrated Renewable Energy Systems in Heavy Industries. Journal of Adv Research in Dynamical & Control Systems (JARDCS), 12(06), 2289-2302.

[38]. Thounthong, P., & Sethakul, P. (2007, April). Analysis of a fuel starvation phenomenon of a PEM fuel cell. In 2007 Power Conversion Conference-Nagoya (pp. 731-738). IEEE.

Enhancing Grid-Connected Hybrid PV-Wind Systems: A Comprehensive Review

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