Open Access Open Access  Restricted Access Subscription or Fee Access

Modeling of hybrid solar wind and thermal power plant for improving power system reliability

Saroja Kumar Dash, Sandeep Kumar Chaurasia

Abstract


Despite the fact that solar and wind power are two of its most promising alternatives, study on alternative energy sources has been restricted. Integration research has been reported to taking use of complementary qualities of the two. The number of solar modules, the height of the wind turbines, the number of wind turbines, and the diameter of the turbine rotor are the elements that will be improved in this study with the goal of eliminating expenses. According to simulations and sensitivity analysis, the proposed plant may profit from the complementary nature of the two electricity sources to ensure year-round energy

Keywords


Solar wind, thermal power, alternative energy

Full Text:

PDF

References


Dihrab, S.S. And Sopian, K. “Electricity generation of hybrid PV/wind systems in Iraq”,Renewable Energy, Vol 35, pp. 1303-1307, 2010.

Yang, H., Zhou, W., and Lou, C. “Optimal Design and Techno-economic Analysis of a Hybrid Solar-Wind PowerGeneration System”, Applied Energy, Vol. 86, pp. 163-169,2009.

Kanase-Patil, A.B., Saini, R.P., and Sharma, M.P. “Integrated Renewable Energy Systems for Off Grid RuralElectrification”, Renewable Energy, Vol. 35, pp. 1342-1349,2010.

Ekren, O., Ekren, B.Y., and Ozerdem, B. “Break-evenAnalysis and Size Optimization of A PV/Wind Hybrid Energy Conversion System "A Case Study of Battery Storage," Applied Energy, Vol. 86, No.7-8, pp. 1043-54, 2009.

Ahmed, N.A., Miyatake, M., and Al-Othman, A.K., “Power Fluctuations Suppression of Stand-Alone Hybrid Generation Combining Solar Photovoltaic/Wind Turbine and Fuel Cell Systems”, Energy Conversion and Management,Vol.49, pp. 2711-2719, 2008.

Onar, O.C., Uzunoglu, M., and Alam, M.S. “Modeling, Control and Simulation of an Autonomous Wind Turbine/Photovoltaic/FuelJournal of Power Sources, Vol. 185, Cell/Ultra-Capacitor Hybrid Power System185, No. 2, pp. 1273-83, 2008.

Yang, H., Zhou, W., Lu, L., and Fang, Z. “Optimal Sizing Method for Stand-Alone Hybrid Solar-Wind System with LPSP Technology By Using Genetic Algorithm”, SolarEnergy, Vol.82, pp. 354, 2008.

Mahmoudi, H., Abdul-Wahab, S.A., Goosen, M.F.A., Sablan, S.S., Perret, J., Ouagued, A., and Spahis, N. “Weather Data and Analysis Of Coastal Hybrid Photovoltaic Wind Power Generation Systems Adapted to Seawater Greenhouse Desalination Units in Arid ClimateCountries”, Desalination, Vol. 22, No. 1-3, pp. 119-127, 2008.

Elhadidy, M.A., and Shaahid, S.M. “Promoting applications of hybrid (wind + photovoltaic + diesel +battery) power systems in hot regions”, Renewable Energy,Vol. 29, No. 4, pp. 517-528, 2004.

Shakya, B.D., Aye, L., and Musgrave, P. “Technical Feasibility and Financial Analysis of Hybrid Wind-Photovoltaic System With Cooma's Hydrogen Storage", International Journal of Hydrogen Energy, Vol.30, pp.9-20, 2005.

Tina, G., Gagliano, S., and Raiti, S. “Hybrid solar/wind power system probabilistic modeling for long-term performance assessment”, Solar Energy, Vol. 80, pp. 578-588, 2006.

Kershman, S.A., Rheinlander, J., Neumann, T., and Goebel, O. “Hybrid Wind/PV and Conventional Power for Desalinationin Libya–Ras Ejder's GECOL Facility for Medium and Small-Scale Research", Desalination, Vol.183, No.1-3, pp. 1-12, 2005.

Celik, A.N. “Techno-Economic Analysis of Autonomous PV-Wind Hybrid EnergySystems Using Different Sizing Methods”, EnergyConversion and Management, Vol. 44, pp. 1951-1968, 2003.

Bakos, G.C., and Tsagas, N.F. “Techn*oeconomicAssessment Of A Hybrid Solar/Wind Installation forElectrical Energy Saving”, Energy and Buildings, Vol. 35, No. 2, pp. 139-45, 2003.

Deshmukh, M.K., Deshmukh, S.S. “Modeling Of hybrid Renewable Energy Systems”, Renewable and SustainableEnergy Reviews, Vol. 12, No. 1, pp. 235-249, 2008.

Borowy, B.S., and Salameh Z.M. “Methodology forOptimally Sizing the Combination of a Battery Bank and PV Array in A Wind/PVHybrid System”, IEEE Trans.Energy Convert., Vol. 11, No. 2, pp. 367-73, 1996.

Yang, H.X., Jurnett, B., and Lu, L. “Weather data and probability analysis of hybrid photovoltaic-wind power generation systems in Hong Kong”, Renewable Energy, Vol. 28, No. 11, pp. 1813-24, 2003.

Yang, H.X., Lu, L., and Zhou, W. “A Novel Optimization Sizing Model for Hybrid Solar-Wind Power Generation System, Solar Energy, Vol. 81, No. 1, pp. 76-84, 2007.

P. Kundur, “Power System Stability and Control,” New York, USA:McGraw-Hill, 1994.

D. J. Lee, and L. Wang, “Small-Signal Stability Analysis of anAutonomous Hybrid Renewable Energy Power Generation/EnergyStorage SystemPart I: Time-Domain Simulations”,IEEE Transactions on Energy Conversion, Vol. 23, No. 1, pp. 311-320, March 2008.

P. K. Ray, S. R. Mohanty, and N. Kishor, “Small-Signal Analysis of Autonomous Hybrid Distributed Generation Systems”, Journal of Electrical Engineering, Vol.61, No.4, pp.205-214, 2010.

T. Senjyu, T. Nakaji, K. Uezato, and T. Funabashi, “A Hybrid Power System Using Alternative Energy Facilities in Isolated Island,” IEEETransactions on Energy Conversion, Vol. 20, No. 2, pp. 406-414, June 2005.

M. A. Sofla, and R. King,“Control Method for Multi-Micro-gridSystems in Smart Grid Environment—Stability, Optimization and Smart Demand Participation”, IEEE PES,Innovative Smart GridTechnologies(ISGT), pp.1-5, 16-20 January, 2012.

M. Matsubara, G. Fujita, T. Shinji, T. Sekine, A. Akisawa, T. Kashiwagi, andR.Yokoyama, “Supply and Demand Control of Dispersed Type Power Sources in Micro Grid", 13th International Conference on Intelligent Systems Application to Power Systems, pp.67 – 72, 2005.

X. Li, Y. Li, X. Hanb, and D. Hui,“Application of Fuzzy Wavelet Transform to Smooth Wind/PV Hybrid Power System Output withBattery”,The Proceedings of the International Conference on Smart Grid and Clean Energy Technologies, Vol.12, pp .994–1001, 2011.

X. Li, D. Hui, L. Wu, and X. Lai, “Control Strategy of Battery State of Chargefor Wind/Battery Hybrid Power System,” IEEE International Symposium on Industrial Electronics (ISIE), pp. 2723 – 2726, 2010.

N. J. Gil, and J. A. P. Lopes, “Hierarchical Frequency Control Scheme for Islanded Multi-Microgrids Operation,” in IEEE Lausanne Power Tech Lausanne, pp.473-478, 2007.

S. Chowdhury, S. P. Chowdhury, and P. Crossley, “Microgrids and Active Distribution Networks,” The Institution of Engineering andTechnology, 2009.

S.K. Aditya, and D. Das, “Load-Frequency Control of an Interconnected Hydro-ThermalPower System with New Area Control Error”, International Journal of Energy Research, Vol.24, pp.525-538, 2000.

M. U. Usama, D. Kelle, and T. Baldwin, “Utilizing Spinning Reserves as Energy Storage for Renewable Energy Integration,” Power Systems Conference, Clemson University, pp.1-5, March 2014.

D. Kottick, M. Blau, and D. Edelstein, “Battery Energy Storage for frequency regulationin an Island Power System”, IEEE Transactionson Energy Conversion, Vol. 8, No.3, pp.455-459, September 1993.

Prakash K. Ray, Soumya R. Mohanty, NandKishor,“Proportional–integral controller based small-signal analysis of hybrid distributed generation systems”, EnergyConversion and Management, Vol. 52, No.4, pp.1943–1954, April 2011.

H. Be0vrani, F. Habibi, P. Babahajyani, M. Watanabe, and Y. Mitani, “Intelligent Frequency Control in an AC Microgrid: Online PSOBased Fuzzy Tuning Approaches in Smart Grid”, IEEE Transactions”, Vol. 3, No. 4, pp.1935 – 1944, December 2012.


Refbacks

  • There are currently no refbacks.


Copyright (c) 2022 Journal of Thermal Engineering and Applications