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Energy, Exergy, Economic, and Exergoenvironmental Analyses of a Novel Hybrid System to Produce Electricity, Cooling, and Syngas

Saeed Esfandi, Simin Baloochzadeh, Mohammad Asayesh, M.A. Ehyaei, Abolfazl Ahmadi, Amir Arsalan Rabanian, Biplab Das, V.A.F. Costa, Afshin Davarpanah

2020Energies46 citationsDOIOpen Access PDF

Abstract

Efficient solar and wind energy to electricity conversion technologies are the best alternatives to reduce the use of fossil fuels and to evolve towards a green and decarbonized world. As the conventional photovoltaic systems use only the 600–1100 nm wavelength range of the solar radiation spectrum for electricity production, hybrid systems taking advantage of the overall solar radiation spectrum are gaining increasing interest. Moreover, such hybrid systems can produce, in an integrated and combined way, electricity, heating, cooling, and syngas through thermochemical processes. They have thus the huge potential for use in residential applications. The present work proposes a novel combined and integrated system for residential applications including wind turbines and a solar dish collector for renewables energy harvesting, an organic Rankine cycle for power production, an absorption chiller for cold production, and a methanation plant for CH4 production from captured CO2. This study deals with the energy, exergy, economic, and exergoenvironmental analyses of the proposed hybrid combined system, to assess its performance, viability, and environmental impact when operating in Tehran. Additionally, it gives a clear picture of how the production pattern of each useful product depends on the patterns of the collection of available renewable energies. Results show that the rate of methane production of this hybrid system changes from 42 up to 140 Nm3/month, due to CO2 consumption from 44 to 144 Nm3/month during a year. Moreover, the energy and exergy efficiencies of this hybrid system vary from 24.7% and 23% to 9.1% and 8%, respectively. The simple payback period of this hybrid system is 15.6 and the payback period of the system is 21.4 years.

Topics & Concepts

Renewable energyProcess engineeringHybrid systemPhotovoltaic systemEnvironmental scienceExergyElectricity generationElectricityPayback periodExergy efficiencyRankine cycleSolar energyAutomotive engineeringEngineeringProduction (economics)Computer scienceElectrical engineeringPower (physics)Quantum mechanicsMacroeconomicsMachine learningEconomicsPhysicsThermodynamic and Exergetic Analyses of Power and Cooling SystemsAdvanced Thermodynamic Systems and EnginesAdvanced Thermodynamics and Statistical Mechanics
Energy, Exergy, Economic, and Exergoenvironmental Analyses of a Novel Hybrid System to Produce Electricity, Cooling, and Syngas | Litcius