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Sensitivity analysis and multi-objective optimization of the energy, exergy and thermo-economic performance of a Brayton supercritical CO2-ORC configurations

Guillermo Valencia Ochoa, Dora Villada Castilla, Daniel Mendoza Cásseres

2023Energy Reports17 citationsDOIOpen Access PDF

Abstract

The following research compared some energy, exergetic and thermo-economic indicators of a supercritical CO2 simple Brayton cycle integrated with a simple organic Rankine cycle (SORC), and a regenerative organic Rankine cycle (RORC). A thermodynamic model was developed to determine the net power, thermal efficiency, the fuel consumption, and the exergy destruction of all the components of the system. Also, a thermo-economic model was developed to determine some economic indicators such as the levelized cost of energy (LCOE), the payback period (PBP) and specific investment cost (SIC). A sensitivity analysis was carried out to study the influence of the primary turbine inlet temperature (TIT), the high-pressure in the compressor (PHigh), the evaporator pinch point temperature difference (PPT), and the pressure ratio (Pr) on the indicators performance. Three different working fluids were selected in this study: acetone, toluene and cyclohexane. The results showed that cyclohexane had the best energy performance giving an efficiency of 48.02% for the RORC system. Besides, it presented the best thermo-economic results for the LCOE (0.26 USD/kWh), SIC (2626.75 USD/kWh), and a PBP (11.2 years). Finally, a multi-objective optimization was developed based on energy, exergy and thermo-economic performance parameters as objective functions to obtain a technical and economic feasible solution able to implement them in industrial applications.

Topics & Concepts

Organic Rankine cycleExergyExergy efficiencyBrayton cycleCost of electricity by sourceProcess engineeringWorking fluidEnvironmental scienceThermal efficiencyPinch pointPayback periodRankine cycleEngineeringElectricity generationHeat exchangerThermodynamicsWaste heatCombustionMechanical engineeringPower (physics)ChemistryEconomicsPhysicsOrganic chemistryMacroeconomicsProduction (economics)Thermodynamic and Exergetic Analyses of Power and Cooling SystemsRefrigeration and Air Conditioning TechnologiesAdvanced Thermodynamic Systems and Engines
Sensitivity analysis and multi-objective optimization of the energy, exergy and thermo-economic performance of a Brayton supercritical CO2-ORC configurations | Litcius