Thermal performance and economic analysis of supercritical Carbon Dioxide cycles in combined cycle power plant

Keyphrases

• Gas Turbine 100%
• Thermoeconomic Analysis 100%
• Thermal Performance Analysis 100%
• Combined Cycle Power Plant 100%
• S-CO2 Cycle 100%
• Supercritical Carbon Dioxide Cycle 100%
• Pressure Ratio 66%
• Plant Performance 50%
• Steam Rankine Cycle 50%
• High Efficiency 33%
• Whole Plant 33%
• Maximum Performance 33%
• Maximum Cost 33%
• Fossil Fuels 16%
• Electricity Cost 16%
• Closed-loop 16%
• Multi-objective Optimization 16%
• Cost Reduction 16%
• Full Potential 16%
• Net Efficiency 16%
• Pareto Front 16%
• Heat Exchanger 16%
• High Compactness 16%
• Nuclear Applications 16%
• Lieu 16%
• Supercritical CO2 (SCO2) 16%
• Turbine Inlet Pressure 16%
• Turbine Inlet Temperature 16%
• Power Efficiency 16%
• Specific Power 16%
• Cycle Configuration 16%
• Temperature Ratio 16%
• Triple Pressure 16%
• Bottoming Cycle 16%
• Supercritical Carbon Dioxide(sCO2) 16%
• Plant Efficiency 16%
• Temperature Glide 16%
• Performance Map 16%
• Solar Thermal Applications 16%
• S-CO2 Brayton Cycle 16%

Engineering

• Supercritical Carbon Dioxide 100%
• Thermal Performance 100%
• Gas Turbine 100%
• Combined Cycle Power Plant 100%
• Pressure Ratio 66%
• Steam Rankine Cycle 50%
• Fossil Fuel 16%
• Closed Loop 16%
• Multiobjective Optimization 16%
• Cost Reduction 16%
• Pareto Front 16%
• Exchanger 16%
• Solar Thermal 16%
• Turbine Inlet Temperature 16%
• Inlet Pressure 16%
• Specific Power 16%
• Power Cycle 16%
• Performance Map 16%
• Net Efficiency 16%
• Cascaded Cycle 16%
• Bottoming Cycle 16%
• Pressure Steam 16%