A comparative thermoeconomic analysis and optimization of two different combined cycles by utilizing waste heat source of an MSWPP

Engineering

• Actual Power 10%
• Actuator 100%
• Capital Cost Rate 10%
• Combined Cycle 100%
• Design Stage 10%
• Electric Power Plant 30%
• Exhaust Gas 10%
• Gas Turbine 100%
• Generation Capacity 10%
• Genetic Algorithm 10%
• Genetic Algorithm Method 10%
• Heat Sources 100%
• Kalina Cycle 50%
• Multiobjective Optimization Method 10%
• Net Power Output 50%
• Non-Dominated Sorting Genetic Algorithm II 10%
• Organic Rankine Cycle 50%
• Power Generation 10%
• Power Output 10%
• System Capacity 10%
• Thermoeconomic Analysis 100%
• Thermoeconomics 10%
• Total Cost Rate 20%

Keyphrases

• Actual Power 10%
• Additional Power 10%
• Algorithm Analysis 10%
• Cost of Capital 10%
• Cost Rate 10%
• Exhaust Gas 10%
• Gas Turbine 100%
• Genetic Algorithm 10%
• Genetic Algorithm Optimization 10%
• Kalina Cycle 50%
• Multi-objective Optimization Algorithm 10%
• Net Power Output 50%
• Non-dominated Sorting Genetic Algorithm (NSGA-II) 20%
• Organic Rankine Cycle 50%
• Power Generation Capacity 10%
• Power Output 10%
• Power Plant 20%
• Solid Waste 10%
• System Capacity 10%
• Thermo-economic Optimization 100%
• Thermodynamic Analysis 20%
• Thermoeconomic Analysis 100%
• Thermoeconomics 10%
• Total Cost Rate 20%
• Total Power 10%
• Two-objective 10%
• Waste Heat Source 100%
• Waste Power Plant 10%