Keyphrases
Performance Analysis
100%
Thermo-economic Optimization
100%
Thermo-economic Performance
100%
Pressure Loss
100%
Environmental Cost
100%
Optimization Analysis
100%
Internal Irreversibility
100%
Internal Pressure
100%
Closed Brayton Cycle
100%
Fuel Cost
75%
Gas Turbine
75%
Thermal Efficiency
50%
Investment Cost
50%
Power Output
50%
Cost Efficiency
25%
Aviation Industry
25%
Chemical Equilibrium
25%
Fuel Consumption
25%
Combustion
25%
Maximum Temperature
25%
Temperature Ratio
25%
Performance Optimization
25%
Regeneration
25%
High Power
25%
Global Demand
25%
Fossil Fuels
25%
Weight Ratio
25%
Power Weights
25%
Cost Rate
25%
Power Generation
25%
Production Industry
25%
Maritime Industry
25%
Adiabatic Flame Temperature
25%
Net Power Output
25%
Power Production
25%
Demand for Electricity
25%
Flow Cost
25%
High Reliability
25%
Isentropic Efficiency
25%
Regenerator
25%
Isentropic
25%
Regenerator Effectiveness
25%
Equilibrium Approach
25%
Brayton Cycle
25%
Efficiency Investment
25%
Ease of Maintenance
25%
Total Cost Rate
25%
Maintenance Reliability
25%
Operational Flexibility
25%
Loss Factor
25%
Brayton Heat Engine
25%
Mover
25%
US Power
25%
Regenerative Brayton Cycle
25%
Utility Power
25%
Engineering
Performance Analysis
100%
Pressure Loss
100%
Thermoeconomics
100%
Internal Pressure
100%
Gas Turbine
100%
Closed Brayton Cycle
100%
Internal Irreversibility
100%
Power Output
66%
Thermodynamic Efficiency
66%
Flow Rate
33%
Fossil Fuel
33%
Objective Function
33%
Power Generation
33%
Maximum Temperature
33%
Heat Engine
33%
Fuel Cost
33%
Investment Cost
33%
Adiabatic Flame Temperature
33%
Net Power Output
33%
Power Production
33%
Regenerator
33%
Isentropic
33%
Isentropic Efficiency
33%
Total Cost Rate
33%
Fuel Cost Rate
33%
Prime Mover
33%
Regenerative Brayton Cycle
33%
Regenerator Effectiveness
33%
Environmental Cost Rate
33%
Flow Velocity
33%