Engineering
Low-Temperature
100%
Operational Condition
100%
Objective Function
100%
Metrics
100%
Artificial Neural Network
100%
Feasibility Study
100%
Hydrogen Production
100%
Inlet Temperature
100%
Investment Cost
100%
Heat Recovery
100%
Recovery Technique
100%
Waste Heat Recovery System
100%
Electrolyzer
100%
Exergy Efficiency
100%
Desalination
100%
Cooling Load
100%
Rankine
100%
Poly-Generation System
100%
Sustainability Index
100%
Net Power Output
100%
Geothermal Water
100%
Cost Rate
100%
Keyphrases
Multivariable
100%
Study Optimization
100%
System Application
100%
Waste Heat
100%
Polygeneration System
100%
Soft Computing
100%
MOGWO
100%
Sustainability Indicators
33%
In Tandem
33%
Production Rate
33%
Low Temperature
33%
Operating Conditions
33%
Electrolysis
33%
Artificial Neural Network
33%
Inlet Temperature
33%
Unified Framework
33%
Single Effect
33%
Multi-criteria Optimization
33%
Performance Metrics
33%
Polygeneration
33%
Energy Economics
33%
Influential Parameters
33%
Recovery Method
33%
Heat Recovery
33%
Waste Heat Recovery
33%
Exergy Efficiency
33%
Freshwater Production
33%
Power Cooling
33%
Cooling Load
33%
Energy-exergy
33%
Product Cost
33%
Rankine Cycle
33%
Generation Model
33%
Water Inlet
33%
Desalination
33%
Cost Rate
33%
TOPSIS Method
33%
Net Power Output
33%
Total Investment Cost
33%
Hydrogen Production Rate
33%
Geothermal Cycle
33%
Multi-objective Grey Wolf Optimizer
33%
Levelized Cost
33%
Flash-binary Geothermal
33%
Geothermal Water
33%
Absorption Refrigerator
33%
Transcritical Carbon Dioxide
33%
Production Hydrogen
33%
Chemical Engineering
Exergy
100%
Intelligent Computing
100%
Carbon Dioxide
50%
Enthalpy
50%
Neural Network
50%
Hydrogen Production
50%
Feasibility Study
50%
Rankine Cycle
50%