Dropwise condensation heat transfer process optimisation on superhydrophobic surfaces using a multi-disciplinary approach

Keyphrases

• Process Optimization 100%
• Multidisciplinary Approach 100%
• Dropwise Condensation Heat Transfer 100%
• Superhydrophobic Surface 100%
• Heat Transfer Process 100%
• Initial Radius 66%
• Jumping Phenomenon 66%
• Computational Fluid Dynamics Analysis 66%
• Condensation 33%
• Energy Efficiency 33%
• Function-based 33%
• Heat Transfer 33%
• Optimal Combination 33%
• Radial Basis Function 33%
• Modeling Approach 33%
• Design Features 33%
• Technological Challenges 33%
• Evacuation 33%
• Experimental Fluid Dynamics 33%
• Dropwise Condensation 33%
• Near-optimal 33%
• Experiment Technique 33%
• Desirable Characteristics 33%
• Droplet Jumping 33%
• Static Contact Angle 33%
• Critical Contact Angle 33%
• Vertical Velocity 33%
• Jumping Droplets 33%
• Optimization Framework 33%
• Filmwise Condensation 33%
• Solid Surface 33%
• Lattice Boltzmann 33%
• Exchange Rate 33%
• Surrogate Model 33%
• Volume of Fluid Method 33%
• Design of Experiments 33%
• Lattice Volume 33%
• Surface Design 33%
• Surface Productivity 33%
• Adhesive Force 33%
• Heat Transfer Rate 33%
• Kinematic Conditions 33%

Engineering

• Condensation Heat Transfer 100%
• Condensation 100%
• Computational Fluid Dynamics 66%
• Input Parameter 33%
• Energy Efficiency 33%
• Process Parameter 33%
• Radial Basis Function 33%
• Design Feature 33%
• Design of Experiments 33%
• Adhesive Force 33%
• Static Contact 33%
• Boltzmann Equation 33%
• Volume of Fluid Method 33%
• Optimal Combination 33%