Keyphrases
Breakup Model
100%
Commercially Viable
33%
Computational Capability
33%
Design of Experiments
100%
Diesel Spray Modeling
33%
Direct numerical Simulation
33%
Dissipation Constant
33%
Engine Combustion Network
100%
Engine Parameters
33%
Fluid Dynamics Problems
33%
Gas Phase
33%
Gas-liquid
33%
Industrial Application
33%
Injection Pressure
33%
Local Sensitivity
33%
Match Simulation
33%
Momentum Transfer
33%
Motion Scaling
33%
Multivariable
33%
Multivariable Design
33%
Multivariate Interaction
100%
Network Database
33%
Numerical Simulation Approach
33%
Operating Conditions
33%
Physical Phenomena
33%
Physical Processes
33%
Pressure Swing
33%
Response Model
33%
Reynolds-averaged Navier-Stokes
66%
Sensitivity Study
33%
Set Criterion
33%
Simulation Time
33%
Spraying Condition
100%
Stochastic Response
33%
Transport Equation
33%
Tuning Constant
100%
Turbulent Dissipation
33%
Mathematics
Dynamic Problem
33%
Experimental Data
33%
Experimental Design
100%
Gas Phase
33%
Interaction Variable
100%
Momentum Transfer
33%
Numerical Simulation
33%
Optimal Set
33%
Response Model
33%
Statistical Approach
100%
Stochastics
33%
Transport Equation
33%
Engineering
Automotives
33%
Design of Experiments
100%
Direct Numerical Simulation
33%
Fluid Dynamics
33%
Gas-Phase
33%
Industrial Applications
33%
Injection Pressure
33%
Liquid Gas
33%
Model Response
33%
Momentum Transfer
33%
Optimal Set
33%
Physical Phenomena
33%
Reynolds-Averaged Navier-Stokes
66%
Sensitivity Study
33%
Simplifies
33%
Computer Science
Industrial Application
50%
Momentum Transfer
50%
Network Database
50%
Numerical Simulation
50%
Operating Condition
50%
Physical Phenomena
50%
Simulation Approach
50%
Statistical Approach
100%
Transport Equation
50%
Material Science
Experimental Design
100%
Fluid Dynamics
33%