Explores turbulence characteristics, simulation methods, and modeling challenges, providing guidelines for choosing and validating turbulence models.
Covers symmetries and conservation laws in fluid dynamics, emphasizing the importance of maximizing symmetries in ideal fluid systems.
Explores the application of the SIMPLE algorithm in solving Navier-Stokes equations and compares staggered grid vs. collocated grid approaches in numerical flow simulations.
Explores physical models for microsystems, ideal fluids, Navier-Stokes equations, incompressible fluids, Reynolds number, and molecular dynamics.
Discusses approximations in incompressible, unsteady, and inviscid flow, lift, drag, viscosity, and fluid element deformation.
Covers the fundamentals of numerical flow simulation, emphasizing the importance of understanding the methodology and practicing simulation techniques to run full simulations autonomously.
Explores 2D potential flows in fluid dynamics, focusing on stream function and velocity potential relationships and visualization techniques.
Explores turbulence characteristics, modeling challenges, and various numerical simulation methods.
Explores equations and solutions for viscous flow, including stress-deformation relationships, Navier-Stokes equations, and simple fluid flow cases.
